Ghrelin reduces voltage-gated calcium currents in GH₃ cells via cyclic GMP pathways

Ghrelin is an endogenous growth hormone secretagogue (GHS) causing release of GH from pituitary somatotropes through the GHS receptor. Secretion of GH is linked directly to intracellular free Ca2+ concentration ([Ca2+]i), which is determined by Ca2+ influx and release from intracellular Ca2+ storage sites. Ca2+ influx is via voltage-gated Ca2+ channels, which are activated by cell depolarization. The mechanism underlying the effect of ghrelin on voltage-gated Ca2+ channels is still not clear. In this report, using whole cell patch-clamp recordings, we assessed the acute action of ghrelin on voltage-activated Ca2+ currents in GH3 rat somatotrope cell line. Ca2+ currents were divided into three types (T, N, and L) through two different holding potentials (-80 and -40 mV) and specific L-type channel blocker (nifedipine, NFD). We demonstrated that ghrelin significantly and reversibly decreases all three types of Ca2+ currents in GH3 cells through GHS receptors on the cell membrane and down-stream signaling systems. With different signal pathway inhibitors, we observed that ghrelin-induced reduction in voltage-gated Ca2+ currents in GH3 cells was mediated by a protein kinase G-dependent pathways. As ghrelin also stimulates Ca2+ release and prolongs the membrane depolarization, this reduction in voltage-gated Ca2+ currents may not be translated into a reduction in [Ca2+]i, or a decrease in GH secretion.     

Stimulatory effect of ghrelin on isolated porcine somatotropes

Research on the mechanism for growth hormone secretagogue (GHS) induction of growth hormone secretion led to the discovery of the GHS receptor (GHS-R) and later to ghrelin, an endogenous ligand for GHS-R. The ability of ghrelin to induce an increase in the intracellular Ca(2+) concentration - [Ca(2+)](i) - in somatotropes was examined in dispersed porcine pituitary cells using a calcium imaging system. Somatotropes were functionally identified by application of human growth hormone releasing hormone. Ghrelin increased the [Ca(2+)](i) in a dose-dependent manner in 98% of the cells that responded to human growth hormone releasing hormone. In the presence of (D-Lys(3))-GHRP-6, a specific receptor antagonist of GHS-R, the increase in [Ca(2+)](i) evoked by ghrelin was decreased. Pretreatment of cultures with somatostatin or neuropeptide Y reduced the ghrelin-induced increase of [Ca(2+)](i). The stimulatory effect of ghrelin on somatotropes was greatly attenuated in low-calcium saline and blocked by nifedipine, an L-type calcium channel blocker, suggesting involvement of calcium channels. In a zero Na(+) solution, the stimulatory effect of ghrelin on somatotropes was decreased, suggesting that besides calcium channels, sodium channels are also involved in ghrelin-induced calcium transients. Either SQ-22536, an adenylyl cyclase inhibitor, or U73122, a phospholipase C inhibitor, decreased the stimulatory effects of ghrelin on [Ca(2+)](i) transiently, indicating the involvement of adenylyl cyclase-cyclic adenosine monophosphate and phospholipase C inositol 1,4,5-trisphosphate pathways. The nonpeptidyl GHS, L-692,585 (L-585), induced changes in [Ca(2+)](i) similar to those observed with ghrelin. Application of L-585 after ghrelin did not have additive effects on [Ca(2+)](i). Preapplication of L-585 blocked the stimulatory effect of ghrelin on somatotropes. Simultaneous application of ghrelin and L-585 did not cause an additive increase in [Ca(2+)](i). Our results suggest that the actions of ghrelin and synthetic GHS closely parallel each other, in a manner that is consistent with an increase of hormone secretion.     

Orexin-B augments voltage-gated L-type Ca(2+) current via protein kinase C-mediated signalling pathway in ovine somatotropes

Orexins, orexigenic neuropeptides, are secreted from lateral hypothalamus and orexin receptors are expressed in the pituitary. Since growth hormone (GH) secreted from pituitary is integrally linked to energy homeostasis and metabolism, we studied the effect of orexin-B on voltage-gated Ca(2+) currents and the related signalling mechanisms in primary cultured ovine somatotropes using whole-cell patch-clamp techniques. With a bath solution containing TEA-Cl (40 mM) and Tetrodotoxin (TTX) (1 microM), three subtypes of Ca(2+) currents, namely the long-lasting (L), transient (T), and N currents, were isolated using different holding potentials (-80 and -30 mV) in combination with specific Ca(2+) channel blockers (nifedipine and omega-conotoxin). About 75% of the total current amplitude was contributed by the L current, whereas the N and T currents accounted for the rest. Orexin-B (1-100 nM) dose-dependently and reversibly increased only the L current up to approximately 125% of the control value within 4-5 min. Neither a specific protein kinase A (PKA) blocker (H89, 1 microM) nor an inhibitory peptide (PKI, 10 microM) had any effect on the increase in L current by orexin-B. The orexin-B-induced increase in the L current was abolished by concurrent treatment with calphostin C (Cal-C, 100 nM), protein kinase C (PKC) inhibitory peptide (PKC(19-36), 1 microM), or by pretreatment with phorbol-12,13-dibutyrate (PDBu) (0.5 microM) for 16 h (a downregulator of PKC). Orexin-B also increased in vitro GH secretion in a dose-dependent manner. We conclude that orexin-B increases the L-type Ca(2+) current and GH secretion through orexin receptors and PKC-mediated signalling pathways in ovine somatotropes.     

Intracellular signaling mechanisms mediating ghrelin-stimulated growth hormone release in somatotropes

Ghrelin is a newly discovered peptide that binds the receptor for GH secretagogues (GHS-R). The presence of both ghrelin and GHS-Rs in the hypothalamic-pituitary system, together with the ability of ghrelin to increase GH release, suggests a hypophysiotropic role for this peptide. To ascertain the intracellular mechanisms mediating the action of ghrelin in somatotropes, we evaluated ghrelin-induced GH release from pig pituitary cells both under basal conditions and after specific blockade of key steps of cAMP-, inositol phosphate-, and Ca2+-dependent signaling routes. Ghrelin stimulated GH release at concentrations ranging from 10-10 to 10-6 m. Its effects were comparable with those exerted by GHRH or the GHS L-163,255. Combined treatment with ghrelin and GHRH or L-163,255 did not cause further increases in GH release, whereas somatostatin abolished the effect of ghrelin. Blockade of phospholipase C or protein kinase C inhibited ghrelin-induced GH secretion, suggesting a requisite role for this route in ghrelin action. Unexpectedly, inhibition of either adenylate cyclase or protein kinase A also suppressed ghrelin-induced GH release. In addition, ghrelin stimulated cAMP production and also had an additive effect with GHRH on cAMP accumulation. Ghrelin also increased free intracellular Ca2+ levels in somatotropes. Moreover, ghrelin-induced GH release was entirely dependent on extracellular Ca2+ influx through L-type voltage-sensitive channels. These results indicate that ghrelin exerts a direct stimulatory action on porcine GH release that is not additive with that of GHRH and requires the contribution of a multiple, complex set of interdependent intracellular signaling pathways.     

Somatostatin increases voltage-gated K+ currents in GH3 cells through activation of multiple somatostatin receptors

The secretion of GH by somatotropes is inhibited by somatostatin (SRIF) through five specific membrane receptors (SSTRs). SRIF increases both transient outward (IA) and delayed rectifying (IK) K+ currents. We aim to clarify the subtype(s) of SSTRs involved in K+ current enhancement in GH3 somatotrope cells using specific SSTR subtype agonists. Expression of all five SSTRs was confirmed in GH3 cells by RT-PCR. Nystatin-perforated patch clamp was used to record voltage-gated K+ currents. We first established the presence of IA and IK type K+ currents in GH3 cells using different holding potentials (-40 or -70 mV) and specific blockers (4-aminopirimidine and tetraethylammonium chloride). SRIF (200 nM) increased the amplitude of both IA and IK in a fully reversible manner. Various concentrations of each specific SRTR agonist were tested on K+ currents to find the maximal effective concentration. Activation of SSTR2 and SSTR4 by their respective agonists, L-779,976 and L-803,087 (10 nM), increased K+ current amplitude without preference to IA or IK, and abolished any further increase by SRIF. Activation of SSTR1 and SSTR5 by their respective agonists, L-797,591 or L-817,818 (10 nM), increased K+ current amplitude, but SRIF evoked a further increase. The SSTR3 agonist L-797,778 (10 nM) did not affect the K+ currents or the response to SRIF. These results indicate that SSTR1, -2, -4, and -5 may all be involved in the enhancement of K+ currents by SRIF but that only the activation of SSTR2 or -4 results in the full activation of K+ current caused by SRIF.     

High expression of the R-type voltage-gated Ca2+ channel and its involvement in Ca2+-dependent gonadotropin-releasing hormone release in GT1-7 cells

The GT1 cell has been widely used as a model cell to study cellular functions of GnRH neurons. Despite the importance of Ca(2+) channels, little is known except for L- and T-type Ca(2+) channels in GT1 cells. Therefore, we studied the diversity of voltage-gated Ca(2+) channels in GT1-7 cells with perforated-patch clamp and RT-PCR. An R-type Ca(2+) channel blocker, SNX-482, inhibited the Ca(2+) currents by 75.6% in all cells examined (n = 9). A T-type Ca(2+) channel blocker, Ni(2+), inhibited the Ca(2+) currents by 12.6% in all cells examined (n = 9). An L-type Ca(2+) channel blocker, nimodipine, inhibited the Ca(2+) currents by 17.9% in five of 11 cells examined. When using Ba(2+) as a charge carrier, another dihydropyridine antagonist, nifedipine, clearly inhibited the currents by 12.1% in all cells examined (n = 16). An N-type Ca(2+) channel blocker, omega-conotoxin-GVIA, inhibited the Ca(2+) currents by 13.8% in three of 20 cells examined. A P/Q type Ca(2+) channel blocker, omega-agatoxin-IVA, had no effect on the currents (n = 9). RT-PCR revealed that GT1-7 cells expressed the alpha(1B), alpha(1D), alpha(1E), and alpha(1H) subunit mRNA. Furthermore, SNX-482 and nifedipine inhibited the high K(+)-induced increase in the intracellular Ca(2+) concentration and GnRH release. omega-Conotoxin-GVIA and omega-agatoxin-IVA had no effect. These results suggest that GT1-7 cells express R-, L-, N-, and T-type voltage-gated Ca(2+) channels; the R-type was a major current component, and the L-, N-, and T-types were minor ones. The R- and L-type Ca(2+) channels play a critical role in the regulation of Ca(2+)-dependent GnRH release.     

The in vitro regulation of growth hormone secretion by orexins

Orexins, orexigenic neuropeptides, have recently been discovered in lateral hypothalamus and play an important role in the regulation of pituitary hormone secretion. Two subtypes of orexin receptors (orexin-1 and orexin-2) have been demonstrated in pituitaries. In this experiment, the effects of orexins on voltage-gated Ca2+ currents and the GH release in primary cultured ovine somatotropes were examined. Voltage-gated Ca2+ currents were isolated in ovine somatotropes as L, T, and N currents using whole-cell patch-clamp techniques and specific Ca2+ channel blocker and toxin. Application of orexin-A or orexin-B (100 nM) significantly, dose-dependently, and reversibly increased only nifedipine-sensitive L-type Ca2+ current. Inhibitors of PKC (calphostin C, PKC inhibitory peptide) but not inhibitors of PKA (H89, PKA inhibitory peptide) cancelled the increase in the L current by orexins. Co-administration of orexin-A and GHRH (10 nM) showed an additive effect on the L current. Specific intracellular Ca2+-store-depleting reagent, thapsigargin (1 microM), did not affect the orexin-induced increase in the L current. Orexin-B alone slightly increased GH release and co-administration of orexin-A and GHRH synergistically stimulated GH secretion in vitro. It is therefore suggested that orexins may play an important role in regulating GHRH-stimulated GH secretion through an increase in the L-type Ca2+ current and the PKC-mediated signaling pathways in ovine somatotropes.     

Reduction of Ca(2+) channel activity by hypoxia in human and porcine coronary myocytes.

OBJECTIVE: Oxygen (O(2)) tension is a major regulator of blood flow in the coronary circulation. Hypoxia can produce vasodilation through activation of ATP regulated K(+) (K(ATP)) channels in the myocyte membrane, which leads to hyperpolarization and closure of voltage-gated Ca(2+) channels. However, there are other O(2)-sensitive mechanisms intrinsic to the vascular smooth muscle since hypoxia can relax vessels precontracted with high extracellular K(+), a condition that prevents hyperpolarization following opening of K(+) channels. The objective of the present study was to determine whether inhibition of Ca(2+) influx through voltage-dependent channels participates in the response of coronary myocytes to hypoxia. METHODS: Experiments were performed on porcine anterior descendent coronary arterial rings and on enzymatically dispersed human and porcine myocytes of the same artery. Cytosolic [Ca(2+)] was measured by microfluorimetry and whole-cell currents were recorded with the patch clamp technique. RESULTS: Hypoxia (O(2) tension approximately 20 mmHg) dilated endothelium-denuded porcine coronary arterial rings precontracted with high K(+) in the presence of glibenclamide (5 microM), a blocker of K(ATP) channels. In dispersed human and porcine myocytes, low O(2) tension decreased basal cytosolic [Ca(2+)] and transmembrane Ca(2+) influx independently of K(+) channel activation. In patch clamped cells, hypoxia reversibly inhibited L-type Ca(2+) channels. RT-PCR indicated that rHT is the predominant mRNA variant of the alpha(1C) Ca(2+) channel subunit in human coronary myocytes. CONCLUSION: Our study demonstrates, for the first time in a human preparation, that voltage-gated Ca(2+)channels in coronary myocytes are under control of O(2) tension.     

Calcium exerts a larger regulatory effect on potassium+ channels in small mesenteric artery mycoytes from spontaneously hypertensive rats compared to Wistar-Kyoto rats

Hypertension is associated with a remodeling of arterial smooth muscle K(+) channels with Ca(2+)-gated K(+) channel (BK(Ca)) activity being enhanced and voltage-gated K(+) channel (K(v)) activity depressed. Because both of these channel types are modulated by intracellular Ca(2+), we tested the hypothesis that Ca(2+) had a larger effect on both BK(Ca) and K(v) channels in arterial myocytes from hypertensive animals. Myocytes were enzymatically dispersed from small mesenteric arteries (SMA) of 12-week-old Wistar-Kyoto rats (WKY) and spontaneously hypertensive rats (SHR). Using whole cell patch clamp methods, BK(Ca) and K(v) current components were determined as iberiotoxin-sensitive and -insensitive currents, respectively. The effects of Ca(2+) on these K(+) current components were determined from measurements made with 0.2 and 2 mmol/L external Ca(2+). Increasing external Ca(2+) from 0.2 to 2 mmol/L Ca(2+) increased BK(Ca) currents recorded using myocytes from both WKY rats and SHR with a larger effect in SHR. Increasing external Ca(2+) decreased K(v) currents recorded using myocytes from both WKY and SHR also with a larger effect in SHR. In other experiments, currents through voltage-gated Ca(2+) channels (Ca(v)) measured at 0.2 mmol/L external Ca(2+) were 12 +/- 2% (n = 12) of those recorded at 2 mmol/L Ca(2+) with no differences in percent effect between WKY and SHR. In isolated SMA segments, isometric force development in response to 140 mmol/L KCl at 0.2 mmol/L external Ca(2+) was about 23 +/- 6% (n = 8) of that measured at 2 mmol/L external Ca(2+). These results suggest that an increase in Ca(2+) influx through Ca(v) or in intracellular Ca(2+) secondary to an increase in external Ca(2+) augments BK(Ca) currents and inhibits K(v) currents in SMA myocytes with a larger effect in SHR compared to WKY. This mechanism may contribute to the functional remodeling of K(+) currents of arterial myocytes in hypertensive animals.     

Role of K(+) channels in frequency regulation of spontaneous action potentials in rat pituitary GH(3) cells

The frequency of spontaneous action potentials (SAP) is important in the regulation of hormone secretion. The decrease in K(+) conductance is known as a primary mechanism for increasing SAP frequency. To investigate the nature of K(+) channels that contribute to the frequency regulation of the SAP in rat clonal pituitary GH(3) cells, the effect of various K(+) channel blockers on the SAP and membrane currents were recorded using the patch-clamp technique. A classical inward rectifying K(+) channel blocker, Cs(+) (5 mM), caused an increase in firing frequency and depolarization in after-hyperpolarization (AHP) voltage. An ETHER-A-GO-GO(ERG) type K(+) channel blocker, E-4031 (5 microM), caused no significant effect on the SAP. Tetraethylammonium (TEA, 10 mM) decreased firing frequency and increased the duration of SAP. These effects were not changed by the presence of high concentration of Ca(2+) buffer (10 mM EGTA or BAPTA) in pipette solutions. In voltage-clamp experiments, Cs(+) and E-4031 did not affect outwardly rectifying K(+) currents, but significantly inhibited inwardly rectifying K(+) currents recorded in isotonic K(+) solution. However, the kinetics of Cs(+)-sensitive current and E-4031-sensitive current were distinctive: the time to peak was more immediate and the decay rate was slower in Cs(+)-sensitive current than in E-4031-sensitive current. These results imply that Cs(+) and E-4031 inhibit the distinct components of inwardly rectifying K(+) currents, and that the contribution of the Cs(+)-sensitive current can be immediate on repolarization and can last more effectively over pacemaking potential range than E-4031-sensitive current.     

Pore collapse underlies irreversible inactivation of TRPM2 cation channel currents

The Ca(2+)-permeable cation channel transient receptor potential melastatin 2 (TRPM2) plays a key role in pathogen-evoked phagocyte activation, postischemic neuronal apoptosis, and glucose-evoked insulin secretion, by linking these cellular responses to oxidative stress. TRPM2 channels are coactivated by binding of intracellular ADP ribose and Ca(2+) to distinct cytosolically accessible sites on the channels. These ligands likely regulate the activation gate, conserved in the voltage-gated cation channel superfamily, that comprises a helix bundle formed by the intracellular ends of transmembrane helix six of each subunit. For several K(+) and TRPM family channels, activation gate opening requires the presence of phosphatidylinositol-bisphosphate (PIP(2)) in the inner membrane leaflet. Most TRPM family channels inactivate upon prolonged stimulation in inside-out patches; this "rundown" is due to PIP(2) depletion. TRPM2 currents also run down within minutes, but the molecular mechanism of this process is unknown. Here we report that high-affinity PIP(2) binding regulates Ca(2+) sensitivity of TRPM2 activation. Nevertheless, TRPM2 inactivation is not due to PIP(2) depletion; rather, it is state dependent, sensitive to permeating ions, and can be completely prevented by mutations in the extracellular selectivity filter. Introduction of two negative charges plus a single-residue insertion, to mimic the filter sequence of TRPM5, results in TRPM2 channels that maintain unabated maximal activity for over 1 h, and display altered permeation properties but intact ADP ribose/Ca(2+)-dependent gating. Thus, upon prolonged stimulation, the TRPM2 selectivity filter undergoes a conformational change reminiscent of that accompanying C-type inactivation of voltage-gated K(+) channels. The noninactivating TRPM2 variant will be invaluable for gating studies.     

Role of Ca2+-activated K+ channels on adrenergic responses of human saphenous vein

BACKGROUND: We studied the participation of K(+) channels on the adrenergic responses in human saphenous veins as well as the intervention of dihydropyridine-sensitive Ca(2+) channels on modulation of adrenergic responses by K(+) channels blockade. METHODS: Saphenous vein rings were obtained from 40 patients undergoing coronary artery bypass surgery. The vein rings were suspended in organ bath chambers for isometric recording of tension. RESULTS: Iberiotoxin (10(-7) mol/L), an inhibitor of large conductance Ca(2+)-activated K(+) channels, and charybdotoxin (10(-7) mol/L), an inhibitor of both large and intermediate conductance Ca(2+)-activated K(+) channels, enhanced the contractions elicited by electrical field stimulation and produced a leftward shift of the concentration-response curve to norepinephrine. In contrast, the inhibitor of small conductance Ca(2+)-activated K(+) channels apamin (10(-6) mol/L) did not modify the contractile response to electrical field stimulation or norepinephrine. In the presence of the dihydropyridine Ca(2+)-channel blocker nifedipine (10(-6) mol/L), iberiotoxin and charybdotoxin failed to enhance the contractile responses to electrical field stimulation and norepinephrine. CONCLUSIONS: The results suggest that large conductance Ca(2+)-activated K(+) channels are activated by stimulation with norepinephrine to counteract the adrenergic-induced contractions of human saphenous vein. Thus, inhibition of these channels increases significantly the contraction, an effect that appears to be mediated by an increase in Ca(2+) entry through L-type voltage-dependent Ca(2+) channels.     

Cardiac IK1 underlies early action potential shortening during hypoxia in the mouse heart

It is established that prolonged hypoxia leads to activation of K(ATP) channels and action potential (AP) shortening, but the mechanisms behind the early phase of metabolic stress remain controversial. Under normal conditions IK1 channels are constitutively active while K(ATP) channels are closed. Therefore, early changes in IK1 may underlie early AP shortening. This hypothesis was tested using transgenic mice with suppressed IK1 (AAA-TG). In isolated AAA-TG hearts AP shortening was delayed by approximately 24 s compared to WT hearts. In WT ventricular myocytes, blocking oxidative phosphorylation with 1 mM cyanide (CN; 28 degrees C) led to a 29% decrease in APD90 within approximately 3-5 min. The effect of CN was reversed by application of 100 microM Ba2+, a selective blocker of IK1, but not by 10 microM glybenclamide, a selective blocker of KATP channels. Accordingly, voltage-clamp experiments revealed that both CN and true hypoxia lead to early activation of IK1. In AAA-TG myocytes, neither CN nor glybenclamide or Ba2+ had any effect on AP. Further experiments showed that buffering of intracellular Ca2+ with 20 mM BAPTA prevented IK1 activation by CN, although CN still caused a 54% increase in IK1 in a Ca2+ -free bath solution. Importantly, both (i) 20 microM ruthenium red, a selective inhibitor of SR Ca2+ -release, and (ii) depleting SR by application of 10 microM ryanodine+1 mM caffeine, abolished the activation of IK1 by CN. The above data strongly argue that in the mouse heart IK1, not KATP, channels are responsible for the early AP shortening during hypoxia.     

Inhibition of T cell proliferation by selective block of Ca2+-activated K+ channels

T lymphocytes express a plethora of distinct ion channels that participate in the control of calcium homeostasis and signal transduction. Potassium channels play a critical role in the modulation of T cell calcium signaling, and the significance of the voltage-dependent K channel, Kv1.3, is well established. The recent cloning of the Ca(2+)-activated, intermediate-conductance K(+) channel (IK channel) has enabled a detailed investigation of the role of this highly Ca(2+)-sensitive K(+) channel in the calcium signaling and subsequent regulation of T cell proliferation. The role IK channels play in T cell activation and proliferation has been investigated by using various blockers of IK channels. The Ca(2+)-activated K(+) current in human T cells is shown by the whole-cell voltage-clamp technique to be highly sensitive to clotrimazole, charybdotoxin, and nitrendipine, but not to ketoconazole. Clotrimazole, nitrendipine, and charybdotoxin block T cell activation induced by signals that elicit a rise in intracellular Ca(2+)-e.g., phytohemagglutinin, Con A, and antigens such as Candida albicans and tetanus toxin in a dose-dependent manner. The release of IFN-gamma from activated T cells is also inhibited after block of IK channels by clotrimazole. Clotrimazole and cyclosporin A act synergistically to inhibit T cell proliferation, which confirms that block of IK channels affects the process downstream from T cell receptor activation. We suggest that IK channels constitute another target for immune suppression.     

Nateglinide,but not repaglinide,stimulates growth hormone release in rat pituitary cells by inhibition of K channels and stimulation of cyclic AMP-dependent exocytosis

OBJECTIVE: GH causes insulin resistance, impairs glycemic control and increases the risk of vascular diabetic complications. Sulphonylureas stimulate GH secretion and this study was undertaken to investigate the possible stimulatory effect of repaglinide and nateglinide, two novel oral glucose regulators, on critical steps of the stimulus-secretion coupling in single rat somatotrophs. METHODS: Patch-clamp techniques were used to record whole-cell ATP-sensitive K(+) (K(ATP)) and delayed outward K(+) currents, membrane potential and Ca(2+)-dependent exocytosis. GH release was measured from perifused rat somatotrophs. RESULTS: Both nateglinide and repaglinide dose-dependently suppressed K(ATP) channel activity with half-maximal inhibition being observed at 413 nM and 13 nM respectively. Both compounds induced action potential firing in the somatotrophs irrespective of whether GH-releasing hormone was present or not. The stimulation of electrical activity by nateglinide, but not repaglinide, was associated with an increased mean duration of the action potentials. The latter effect correlated with a reduction of the delayed outward K(+) current, which accounts for action potential repolarization. The latter effect had a K(d) of 19 microM but was limited to 38% inhibition. When applied at concentrations similar to those required to block K(ATP) channels, nateglinide in addition potentiated Ca(2+)-evoked exocytosis 3.3-fold (K(d)=3 microM) and stimulated GH release 4.5-fold. The latter effect was not shared by repaglinide. The stimulation of exocytosis by nateglinide was mimicked by cAMP and antagonized by the protein kinase A inhibitor Rp-cAMPS. CONCLUSION: Nateglinide stimulates GH release by inhibition of plasma membrane K(+) channels, elevation of cytoplasmic cAMP levels and stimulation of Ca(2+)-dependent exocytosis. By contrast, the effect of repaglinide was confined to inhibition of the K(ATP) channels.     

Role of BK potassium channels shaping action potentials and the associated [Ca(2+)](i) oscillations in GH(3) rat anterior pituitary cells

Measurements of electrical activity and intracellular Ca(2+) levels were performed in perforated-patch clamped GH(3) cells to determine the contribution of large-conductance calcium-activated K(+) (BK) channels to action potential repolarization and size of the associated Ca(2+) oscillations. By examining the dependence of action potential (AP) duration on extracellular Ca(2+) levels in the presence and the absence of the specific BK channel blocker paxilline, it is observed that plateau-like action potentials are associated to low densities of paxilline-sensitive currents. Extracellular Ca(2+) increases or paxilline additions are not able to largely modify action potential duration in cells showing a reduced expression of BK currents. Furthermore, specific blockade of these currents with paxilline systematically elongates AP duration, but only under conditions in which short APs and/or prominent BK currents recorded under voltage-clamp mode are present in the same cells. Our data indicate that in GH(3) cells, BK channels act primarily ending the action potential and suggest that by contributing to fine-tuning cellular electrical properties and hence intracellular Ca(2+) variations, BK channels may play an important role on time- and cell-dependent modulation of physiological outputs in adenohypophyseal cells.     

Inhibition of ultra-rapid delayed rectifier K+ current by verapamil in human atrial myocytes

Verapamil is a widely used Ca(2+) channel antagonist in the treatment of cardiovascular disorders including atrial arrhythmias. However, it is unknown whether the drug would inhibit the repolarization currents transient outward K(+) current (I(to1)) and ultra-rapid delayed rectifier K(+) current (I(Kur)) in human atrium. With whole-cell patch configuration, we evaluated effects of verapamil on I(to1) and I(Kur) in isolated human atrial myocytes. It was found that verapamil did not decrease I(to1) at 1-50 microM. However, verapamil reversibly inhibited I(Kur) in a concentration-dependent manner (IC(50) = 3.2 microM). At test potential of +50 mV, 5 microM verapamil decreased I(Kur) by 61.3 +/- 7.5%. Verapamil significantly accelerated inactivation of I(Kur), suggesting an open channel block mechanism. The results indicate that verapamil significantly blocks the repolarization K(+) current I(Kur), but not I(to1), in human atrial atrium, which may account at least in part for the atrial effect of the drug.     

Cilostazol, an inhibitor of type 3 phosphodiesterase, stimulates large-conductance, calcium-activated potassium channels in pituitary GH3 cells and pheochromocytoma PC12 cells

The effects of cilostazol, a dual inhibitor of type 3 phosphodiesterase and adenosine uptake, on ion currents were investigated in pituitary GH(3) cells and pheochromocytoma PC12 cells. In whole-cell configuration, cilostazol (10 microm) reversibly increased the amplitude of Ca(2+)-activated K(+) current [I(K(Ca))]. Cilostazol-induced increase in I(K(Ca)) was suppressed by paxilline (1 microM) but not glibenclamide (10 microm), dequalinium dichloride (10 microM), or beta-bungarotoxin (200 nM). Pretreatment of adenosine deaminase (1 U/ml) or alpha,beta-methylene-ADP (100 microM) for 5 h did not alter the magnitude of cilostazol-stimulated I(K(Ca)). Cilostazol (30 microM) slightly suppressed voltage-dependent l-type Ca(2+) current. In inside-out configuration, bath application of cilostazol (10 microM) into intracellular surface caused no change in single-channel conductance; however, it did increase the activity of large-conductance Ca(2+)-activated K(+) (BK(Ca)) channels. Cilostazol enhanced the channel activity in a concentration-dependent manner with an EC(50) value of 3.5 microM. Cilostazol (10 microM) shifted the activation curve of BK(Ca) channels to less positive membrane potentials. Changes in the kinetic behavior of BK(Ca) channels caused by cilostazol were related to an increase in mean open time and a decrease in mean closed time. Under current-clamp configuration, cilostazol decreased the firing frequency of action potentials. In pheochromocytoma PC12 cells, cilostazol (10 microM) also increased BK(Ca) channel activity. Cilostazol-mediated stimulation of I(K(Ca)) appeared to be not linked to its inhibition of adenosine uptake or phosphodiesterase. The channel-stimulating properties of cilostazol may, at least in part, contribute to the underlying mechanisms by which it affects neuroendocrine function.     

Physiological significance of SK4 channels in pancreatic β-cell oscillations

Pancreatic beta-cells show oscillations in membrane potential (Vm), the cytosolic Ca (2+) concentration ([Ca (2+) ]c) and finally insulin secretion. It is well accepted that the initiation of a burst phase with action potentials is mediated by voltage-dependent Ca (2+) (and Na (+) ) channels. The mechanism triggering the onset of interburst phases is less clear. The exact nature of the K (+) channels that hyperpolarize Vm to maintain the rhythmic activity is unknown. In 1999 G?pel and co-workers (1) described a current termed Kslow and claimed that this current terminates the burst phases. KATP current is a part of the Kslow current. We could show that the Ca (2+) -dependent K (+) current through K (+) channels of intermediate conductance (SK4, KCa3.1 or IK1) also contributes to the Kslow current. We suggest that the Kslow current is composed of two currents through metabolism-regulated K (+) channels, KATP (regulated by ATP) and SK4 (regulated by Ca (2+) ). We further propose that the SK4 component of the Kslow current can trigger oscillations in mice without functioning KATP channels.     

Calcium and small-conductance calcium-activated potassium channels in gonadotropin-releasing hormone neurons before, during, and after puberty

The pubertal increase in GnRH secretion resulting in sexual maturation and reproductive competence is a complex process involving kisspeptin stimulation of GnRH neurons and requiring Ca(2+) and possibly other intracellular messengers. To determine whether the expression of Ca(2+) channels, or small-conductance Ca(2+)-activated K(+) (SK) channels, whose activity reflects cytoplasmic free Ca(2+) concentration, changes at puberty in GnRH neurons, Ca(2+) and SK currents in GnRH neurons were recorded in brain slices of juvenile [postnatal day (P) 10-21], pubertal (P28-P42), and adult (> or =P56) male GnRH-green fluorescent protein transgenic mice using perforated-patch and whole-cell techniques. Ca(2+) currents were inhibited by the Ca(2+) channel blocker Cd(2+) and showed marked heterogeneity but were on average similar in juvenile, pubertal, and adult GnRH neurons. SK currents, which were inhibited by the SK channel blocker apamin and enhanced by the SK and intermediate-conductance Ca(2+)-activated K(+) channel activator 1-ethyl-2-benzimidazolinone, were also on average similar in juvenile, pubertal, and adult GnRH neurons. These findings suggest that whereas Ca(2+) and SK channels may participate in the pubertal increase in GnRH secretion and there may be changes in Ca(2+) or SK channel subtypes, overall Ca(2+) and SK channel expression in GnRH neurons remains relatively constant across pubertal development. Hence, the expected increase in GnRH neuron cytoplasmic free Ca(2+) concentration required for increased GnRH secretion at puberty appears to be due to mechanisms other than altered Ca(2+) or SK channel expression, e.g. increased membrane depolarization and subsequent activation of preexisting Ca(2+) channels after increased excitatory synaptic input.