GABA(B)R1a/R1b-type receptor antisense deoxynucleotide treatment of melanotropes blocks chronic GABA(B) receptor inhibition of high voltage-activated Ca2+ channels

GABA(B) and dopamine D2 receptors, both of which acutely inhibit adenylyl cyclase and high voltage-activated Ca2+ channels (HVA-CCs), are found in high levels in the melanotrope cells of the pituitary intermediate lobe. Chronic D2 receptor agonist application in vitro has been reported to result in inhibition of HVA-CC activity by down-regulation. Here we report that chronic GABA(B), but not GABA(A), agonist treatment also resulted in HVA-CC inhibition. Two GABA(B) receptor variants have been cloned and shown to inhibit adenylyl cyclase in HEK-293 cells. We have constructed an antisense deoxynucleotide knockdown-type probe that is complementary to 18 bp from the point at which the two sequences first become homologous. Chronic coincubation with baclofen and GABA(B) antisense nucleotide completely eliminated the inhibition of the channels by baclofen alone but had no reversing effect on HVA-CC inhibition by the D2 agonist quinpirole. A scrambled, missense nucleotide also had no reversing effect. Incubation with a D2 antisense knockdown probe eliminated the ability of a D2 agonist to inhibit the channels but had no effect on baclofen blockade. These results show the existence an R1a/R1b type of GABA(B) receptor, which, like the D2 receptor, is coupled to chronic HVA-CC inhibition in melanotropes.     

The expression of plasma membrane Ca2+ pump isoforms in cerebellar granule neurons is modulated by Ca2+

Plasma membrane Ca2+ ATPase (PMCA) pump isoforms 2, 3, and 1CII are expressed in large amounts in the cerebellum of adult rats but only minimally in neonatal cerebellum. These isoforms were almost undetectable in rat neonatal cerebellar granule cells 1-3 days after plating, but they became highly expressed after 7-9 days of culturing under membrane depolarizing conditions (25 mM KCl). The behavior of isoform 4 was different: it was clearly detectable in adult cerebellum but was down-regulated by the depolarizing conditions in cultured cells. 25 mM KCl-activated L-type Ca2+ channels, significantly increasing cytosolic Ca2+. Changes in the concentration of Ca2+ in the culturing medium affected the expression of the pumps. L-type Ca2+ channel blockers abolished both the up-regulation of the PMCA1CII, 2, and 3 isoforms and the down-regulation of PMCA4 isoform. When granule cells were cultured in high concentrations of N-methyl-D-aspartic acid, a condition that increased cytosolic Ca2+ through the activation of glutamate-operated Ca2+ channels, up-regulation of PMCA1CII, 2, and 3 and down-regulation of PMCA4 was also observed. The activity of the isoforms was estimated by measuring the phosphoenzyme intermediate of their reaction cycle: the up-regulated isoforms, the activity of which was barely detectable at plating time, accounted for a large portion of the total PMCA activity of the cells. No up-regulation of the sarcoplasmic/endoplasmic reticulum calcium pump was induced by the depolarizing conditions.     

Speed of Ca2+ channel modulation by neurotransmitters in rat sympathetic neurons

We have measured the onset and recovery speed of inhibition of N-type Ca2+ channels in adult rat superior cervical ganglion neurons by somatostatin (SS), norepinephrine (NE), and oxotremorine-M (oxo-M, a muscarinic agonist), using the whole cell configuration of the patch-clamp method with 5 mM external Ca2+. With a local perfusion pipette system that changed the solution surrounding the cell within 50 ms, we applied agonists at various times before a brief depolarization from -80 mV that elicited I(Ca). At concentrations that produced maximal inhibition, the onset time constants for membrane-delimited inhibition by SS (0.5 microM), NE (10 microM), and oxo-M (20 microM) were 2.1, 0.7, and 1.0 s, respectively. The time constants for NE inhibition depended only weakly on the concentration, ranging from 1.2 to 0.4 s in the concentration range from 0.5 to 100 microM. Inhibition by oxo-M (20 microM) through a different G-protein pathway that uses a diffusible cytoplasmic messenger had a time constant near 9 s. The recovery rate constant from membrane-delimited inhibition was between 0.09 and 0.18 s(-1), significantly higher than the intrinsic GTPase rate of purified G protein Go, suggesting that Ca2+ channels or other proteins in the plasma membrane act as GTPase activating proteins. We also measured the rate of channel reinhibition after relief by strong depolarizing prepulses, which should reflect the kinetics of final steps in the inhibition process. In the presence of different concentrations of NE, reinhibition was four to seven times faster than the onset of inhibition, indicating that the slowest step of inhibition must precede the binding of G protein to the channel. We propose a kinetic model for the membrane-delimited NE inhibition of Ca2+ channels. It postulates two populations of receptors with different affinities for NE, a single population of G proteins, and a single population of Ca2+ channels. This model closely simulated the time courses of onset and recovery of inhibition and reinhibition, as well as the dose-response curve for inhibition of Ca2+ channels by NE.     

Interaction of Ca2+ agonist and depolarization on Ca2+ channel current in guinea pig detrusor cells

The interaction of large depolarization and dihydropyridine Ca2+ agonists, both of which are known to enhance L-type Ca2+ channel current, was examined using a conventional whole-cell clamp technique. In guinea pig detrusor cells, only L-type Ca2+ channels occur. A second open state (long open state: O2) of the Ca2+ channels develops during large depolarization (at +80 mV, without Ca2+ agonists). This was judged from lack of inactivation of the Ca2+ channel current during the large depolarizing steps (5 s) and slowly deactivating inward tail currents (= 10-15 ms) upon repolarization of the cell membrane to the holding potential (-60 mV). Application of Bay K 8644 (in 2.4 mM Ca(2+)-containing solutions) increased the amplitude of the Ca2+ currents evoked by simple depolarizations, and made it possible to observe inward tail currents (= 2.5-5 ms at -60 mV). The open state induced by large depolarization (O2*) in the Bay K 8644 also seemed hardly to inactivate. After preconditioning with large depolarizing steps, the decay time course of the inward tail currents upon repolarization to the holding potential (-60 mV) was significantly slowed, and could be fitted reasonably with two exponentials. The fast and slow time constants were 10 and 45 ms, respectively, after 2 s preconditioning depolarizations. Qualitatively the same results were obtained using Ba2+ as a charge carrier. Although the amplitudes of the inward currents observed in the test step and the subsequent repolarization to the holding potential were decreased in the same manner by additional application of nifedipine (in the presence of Bay K 8644), the very slow deactivation time course of the tail current was little changed. The additive enhancement by large depolarization and Ca2+ agonists of the inward tail current implies that two mechanisms separately induce long opening of the Ca2+ channels: i.e., that there are four open states.     

Beta3-integrin-deficient mice are a model for Glanzmann thrombasthenia showing placental defects and reduced survival

The relationship between Ca2+ release ("Ca2+ sparks") through ryanodine-sensitive Ca2+ release channels in the sarcoplasmic reticulum and KCa channels was examined in smooth muscle cells from rat cerebral arteries. Whole cell potassium currents at physiological membrane potentials (-40 mV) and intracellular Ca2+ were measured simultaneously, using the perforated patch clamp technique and a laser two-dimensional (x-y) scanning confocal microscope and the fluorescent Ca2+ indicator, fluo-3. Virtually all (96%) detectable Ca2+ sparks were associated with the activation of a spontaneous transient outward current (STOC) through KCa channels. A small number of sparks (5 of 128) were associated with currents smaller than 6 pA (mean amplitude, 4.7 pA, at -40 mV). Approximately 41% of STOCs occurred without a detectable Ca2+ spark. The amplitudes of the Ca2+ sparks correlated with the amplitudes of the STOCs (regression coefficient 0.8; P < 0.05). The half time of decay of Ca2+ sparks (56 ms) was longer than the associated STOCs (9 ms). The mean amplitude of the STOCs, which were associated with Ca2+ sparks, was 33 pA at -40 mV. The mean amplitude of the "sparkless" STOCs was smaller, 16 pA. The very significant increase in KCa channel open probability (>10(4)-fold) during a Ca2+ spark is consistent with local Ca2+ during a spark being in the order of 1-100 microM. Therefore, the increase in fractional fluorescence (F/Fo) measured during a Ca2+ spark (mean 2.04 F/Fo or approximately 310 nM Ca2+) appears to significantly underestimate the local Ca2+ that activates KCa channels. These results indicate that the majority of ryanodine receptors that cause Ca2+ sparks are functionally coupled to KCa channels in the surface membrane, providing direct support for the idea that Ca2+ sparks cause STOCs.     

Single L-type calcium channels in smooth muscle cells from resistance arteries of spontaneously hypertensive rats

The amplitude of the whole-cell L-type Ca2+ channel current recorded from vascular smooth muscle cells is reportedly greater in spontaneously hypertensive rats (SHR) than in Wistar-Kyoto rats (WKY). However, no study has examined properties of single Ca2+ channels in arterial cells from these strains. To further test the hypothesis that activation of L-type Ca2+ channels in arterial smooth muscle cells would be enhanced in SHR, we recorded single Ca2+ channel currents in resistance mesenteric artery cells from SHR and WKY (8 to 9 weeks of age) using a cell-attached patch clamp technique. With 50 mmol/L Ba2+ in the recording pipette, the depolarizing pulse from a holding potential of -40 mV evoked the single L-type Ca2+ channel current. Opening of the single channels was more frequent in cells from SHR than from WKY. Single-channel conductance (20 pS) and open time (1 ms at 0 mV) did not differ in the two strains. The results suggest that an increased amplitude of the whole-cell current can be attributed to the enhanced opening of single Ca2+ channels in the arterial smooth muscle cells from SHR compared with WKY.     

beta-Fructosidases: a new superfamily of glycosyl-hydrolases

Dihydropyridines (DHPs) block L-type Ca2+ channels more potently at depolarized membrane potentials, consistent with high affinity binding to the inactivated state. Nisoldipine (a DHP antagonist) blocks the smooth muscle channel more potently than the cardiac one, a phenomenon observed not only in native channels but also in expressed channels. We examined whether this tissue specificity was attributable to differences of inactivation in the two channel types. We expressed cardiac or smooth muscle alpha1C subunits in combination with beta2a and alpha2/delta subunits in human embryonic kidney cells, and used 2 mM Ca2+ as the permeant ion. This system thus reproduces the in vivo topology and charge carrier of the channels while facilitating comparison of the two alpha1C splice variants. Both voltage-dependent and isoform-specific sensitivity of 10 nM nisoldipine inhibition of the channel were demonstrated, with the use of -100 mV as the holding potential for fully reprimed channels and -65 mV to populate the inactivated state. Under drug-free conditions, we characterized fast inactivation (1-sec prepulses) and slow inactivation (3 min prepulses) in the two isoforms. Inactivation parameters were not statistically different in the two channel isoforms; if anything, cardiac channels tended to inactivate more than the smooth muscle channels at relevant voltages. Likewise, the voltage-dependent activation was identical in the two isoforms. We thus conclude that the more potent nisoldipine inhibition of smooth muscle versus cardiac L-type Ca2+ channels is not attributable to differences in channel inactivation or activation. Intrinsic, gating-independent DHP receptor binding affinity differences must be invoked to explain the isoform-specific sensitivity of the DHP block.     

Cranial asymmetries. Reflexions on plagiocephalies. Premature sutural synostosis or extracranial origin?

The effects of various Ca2+ channel agonists and antagonists on tumor cell growth were investigated using U-373 MG human astrocytoma and SK-N-MC human neuroblastoma cell lines. Classical Ca2+ channel antagonists, verapamil, nifedipine, and diltiazem, and inorganic Ca2+ channel antagonists, Ni2+ and Co2+, inhibited growth of these tumor cells in a dose-dependent manner. Except Ni2+, these Ca2+ channel antagonists did not induce a significant cytotoxicity, suggesting that the growth-inhibitory effects of these drugs may be the result of the influence on the proliferative signaling mechanisms of these tumor cells. In contrast, Bay K-8644, a Ca2+ channel agonist, neither enhanced the growth of tumor cells nor increased intracellular Ca2+ concentration, indicating that voltage-sensitive Ca2+ channels may not be involved in tumor cell proliferation. Moreover, growth-inhibitory concentrations of Ca2+ channel antagonists significantly blocked agonist (carbachol or serum)-induced intracellular Ca2+ mobilization, which was monitored using Fura-2 fluorescence technique. These results suggest that the inhibition of the growth of human brain tumor cells induced by Ca2+ channel antagonists may not be the result of interaction with Ca2+ channels, but may be the result of the interference with agonist-induced intracellular Ca2+ mobilization, which is an important proliferative signaling mechanism.     

Glucocorticoid regulation of calcium-activated potassium channels mediated by serine/threonine protein phosphatase

Adrenal glucocorticoids exert powerful effects on cellular excitability in neuroendocrine cells and neurons, although the underlying mechanisms are poorly understood. In metabolically intact mouse anterior pituitary corticotrope (AtT20) cells glucocorticoid-induced proteins render large conductance calcium-activated potassium (BK) channels insensitive to inhibition by protein kinase A (PKA). In this study we have addressed whether this action of glucocorticoids is mediated via protein phosphatase activity at the level of single BK channels. In isolated inside-out patches from control AtT20 cells BK channels (125 pS) were inhibited by activation of closely associated PKA. Pretreatment (2 h) of cells with 1 microM dexamethasone before patch excision did not modify the intrinsic properties or expression levels of BK channel alpha-subunits in AtT20 cells. However, PKA-mediated inhibition of BK channel activity in isolated patches from steroid-treated cells was severely blunted. This effect of steroid was not observed using adenosine 5'-O-(3-thiotriphosphate) as phosphate donor or on exposure of the intracellular face of the patch with 10 nM of the protein phosphatase inhibitors okadaic acid or calyculin A but was mimicked by application of protein phosphatase 2A (PP2A) to the intracellular face of patches from control cells. Glucocorticoids did not modify total PP2A activity in AtT20 cells, suggesting that modified PP2A-like phosphatase activity closely associated with BK channels is required for glucocorticoid action.     

Action-potential-like depolarizations relieve opioid inhibition of N-type Ca2+ channels in NG108-15 cells

The ability of action-potential-like waveforms (APWs) to attenuate opioid-induced inhibition of N-type Ca2+ channels was investigated in the neuroblastoma x glioma cell line NG108-15 using whole-cell voltage clamp methods. In in vitro differentiated NG108-15 cells, the opioid agonist [d-ala2]-methionine-enkephalin (DAME) reversibly decreased omega-conotoxin-GVIA-sensitive Ba2+ currents (N-type currents). Agonist-mediated inhibition of N-type currents could be transiently relieved by strong unphysiological depolarizing prepulses to +80 mV (facilitation). Significant facilitation was also achieved by conditioning the cell with a train of 15 APWs, which roughly mimicked physiological action potentials (1- to 6-ms-long depolarizations to +30 mV from a holding potential of -40 mV). The APW-induced facilitation depended on both conditioning pulse frequency and duration. Summation of the disinhibition produced by each APW was possible because reinhibition following repolarization to -40 mV was a much slower process (tau=88 ms) than the onset of facilitation at +80 mV (tau=7 ms). These results provide evidence that N-type Ca2+ channel facilitation may be a physiologically relevant process, and suggest that neuronal firing may relieve agonist-induced inhibition of N-type currents to an extent depending on both the shape of action potentials and the frequency of firing.     

Rapid Ca2+ entry through Ca2+-permeable AMPA/Kainate channels triggers marked intracellular Ca2+ rises and consequent oxygen radical production

The widespread neuronal injury that results after brief activation of highly Ca2+-permeable NMDA channels may, in large part, reflect mitochondrial Ca2+ overload and the consequent production of injurious oxygen radicals. In contrast, AMPA/kainate receptor activation generally causes slower toxicity, and most studies have not found evidence of comparable oxygen radical production. Subsets of central neurons, composed mainly of GABAergic inhibitory interneurons, express AMPA/kainate channels that are directly permeable to Ca2+ ions. Microfluorometric techniques were performed by using the oxidation-sensitive dye hydroethidine (HEt) to determine whether the relatively rapid Ca2+ flux through AMPA/kainate channels expressed on GABAergic neurons results in oxygen radical production comparable to that triggered by NMDA. Consistent with previous studies, NMDA exposures triggered increases in fluorescence in most cultured cortical neurons, whereas high K+ (50 mM) exposures (causing depolarization-induced Ca2+ influx through voltage-sensitive Ca2+ channels) caused little fluorescence change. In contrast, kainate exposure caused fluorescence increases in a distinct subpopulation of neurons; immunostaining for glutamate decarboxylase revealed the responding neurons to constitute mainly the GABAergic population. The effect of NMDA, kainate, and high K+ exposures on oxygen radical production paralleled the effect of these exposures on intracellular Ca2+ levels when they were monitored with the low-affinity Ca2+-sensitive dye fura-2FF, but not with the high-affinity dye fura-2. Inhibition of mitochondrial electron transport with CN- or rotenone almost completely blocked kainate-triggered oxygen radical production. Furthermore, antioxidants attenuated neuronal injury resulting from brief exposures of NMDA or kainate. Thus, as with NMDA receptor activation, rapid Ca2+ influx through Ca2+-permeable AMPA/kainate channels also may result in mitochondrial Ca2+ overload and consequent injurious oxygen radical production.     

Stimulation of large-conductance Ca2+-activated K+ channels by Evans blue in cultured endothelial cells of human umbilical veins

The effect of Evans blue (EB) on large-conductance Ca2+-activated K+ (BKCa) channels was investigated in cultured endothelial cells of human umbilical veins. In whole-cell configuration, EB (50 microM) reversibly increased the amplitude of K+ outward currents (IK). When the patch pipettes were filled with 10 mM EGTA, its stimulatory effect on IK was unaltered. Further application of EB in the presence of suramin, a blocker of P2-purinergic receptor, or AOPCP, an inhibitor of 5'-nucleotidase, still increased IK. However, charybdotoxin (100 nM) suppressed EB-induced increase in IK. In inside-out configuration, bath application of EB (50 microM) did not change single channel conductance but significantly increased the activity of BKCa channels. The EB-induced increase in the activity of BKCa channels was independent on internal Ca2+. EB (50 microM) shifted the activation curve of BKCa channels to less positive membrane potentials by approximately 20 mV. The change in the kinetic behavior of BKCa channels caused by EB in these cells is due to an increase in mean open time and a decrease in mean closed time. These results indicate that EB can stimulate the activity of BKCa channel in endothelial cells. This effect is unrelated to its blockade of P2-purinergic receptors or inhibition of 5'-nucleotidase. The direct stimulation of these ionic channels by EB may contribute to its effect on capillary permeability.     

Two-dimensional confocal images of organization, density, and gating of focal Ca2+ release sites in rat cardiac myocytes

In cardiac myocytes Ca2+ cross-signaling between Ca2+ channels and ryanodine receptors takes place by exchange of Ca2+ signals in microdomains surrounding dyadic junctions, allowing first the activation and then the inactivation of the two Ca2+-transporting proteins. To explore the details of Ca2+ signaling between the two sets of receptors we measured the two-dimensional cellular distribution of Ca2+ at 240 Hz by using a novel confocal imaging technique. Ca2+ channel-triggered Ca2+ transients could be resolved into dynamic "Ca2+ stripes" composed of hundreds of discrete focal Ca2+ releases, appearing as bright fluorescence spots (radius congruent with 0.5 micrometer) at reproducible sites, which often coincided with t-tubules as visualized with fluorescent staining of the cell membrane. Focal Ca2+ releases triggered stochastically by Ca2+ current (ICa) changed little in duration ( congruent with7 ms) and size (congruent with100,000 Ca ions) between -40 and +60 mV, but their frequency of activation and first latency mirrored the kinetics and voltage dependence of ICa. The resolution of 0.95 +/- 0. 13 reproducible focal Ca2+ release sites per micrometer3 in highly Ca2+-buffered cells, where diffusion of Ca2+ is limited to 50 nm, suggests the presence of about one independent, functional Ca2+ release site per half sarcomere. The density and distribution of Ca2+ release sites suggest they correspond to dyadic junctions. The abrupt onset and termination of focal Ca2+ releases indicate that the cluster of ryanodine receptors in individual dyadic junctions may operate in a coordinated fashion.     

A single non-L-, non-N-type Ca2+ channel in rat insulin-secreting RINm5F cells

Single high-voltage-activated (HVA) Ca2+ channel activity was recorded in rat insulinoma RINm5F cells using cell-attached and outside-out configurations. Single-channel recordings revealed three distinct Ca2+ channel subtypes: one sensitive to dihydropyridines (DHPs)-(L-type), another sensitive to omega -conotoxin (CTx)-GVIA (N-type) and a third type insensitive to DHPs and omega -CTx-GVIA (non-L-, non-N-type). The L-type channel was recorded in most patches between -30 and +30 mV. The channel had pharmacological and biophysical features similar to the L-type channels described in other insulin-secreting cells (mean conductance 21 pS in control conditions and 24 pS in the presence of 5 microM Bay K 8644). The non-L-, non-N-type channel was recorded in cells chronically treated with omega -CTx-GVIA in the presence of nifedipine to avoid the contribution of N- and L-type channels. Channel activity was hardly detectable below -10 mV and was recruited by negative holding potentials (< -90 mV). The channel open probability increased steeply from -10 to + 40 mV. Different unitary current sublevels could be detected and the current voltage relationship was calculated from the higher amplitude level with a slope conductance of 21 pS. Channel activity lasted throughout depolarizations of 300-800ms with little sign of inactivation. Above 0 mV the channel showed a persistent flickering kinetics with brief openings (tau o 0.6 ms) and long bursts (tau burst 60 ms) interrupted by short interburst intervals. The third HVA Ca2+ channel subtype, the N-type, had biophysical properties similar to the non-L-, non-N-type and was best identified in outside-out patches by its sensitivity to omega -CTx-GVIA. The channel was detectable only above -10 mV from a -90 mV holding potential, exhibited a fast flickering behaviour, persisted during prolonged depolarizations and had a slope conductance of about 19 pS. The present data provide direct evidence for a slowly inactivating non-L-, non-N-type channel in insulin-secreting RINm5F cells that activates at more positive voltages than the L-type channel and indicate the possibility of identifying unequivocally single HVA Ca2+ channels in cell-attached and excised membrane patches under controlled pharmacological conditions.     

Mechanism of nitric oxide-induced vasodilatation: refilling of intracellular stores by sarcoplasmic reticulum Ca2+ ATPase and inhibition of store-operated Ca2+ influx

The precise mechanisms by which nitric oxide (NO) decreases free [Ca2+]i, inhibits Ca2+ influx, and relaxes vascular smooth muscle are poorly understood. In rabbit and mouse aorta, agonist-induced contractions and increases in [Ca2+]i were resistant to nifedipine, suggesting Ca2+ entry through non-L-type Ca2+ channels. Relaxations to NO were inhibited by thapsigargin (TG) or cyclopiazonic acid (CPA) indicating the involvement of sarcoplasmic reticulum ATPase (SERCA). Studies of the effect of NO on [Ca2+]i and the rate of Mn2+ influx with fura-2 fluorometry in rabbit aortic smooth muscle cells in primary culture were designed to test how SERCA is involved in mediating the response to NO. When cells were stimulated with angiotensin II (AII), NO accelerated the removal of Ca2+ from the cytoplasm, decreased [Ca2+]i, and inhibited Ca2+ and Mn2+ influx. Inhibition of SERCA abolished all the effects of NO. In contrast, inhibition of the Na+/Ca2+exchanger or the plasma membrane Ca2+ ATPase had no influence on the ability of NO to decrease [Ca2+]i. NO maximally decreased [Ca2+]i within 5 s, whereas significant inhibition of AII-induced Ca2+ and Mn2+ influx required more than 15 s. The inhibition of cation influx strictly depended on [Ca2+]o and functional SERCA, suggesting that during the delay before NO inhibits Ca2+ influx, the influx of Ca2+ and the uptake into intracellular stores are required. In the absence of [Ca2+]o, NO diminished the AII-induced [Ca2+]i transient by a SERCA-dependent mechanism and increased the amount of Ca2+ in the stores subsequently released by ionomycin. The present study indicates that the initial rapid decrease in [Ca2+]i caused by NO in vascular smooth muscle is accounted for by the uptake of Ca2+ by SERCA into intracellular stores. It is proposed that the refilling of the stores inhibits store-operated Ca2+ influx through non-L-type Ca2+ conducting ion channels and that this maintains the decrease in [Ca2+]i and NO-induced relaxation.     

Activation of calcium channels by cAMP in STC-1 cells is dependent upon Ca2+ calmodulin-dependent protein kinase II

Activation of L-type calcium channels in the neuroendocrine, cholecytstokinin-secreting cell line, STC-1, is vital for secretion of CCK. In the present study, the regulation of L-type Ca2+ channels by cAMP and Ca2+ calmodulin dependent protein kinase II (CaM-KII) in STC-1 cells was investigated. Exposure to 3-isobutyl-1-methylxanthine (IBMX) increased intracellular cAMP levels, whole cell Ca2+ currents and activated Ca2+ channels in cell-attached membrane patches. Furthermore, in Fura-2AM loaded cells, cytosolic Ca2+ levels increased upon exposure to IBMX. By contrast, pretreatment of cells with the CaM-KII inhibitor KN-62, prevented IBMX activation of Ca2+ channels in cell-attached patches or increases in cytosolic Ca2+ levels. Inclusion of the synthetic peptide fragment 290-309 of CaM-KII, a CaM-KII antagonist, in the pipette solution, blocked the activation of whole cell Ca2+ currents upon addition of IBMX. These results indicate a unique mechanism of L-type Ca2+ channel activation involving two phosphorylation events.     

Alteration of Ca2+ fluxes in brain microsomes by K+ and Na+: modulation by sulfated polysaccharides and trifluoperazine

Rat brain microsomes accumulate Ca2+ at the expense of ATP hydrolysis. The rate of transport is not modulated by the monovalent cations K+, Na+, or Li+. Both the Ca2+ uptake and the Ca(2+)-dependent ATPase activity of microsomes are inhibited by the sulfated polysaccharides heparin, fucosylated chondroitin sulfate, and dextran sulfate. Half-maximal inhibition is observed with sulfated polysaccharide concentrations ranging from 0.5 to 8.0 micrograms/ml. The inhibition is antagonized by KCl and NaCl but not by LiCl. As a result, Ca2+ transport by the native vesicles, which in the absence of polysaccharides is not modulated by monovalent cations, becomes highly sensitive to these ions. Trifluoperazine has a dual effect on the Ca2+ pump of brain microsomes. At low concentrations (20-80 microM) it stimulates the rate of Ca2+ influx, and at concentrations > 100 microM if inhibits both the Ca2+ uptake and the ATPase activity. The activation observed at low trifluoperazine concentrations is specific for the brain Ca(2+)-ATPase; for the Ca(2+)-ATPases found in blood platelets and in the sarcoplasmic reticulum of skeletal muscle, trifluoperazine causes only a concentration-dependent inhibition of Ca2+ uptake. Passive Ca2+ efflux from brain microsomes preloaded with Ca2+ is increased by trifluoperazine (50-150 microM), and this effect is potentiated by heparin (10 micrograms/ml), even in the presence of KCl. It is proposed that the Ca(2+)-ATPase isoforms from brain microsomes is modulated differently by polysaccharides and trifluoperazine when compared with skeletal muscle and platelet isoforms.     

Isoform-specific function of single inositol 1,4,5-trisphosphate receptor channels

The inositol 1,4,5-trisphosphate receptor (InsP3R) family of Ca2+ release channels is central to intracellular Ca2+ signaling in mammalian cells. The InsP3R channels release Ca2+ from intracellular compartments to generate localized Ca2+ transients that govern a myriad of cellular signaling phenomena (Berridge, 1993. Nature. 361:315-325; Joseph, 1996. Cell Signal. 8:1-7; Kume et al., 1997. Science. 278:1940-1943; Berridge, 1997. Nature. 368:759-760). express multiple InsP3R isoforms, but only the function of the single type 1 InsP3R channel is known. Here the single-channel function of single type 2 InsP3R channel is defined for the first time. The type 2 InsP3R forms channels with permeation properties similar to that of the type 1 receptor. The InsP3 regulation and Ca2+ regulation of type 1 and type 2 InsP3R channels are strikingly different. Both InsP3 and Ca2+ are more effective at activating single type 2 InsP3R, indicating that single type 2 channels mobilize substantially more Ca2+ than single type 1 channels in cells. Furthermore, high cytoplasmic Ca2+ concentrations inactivate type 1, but not type 2, InsP3R channels. This indicates that type 2 InsP3R channel is different from the type 1 channel in that its activity will not be inherently self-limiting, because Ca2+ passing through an active type 2 channel cannot feed back and turn the channel off. Thus the InsP3R identity will help define the spatial and temporal nature of local Ca2+ signaling events and may contribute to the segregation of parallel InsP3 signaling cascades in mammalian cells.     

Ca(2+)-activated K+ channels of human and rabbit erythrocytes display distinctive patterns of inhibition by venom peptide toxins

Despite recent progress in the molecular characterization of high-conductance Ca(2+)-activated K+ (maxi-K) channels, the molecular identities of intermediate conductance Ca(2+)-activated K+ channels, including that of mature erythrocytes, remains unknown. We have used various peptide toxins to characterize the intermediate conductance Ca(2+)-activated K+ channels (Gardos pathway) of human and rabbit red cells. With studies on K+ transport and on binding of 125I-charybdotoxin (ChTX) and 125I-kaliotoxin (KTX) binding in red cells, we provide evidence for the distinct nature of the red cell Gardos channel among described Ca(2+)-activated K+ channels based on (i) the characteristic inhibition and binding patterns produced by ChTX analogues, iberiotoxin (IbTX) and IbTX-like ChTX mutants, and KTX (1-37 and 1-38 variants); (ii) the presence of some properties heretofore attributed only to voltage-gated channels, including inhibition of K transport by margatoxin (MgTX) and by stichodactyla toxin (StK); (iii) and the ability of scyllatoxin (ScyTX) and apamin to displace bound 125I-charybdotoxin, a novel property for K+ channels. These unusual pharmacological characteristics suggest a unique structure for the red cell Gardos channel.