Regulation of the L-type Ca2+ channel current in rat pinealocytes: role of basal phosphorylation

Noradrenaline upregulates T-type calcium channels in rat pinealocytes

KEY POINTS

The mammalian pineal gland is a neuroendocrine organ that responds to circadian and seasonal rhythms. Its major function is to secrete melatonin as a hormonal night signal in response to nocturnal delivery of noradrenaline from sympathetic neurons. Culturing rat pinealocytes in noradrenaline for 24 h induced a low-voltage activated transient Ca(2+) current whose pharmacology and kinetics corresponded to a CaV3.1 T-type channel. The upregulation of the T-type Ca(2+) current is initiated by β-adrenergic receptors, cyclic AMP and cyclic AMP-dependent protein kinase. Messenger RNA for CaV3.1 T-type channels is significantly elevated by noradrenaline at 8 h and 24 h. The noradrenaline-induced T-type channel mediated an increased Ca(2+) entry and supported modest transient electrical responses to depolarizing stimuli, revealing the potential for circadian regulation of pinealocyte electrical excitability and Ca(2+) signalling.

ABSTRACT

Our basic hypothesis is that mammalian pinealocytes have cycling electrical excitability and Ca(2+) signalling that may contribute to the circadian rhythm of pineal melatonin secretion. This study asked whether the functional expression of voltage-gated Ca(2+) channels (CaV channels) in rat pinealocytes is changed by culturing them in noradrenaline (NA) as a surrogate for the night signal. Channel activity was assayed as ionic currents under patch clamp and as optical signals from a Ca(2+)-sensitive dye. Channel mRNAs were assayed by quantitative polymerase chain reaction. Cultured without NA, pinealocytes showed only non-inactivating L-type dihydropyridine-sensitive Ca(2+) current. After 24 h in NA, additional low-voltage activated transient Ca(2+) current developed whose pharmacology and kinetics corresponded to a T-type CaV3.1 channel. This change was initiated by β-adrenergic receptors, cyclic AMP and protein kinase A as revealed by pharmacological experiments. mRNA for CaV3.1 T-type channels became significantly elevated, but mRNA for another T-type channel and for the major L-type channel did not change. After only 8 h of NA treatment, the CaV3.1 mRNA was already elevated, but the transient Ca(2+) current was not. Even a 16 h wait without NA following the 8 h NA treatment induced little additional transient current. However, these cells were somehow primed to make transient current as a second NA exposure for only 60 min sufficed to induce large T-type currents. The NA-induced T-type channel mediated an increased Ca(2+) entry during short depolarizations and supported modest transient electrical responses to depolarizing stimuli. Such experiments reveal the potential for circadian regulation of excitability.

Norepinephrine causes a biphasic change in mammalian pinealocye membrane potential: role of alpha1B-adrenoreceptors, phospholipase C, and Ca2+

Perforated patch clamp recording was used to study the control of membrane potential (V(m)) and spontaneous electrical activity in the rat pinealocyte by norepinephrine. Norepinephrine did not alter spiking frequency. However, it was found to act through α(1B)-adrenoreceptors in a concentration-dependent manner (0.1-10 μM) to produce a biphasic change in V(m). The initial response was a hyperpolarization (∼13 mV from a resting potential of -46 mV) due to a transient (∼5 sec) outward K(+) current (∼50 pA). This current appears to be triggered by Ca(2+) released from intracellular stores, based on the observation that it was also seen in cells bathed in Ca(2+)-deficient medium. In addition, pharmacological studies indicate that this current was dependent on phospholipase C (PLC) activation and was in part mediated by bicuculline methiodide and apamin-sensitive Ca(2+)-controlled K(+) channels. The initial transient hyperpolarization was followed by a sustained depolarization (∼4 mV) due to an inward current (∼10 pA). This response was dependent on PLC-dependent activation of Na(+)/Ca(2+) influx but did not involve nifedipine-sensitive voltage-gated Ca(2+) channels. Together, these results indicate for the first time that activation of α(1B)-adrenoreceptors initiates a PLC-dependent biphasic change in pinealocyte V(m) characterized by an initial transient hyperpolarization mediated by a mixture of Ca(2+)-activated K(+) channels followed by a sustained depolarization mediated by a Ca(2+)-conducting nonselective cation channel. These observations indicate that both continuous elevation of intracellular Ca(2+) and sustained depolarization at approximately -40 mV are associated with and are likely to be required for activation of the pinealocyte.

Inhibitors of serine/threonine protein phosphatases antagonize the antinociception induced by agonists of alpha 2 adrenoceptors and GABAB but not kappa-opioid receptors in the tail flick test in mice

We previously reported that serine/threonine protein phosphatases (PPs) play a role in the antinociception induced by the mu-opioid receptor agonist morphine. In this study we evaluated the possible involvement of PPs on the antinociception induced by agonists of others G protein-coupled receptors in the tail flick test in mice. The subcutaneous administration of clonidine (0.25-4 mg/kg), baclofen (2-32 mg/kg) or U50,488H (2-16 mg/kg) (agonists of alpha(2) adrenoceptors, GABA(B) and kappa-opioid receptors, respectively) produced dose-dependent antinociception. The antinociceptive effects of clonidine and baclofen were antagonized in a dose-dependent way by the protein phosphatase inhibitors okadaic acid (0.001-10 pg/mouse, i.c.v.) and cantharidin (0.001-10 ng/mouse, i.c.v.), and okadaic acid was 1000 times more potent than cantharidin in producing this effect. The effects of these drugs appear to be specifically due to the blockade of PPs, since L-norokadaone (an analogue of okadaic acid that has no effect on PPs) did not modify clonidine- or baclofen-induced antinociception over the wide range of doses used (0.001-1000 pg/mouse, i.c.v.). On the other hand, the antinociception induced by activation of kappa-opioid receptors with U50,488H was not modified by okadaic acid or cantharidin. In conclusion, our data support the idea that serine/threonine PPs are differentially involved in the antinociceptive effects of several agonists of G protein-coupled receptors in mice.

Protein kinase C inhibits the transplasma membrane influx of Ca2+ triggered by 4-aminopyridine in Jurkat T lymphocytes

4-aminopyridine (4AP) is a general blocker of voltage-dependent K+ channels. This pyridine derivative has also been shown to inhibit T cell proliferation, to modulate immune responses and to alleviate some of the symptoms associated with neurological disorders such as multiple sclerosis, myasthenia gravis and Alzheimer's disease. 4AP triggers a Ca2+ response in lymphocytes, astrocytes, neurons and muscle cells but little is known about the regulation of the 4AP response in these cells. We report that 4AP induced a non-capacitative transplasma membrane influx of Ca2+ in Jurkat T lymphocytes. The influx of Ca2+ was not affected by activation or inhibition of protein kinase A (PKA). In contrast, activation of protein kinase C (PKC) by phorbol myristyl acetate (PMA), mezerein or 1-oleoyl-2-acetyl-sn-glycerol (OAG) inhibited the influx of Ca2+ triggered by 4AP. The inhibitory effect of PKC could be prevented by prior exposure of the cells to the PKC inhibitor GF 109203X. Under these conditions, mezerein and OAG no longer inhibited the 4AP-dependent Ca2+ response. Inhibition of serine and threonine protein phosphatases PP1 and PP2A by treating the cells with calyculin A (CalA) reduced the Ca2+ response to 4AP. Okadaic acid (OA) had no effect, suggesting an involvement of PP1. A combination of CalA and OAG (or PMA) abolished the influx of Ca2+ induced by 4AP, adding further evidence to the importance of protein phosphorylation in the modulation of the 4AP response. Our data suggest that the transplasma membrane influx of Ca2+ triggered by 4AP in Jurkat T cells can be modulated by the opposite actions of PKC and protein serine and threonine phosphatase(s).

Calyculin A and outward K+ channel currents in rat tail artery smooth muscle cells

Protein dephosphorylation mediated by phosphatases represents an important mechanism for modulating the functions of the targeted proteins. Calyculin A has been extensively used as a specific inhibitor of protein phosphatases. However, the effect of calyculin A on K channel currents in vascular smooth muscle cells (SMCs) and the underlying mechanisms had been unknown. It was found in the current study that calyculin A inhibited the whole-cell outward K channel currents in rat tail artery SMCs in a concentration-dependent (median inhibitory concentration, 12.6 n ) and reversible fashion. The extracellular applied calyculin A induced a biphasic change in K current amplitude with an initial transient increase followed by a long-lasting inhibition (n = 6). The intracellularly applied calyculin A (100 nM ) caused a lesser inhibition (33 +/- 1%) of K channel currents than that caused by the extracellularly applied calyculin A (55.3 +/- 8% inhibition) and did not result in an initial increase in K channel currents. The inhibitory effect of the intracellularly applied calyculin A on K channel currents was reversed to a stimulatory effect after ATP was omitted from the intracellular solution. The K currents inhibited by calyculin A were conducted by the iberiotoxin-sensitive K channels in SMCs. Moreover, okadaic acid (0.03-3 microM ) did not cause any significant change in K(Ca) channel currents. In conclusion, calyculin A inhibited K(Ca) channel currents in vascular SMCs. This effect of calyculin A, however, was not mediated by the inhibition of protein phosphatases.

Phorbol ester stimulates a protein kinase C-mediated agatoxin-TK-sensitive calcium permeability pathway in human red blood cells

Calcium entry into mature erythrocytes (red blood cells; RBCs) is associated with multiple changes in cell properties. At low intracellular Ca(2+), efflux of potassium and water predominates, leading to changes in erythrocyte rheology. At higher Ca(2+) content, activation of kinases and phosphatases, rupture of membrane-to-skeleton bridges, stimulation of a phospholipid scramblase and phospholipase C, and induction of transglutaminase-mediated protein cross-linking are also observed. Because the physiologic relevance of these latter responses depends partially on whether Ca(2+) entry involves a regulated channel or nonspecific leak, we explored mechanisms that initiate controlled Ca(2+) influx. Protein kinase C (PKC) was considered a prime candidate for the pathway regulator, and phorbol-12 myristate-13 acetate (PMA), a stimulator of PKC, was examined for its influence on erythrocyte Ca(2+). PMA was found to stimulate a rapid, dose-dependent influx of calcium, as demonstrated by the increased fluorescence of an entrapped Ca(2+)-sensitive dye, Fluo-3/AM. The PMA-induced entry was inhibited by staurosporine and the PKC-selective inhibitor chelerythrine chloride, but was activated by the phosphatase inhibitors okadaic acid and calyculin A. The PMA-promoted calcium influx was also inhibited by omega-agatoxin-TK, a calcium channel blocker specific for Ca(v)2.1 channels. To confirm that a Ca(v)2.1-like calcium channel exists in the mature erythrocyte membrane, RBC membrane preparations were immunoblotted with antiserum against the alpha(1A) subunit of the channel. A polypeptide of the expected molecular weight (190 kDa) was visualized. These studies indicate that an omega-agatoxin-TK-sensitive, Ca(v)2.1-like calcium permeability pathway is present in the RBC membrane and that it may function under the control of kinases and phosphatases.

Ceramide inhibits the outward potassium current in rat pinealocytes

In the present study, we investigated the effect of ceramide on the outward K(+) current in rat pinealocytes using whole cell and single channel recordings. Three components of the whole cell outward K(+) current were separated, an iberiotoxin (IBTX)-sensitive K(+) current (I(KCa)), a transient A current (I(A)) and a delayed rectifier current (I(K)). C6-ceramide reduced all three components of the outward K(+) current. C6-ceramide (30 microM) caused a 53% inhibition of I(KCa) [a component that is generated by the IBTX-sensitive K(+) channel (BK channel)], a 27% inhibition of I(A) and a 17% inhibition of I(K). Additional studies showed that the BK channel was not inhibited by dihydroC6-ceramide, the inactive analog of C6-ceramide, but mimicked by sphingomyelinase which increased intracellular ceramide. The ceramide inhibition of the BK channel was only partly dependent on its inhibition of the L-type Ca(2+) channel. Studies using specific kinase inhibitors showed that calphostin C (a protein kinase C inhibitor) and to a lesser degree lavendustin A (a tyrosine kinase inhibitor) were effective in reducing the ceramide inhibition of I(KCa). Taken together, our results show that, in rat pinealocytes, ceramide reduces the outward K(+) current predominantly by inhibiting I(KCa). Moreover, protein kinase C appears to be the main kinase involved in the ceramide inhibition of I(KCa).

Estrogen modulates alpha(1)/beta-adrenoceptor- induced signaling and melatonin production in female rat pinealocytes

Nocturnal rise in pineal melatonin output is due to the night-induced acceleration of noradrenergic transmission and alpha(1)- and beta-adrenoceptor activation. In addition, in female animals, cyclic oscillations in circulating levels of sex steroid hormones are accompanied by changes in the rate of pineal melatonin secretion. To investigate whether estrogen directly affects pineal adrenoceptor responsiveness, pinealocytes from 21-day-old ovariectomized rats were exposed to physiological concentrations of 17beta-estradiol (17beta-E(2)) and treated with noradrenergic agonists. Direct exposure to 17beta-E(2) reduced alpha(1)/beta-adrenoceptor-induced stimulation of melatonin synthesis and release. This effect was mediated by an estrogen-dependent inhibition of both beta-adrenoceptor-induced accumulation of cAMP and alpha(1)-adrenoceptor-induced phosphoinositide hydrolysis. Furthermore, estrogen reduced transient Ca(2+) signals elicited in single pinealocytes by alpha(1)-adrenoceptor activation or by potassium-induced depolarization. In the case of beta-adrenoceptor responsiveness, neither forskolin- nor cholera toxin-induced accumulation of cAMP were affected by previous exposure to 17beta-E(2). This indicates that estrogen effects must be exerted upstream from adenylylcyclase activation, and independent of modifications in G protein expression, therefore suggesting changes in either adrenoceptor expression or receptor-effector coupling mechanisms. Since estrogen effects upon adrenoceptor responsiveness in pineal cells was not mimicked by 17beta-E(2) coupled to bovine serum albumin and showed a latency of 48 h, this effect could be compatible with a genomic action mechanism. This is also consistent with the presence of two estrogen receptor proteins, alpha- and beta-subtypes, in female rat pinealocytes under the present experimental conditions.

Effect of APGW-amide on [Ca2+]i in rat pheochromocytoma PC12 cells

In order to determine whether Ala-Pro-Gly-Try-NH2 (APGW-amide) could affect mammalian excitable cells, we investigated the effect of APGW-amide in PC12 cells. APGW-amide caused a rapid [Ca2+]i elevation, which was completely prevented by elimination of extracellular Ca2+ with EGTA and inhibited by two L-type Ca2+ channel blockers. [Ca2+]i elevation was also blocked by a specific PKC inhibitor and prolonged pretreatment of cells with PMA. These results indicate that APGW-amide elevates [Ca2+]i in PC12 cells, possibly by Ca2+ influx via L-type Ca2+ channel activated by PKC.

Molecular diversity of cyclic AMP signalling

Several neuroendocrine control systems are prominently controlled by G-protein coupled receptors that activate the cAMP signal transduction pathway. The discovery of multiple genes that encode the molecular machinery of cAMP metabolism has revolutionized our knowledge of cAMP mediated processes. This perhaps all too familiar second messenger can be generated by nine different membrane enzymes in the context of varied levels of activation of G proteins as well as Ca(2+)- and protein kinase C-dependent processes. The amplitude, length and subcellular distribution of the cAMP signal are further modulated by over twenty functionally distinct isotypes of cAMP-degrading phosphodiesterases in a cell- and stimulus-specific manner. The present review summarizes the key properties of the molecular machinery that generates the cAMP signal and highlights how it is deployed in neuroendocrine systems.

Effects of serine/threonine protein phosphatases on ion channels in excitable membranes

This review deals with the influence of serine/threonine-specific protein phosphatases on the function of ion channels in the plasma membrane of excitable tissues. Particular focus is given to developments of the past decade. Most of the electrophysiological experiments have been performed with protein phosphatase inhibitors. Therefore, a synopsis is required incorporating issues from biochemistry, pharmacology, and electrophysiology. First, we summarize the structural and biochemical properties of protein phosphatase (types 1, 2A, 2B, 2C, and 3-7) catalytic subunits and their regulatory subunits. Then the available pharmacological tools (protein inhibitors, nonprotein inhibitors, and activators) are introduced. The use of these inhibitors is discussed based on their biochemical selectivity and a number of methodological caveats. The next section reviews the effects of these tools on various classes of ion channels (i.e., voltage-gated Ca(2+) and Na(+) channels, various K(+) channels, ligand-gated channels, and anion channels). We delineate in which cases a direct interaction between a protein phosphatase and a given channel has been proven and where a more complex regulation is likely involved. Finally, we present ideas for future research and possible pathophysiological implications.

Endothelin-induced prostacyclin production in rat aortic endothelial cells: role of calcium

Endothelin (ET) is a potent vasoconstrictor peptide, released from endothelial cells, which is associated with prostaglandin (PG) release. The mechanism by which ET causes the release of PG is not clearly understood. We used rat aortic endothelial cells to investigate the role of calcium (Ca2+) in ET-1-induced prostacyclin (PGI2) release. ET-1 (10(-9) M) produced a significant increase in PGI2 release. Pretreatment of rat aortic endothelial cells with different doses (10(-9) M and 10(-6) M) of diltiazem (voltage-sensitive L-type calcium channel blocker) produced significant inhibition of ET-1- and PDBu-induced PGI2 release. Inhibition was first noted at 10(-9) M and was complete at 10(-6) M. Conversely, pretreatment of rat aortic endothelial cells with different doses (10(-9) M and 10(-6) M) of calcium channel blockers (thapsigargin, an intracellular calcium channel blocker or conotoxin, a voltage-sensitive N-type calcium channel blocker) produced no changes on ET-1- or PDBu-induced PGI2 release. These results provide further support for the concept that PKC mediates ET-induced PGI2 release in rat aortic endothelial cells via an increase in intracellular calcium and this increase is due to the influx of extracellular calcium and not to the release of calcium from the sarcoplasmic reticulum.