Tetrandrine, a Ca++ antagonist: effects and mechanisms of action in vascular smooth muscle cells

Tetrandrine, an alkaloid extracted from the Chinese medicinal herb Radix stephania tetrandrae, has traditionally been used to treat hypertension. In the present study, the effect of tetrandrine on vascular smooth muscle was investigated by using the rat tail artery as a model of a resistance vessel. Tetrandrine relaxes the tension in tail artery helical strips produced by depolarization with 60 mM KCl. Further studies show that tetrandrine inhibits the KCl-induced intracellular Ca++ increase and L-type voltage-dependent Ca++ channel currents, suggesting that tetrandrine relaxes the vessel via inhibition of Ca++ influx through Ca++ channels. Tetrandrine also inhibits norepinephrine (NE)-induced vasocontraction in the presence of extracellular Ca++. It does not, however, inhibit NE-induced vasocontraction in the absence of extracellular Ca++. Tetrandrine also inhibits the NE-induced intracellular Ca++ increase in the presence of extracellular Ca++ and has no effect on the NE-induced intracellular Ca++ increase in the absence of extracellular Ca++. This suggests that tetrandrine also blocks NE-induced Ca++ influx but not NE-induced Ca++ release from the intracellular Ca++ stores. Furthermore, tetrandrine inhibits thapsigargin-induced intracellular Ca++ concentration increase, suggesting that, in addition to blocking Ca++ influx, tetrandrine also may interfere with the interaction between thapsigargin and Ca++ adenosine triphosphatase.

Effects of three fragments of parathyroid hormone on calcium channel currents in neonatal rat ventricular cells

The effects of different fragments of bovine parathyroid hormone, bPTH-(1-34), bPTH-(1-84) and bPTH-(3-34), on two types of calcium channel currents in neonatal rat ventricular cells were compared in the present study. bPTH-(1-34) increased the amplitude of L channel currents, but not of the T channel currents. This effect of bPTH-(1-34) was sustained after a complete washout of the peptide from the bath. The intact PTH molecule, bPTH-(1-84), also increased L channel currents but not affecting T channel currents. While bPTH-(3-34) did not affect the amplitudes of either L or T channel currents by itself, pretreatment of cells with bPTH-(3-34) abolished the effects of both bPTH-(1-34) and bPTH-(1-84) on L channel currents. Moreover, the kinetics of L channel currents in the presence of bPTH-(1-34) or bPTH-(3-34) were different. bPTH-(1-34) increased the time constant of activation, but not of inactivation, of L channel currents from 1.8 to 2.5 ms (P < 0.05). In contrast, bPTH-(3-34) decreased the time constant of inactivation, but not of activation, of L channel currents from 159 to 117 ms (P < 0.05). These results indicate that different fragments of PTH exert different effects on the amplitudes or kinetics of cardiac calcium channel currents.

The L-type calcium channel current is increased by alpha-1 adrenoceptor activation in neonatal rat ventricular cells

The activation of alpha-1 adrenoceptors in adult rat ventricular cells results in the reduction of the transient outward K+ current, but does not affect Ca++ currents. In this study, using neonatal rat ventricular cells, the alpha-1 adrenergic receptor agonist phenylephrine increased the long-lasting (L-type) Ca++ channel current (dihydropyridine-sensitive) and the increase was concentration-dependent. Phenylephrine did not, however, modulate the transient-type (T-type) Ca++ channel current. The alpha-1 effect of phenylephrine was reversed or abolished by prazosin, an alpha-1 antagonist. The alpha-2 agonist clonidine had no effect on the L-type current. Yohimbine, an alpha-2 antagonist, and propranolol, a beta antagonist, did not inhibit the effect of phenylephrine on L-type current. The effect of phenylephrine was abolished by pretreatment with WB4101, an alpha-1A antagonist, but not by chloroethylclonidine, an alpha-1B antagonist. In addition, norepinephrine also increased the L-type current in the presence of propranolol and this effect was reversed by washout. These observations suggest that phenylephrine increased the L-type Ca++ channel current specifically through the activation of alpha-1A adrenergic receptors in neonatal rat ventricular myocytes. This may explain in part the increase in the plateau phase of the action potential and the positive inotropic response of the neonatal myocardium to phenylephrine. This is the first description of an increase in L-type Ca++ current by alpha-1A adrenoceptor activation in neonatal rat ventricular myocytes, and this effect is different from that reported in adult rat myocytes.

L-channel modulation by alpha-1 adrenoceptor activation in neonatal rat ventricular cells: intracellular mechanisms

The alpha adrenergic agonist phenylephrine increases the long-lasting Ca++ channel current (L-type Ca++ channel current) in neonatal rat ventricular cells. In these experiments, the intracellular mechanism of the alpha (alpha-1A) adrenergic effect was investigated. Guanosine-5'-O-(2-thiodiphosphate), a G-protein inhibitor, blocked and guanosine-5'-O-(3-thiotriphosphate), a G-protein activator, mimicked the effect of phenylephrine, suggesting that G-proteins are involved in the activation of the alpha-1 adrenoceptor-induced increase in Ca++ channel current. The effect of phenylephrine on the L-type current was not abolished in cells pretreated with pertussis toxin and cholera toxin, indicating that pertussis toxin- and cholera toxin-insensitive G-proteins are coupled to the alpha-1A adrenoceptor. Acute treatment with 4 beta-phorbol-12-myristate and 1-oleoyl-2-acetyl-rac-glycerol, two protein kinase C activators, increased the L-type Ca++ channel current. Staurosporine and prolonged pretreatment with 4 beta-phorbol-12-myristate blocked the effect of phenylephrine. This suggests that protein kinase C activation is involved in the mechanism. The results described in this study suggest that stimulation of the alpha-1A adrenoceptor results in the activation of pertussis toxin- and cholera toxin-insensitive G-proteins which may lead to phosphorylation of Ca++ channel proteins through protein kinase C. The phosphorylation of channel protein results in an increase in the L-type Ca++ channel current in neonatal rat ventricular cells.

Inhibition of a K+ current by beta-dendrotoxin in primary and subcultured vascular smooth muscle cells

beta-Dendrotoxin (beta-DTX), a polypeptide component of Eastern Green Mamba snake venom, inhibits a slow voltage-activated 86Rb efflux from synaptosomes, suggesting that beta-DTX inhibits K+ channels. The effects of beta-DTX on the K+ currents in primary cultured and subcultured (passages 8-12) rat tail artery vascular smooth muscle cells (VSMCs) were studied using the whole-cell patch-clamp technique. A delayed rectifier K+ current was observed in both types of cells. The current, which was relatively insensitive to tetraethylammonium, was activated at -40 to -30 mV and showed almost no inactivation. beta-DTX (1-1000 nM) decreased the outward K+ current. The effect was concentration dependent and reversible by washout but did not depend on the frequency of stimulation (use dependence) or the membrane potential. beta-DTX was more effective in primary cultured cells than in subcultured cells. K+ channels in primary cultured cells were maximally (45%) inhibited by 1 microM beta-DTX compared with 35% inhibition in subcultured cells. The concentration producing half-maximal inhibition was 5.1 x 10(-8) M for primary cells and 7.1 x 10(-8) M for subcultured cells. The delayed rectifier current was not affected by alpha-DTX, a blocker of the fast-inactivating outward K+ current (IA). These results clearly demonstrate that beta-DTX is a novel antagonist of the delayed rectifier K+ current in primary and subcultured rat tail artery VSMCs.

Changes in alpha 1-adrenoceptor coupling to Ca2+ channels during development in rat heart

It has been reported in the literature that alpha 1-adrenoceptor activation in adult rat heart does not cause an increase in Ca2+ current but involves a decrease in I(t). This may explain in part the positive inotropic effect of alpha 1-adrenoceptor activation. In this study, the effect of phenylephrine, an alpha-adrenergic agonist, on L-type Ca2+ channel current was compared in young and neonatal rat myocytes. In the presence of propranolol, phenylephrine increased the Ca2+ current (reversed by prazosin) in neonatal but not in young rat myocytes suggesting that the coupling of the alpha 1-adrenoceptor to Ca2+ channels may switch during development.

Enhanced calcium influx by parathyroid hormone in identified Helisoma trivolvis snail neurons

The modulation of [Ca2+]i by parathyroid hormone (PTH) has been extensively studied in vertebrates. The present study examined the effects of PTH on [Ca2+]i in isolated invertebrate neurons B5 from buccal ganglia of the pond snail, Helisoma trivolvis, utilizing the Fura-2 fluorescence technique. Bovine PTH, bPTH-(1-84), induced a slow and sustained increase in [Ca2+]i in neurons B5. In contrast, the elevation of extracellular K+ concentration from 1.7 mM to 15 mM induced a rapid and transient increase in [Ca2+]i. Simultaneous application of 15 mM KCl and bPTH-(1-84), or application of 15 mM KCl in the presence of bPTH-(1-84) additively increased [Ca2+]i in neurons B5. An increase in [Ca2+]i in neurons B5 was also induced by a PTH agonist [bPTH-(1-34)], but not by a PTH antagonist [bPTH-(3-34)]. The absence of calcium, or the presence of lanthanum (2 mM) or omega-conotoxin (10 microM), in the bath solution abolished the effect of bPTH-(1-84) on [Ca2+]i. Furthermore, our results demonstrated that the effect of PTH on [Ca2+]i in neurons B5 was not due to the hormonal modulation of voltage-dependent Na+ or K+ channels or a Na+/Ca2+ exchanger. The results from this study show that PTH can modulate [Ca2+]i in an identified invertebrate neuron mainly by promoting extracellular calcium influx via the N-like voltage-dependent calcium channel.

1,25-dihydroxyvitamin D as a cardiovascular hormone. Effects on calcium current and cytosolic free calcium in vascular smooth muscle cells

Clinical and in vitro evidence suggests a role for the calcium regulating hormone, 1,25-dihydroxyvitamin D (1,25D) in human and experimental hypertension. To establish the cellular basis for this association, we utilized the whole-cell version of the patch clamp method and fluorescence spectroscopic techniques to measure voltage-dependent calcium channel activity and cytosolic free calcium concentrations ([Ca2+]i) in rat tail artery-derived smooth muscle cells, before and after the addition of 1,25D. 1,25D significantly increased the calcium channel current over the range of test pulses, from -40 to +60 mV, in a dose- and time-dependent manner, appearing by 5 to 10 min of exposure, with maximum effects by 15 min. At 10 and 30 nmol/L, the current increased to 149 +/- 10% and 221 +/- 13% of basal activity of 37.75 +/- 7.7 pA and 37.7 +/- 4.5 pA, respectively. Similarly, at 10 and 100 nmol/L, 1,25D increased cytosolic free calcium levels 115 +/- 2% and 171 +/- 11%, from basal values of 99 +/- 32 nmol/L and 116 +/- 10 nmol/L, respectively. These effects of [Ca2+]i developed slowly over 3 to 4 min. Peak values were achieved by 30 min of incubation and were reversible with removal of 1,25D from the medium. Altogether, these direct effects of 1,25D on calcium current and [Ca2+]i in vascular smooth muscle cells support a role for 1,25D in vascular physiology, and provide a cellular basis for better understanding the involvement of 1,25D in hypertensive vascular disease.

Neural effects of parathyroid hormone: modulation of the calcium channel current and metabolism of monoamines in identified Helisoma snail neurons

Neuronal effects of parathyroid hormone (PTH) have been reported in vertebrates. The effect of PTH on invertebrate central neurons within the buccal ganglion of Helisoma trivolvis snails was examined in the present study. By using a vibrating probe, PTH was found to induce a transient calcium-dependent inward current in intact buccal ganglia. Intracellular microelectrode recording revealed that PTH broadened the spontaneous action potential in buccal B5 neurons in situ. By using the whole-cell configuration of the patch-clamp technique, PTH was demonstrated to increase the N-like calcium channel currents in isolated B5 neurons in a concentration-dependent manner. This effect of PTH on the N-like calcium channel currents depended on the activation of a G protein insensitive to pertussis toxin, but was unlikely to be mediated by the cyclic AMP dependent protein kinase. Furthermore, the release of gamma-glutamyl conjugate of dopamine from buccal ganglia was selectively increased in the presence of PTH. These results represent the first demonstration that a vertebrate peptide hormone, PTH, selectively modulates the N-like voltage-dependent calcium channel currents in identified invertebrate neurons. Therefore, a novel role of PTH in the regulation of invertebrate central neural functions is indicated.

Comparison of the action of two protein kinase C activators on dihydropyridine-sensitive Ca2+ channels in neonatal rat ventricular myocytes

Ca2+ channels can be modulated by protein kinase C which phosphorylates Ca2+ channel proteins. Two protein kinase C activators, 4 beta-phorbol 12-myristate 13-acetate (PMA) and 1-oleyl-2-acetyl-rac-glycerol (OAG), were used to investigate the effect of protein kinase C activation on dihydropyridine-sensitive Ca2+ channel currents (L-type) in neonatal rat ventricular myocytes using the whole cell version of the patch clamp technique. The results show that both of the activators increased the Ca2+ channel current in myocytes. However, these increases in Ca2+ channel current were different as function of time. Therefore, our results suggest that the temporal factor should be considered when the protein kinase C activators are used in studies of channel modulation.

The changes in contractile status of single vascular smooth muscle cells and ventricular cells induced by bPTH-(1-34)

Single smooth muscle cells from rat tail artery and ventricular myocytes from neonatal rat were isolated by repeated enzyme digestion. The change in cell area as determined photographically was used as an index of cell contraction. The photographic areas of single smooth muscle cells bathed in normal Tyrode solution were 403 +/- 22 (n = 13) square micra. Exposure of smooth muscle cells to a modified Tyrode solution containing 60 mM KCl induced cell contraction. This contraction was inhibited by bPTH-(1-34) at a concentration of 1 microM. The inhibitory effect of bPTH-(1-34) was time-dependent with maximum inhibition at 5 min after administration. The photographic areas of ventricular myocytes bathed in the culture medium without fetal calf serum were 516 +/- 47 (n = 29) square micra. At a concentration of 1 microM, bPTH-(1-34) produced a time-dependent contraction in ventricular myocytes as shown by the decrease in the photographic cell area (88 +/- 2% of the control value at 15 min, n = 9, p < 0.01). Furthermore, 1 microM nifedipine inhibited the effect of bPTH-(1-34) on the contraction of ventricular myocytes, indicating that bPTH-(1-34) might exert its action via a calcium channel related mechanism. In addition, bPTH-(1-34) increased the contraction frequency of single ventricular cells, which could also be inhibited by nifedipine. The present study suggests that bPTH-(1-34) directly relaxes precontracted single vascular smooth muscle cells and contracts single ventricular myocytes.

Inhibitory action of ethanol on L-type Ca2+ channels and Ca(2+)-dependent guanosine 3',5'-monophosphate accumulation in rat pinealocytes

It has previously been shown that the K+ potentiation of vasoactive intestinal peptide-stimulated cAMP and cGMP responses was inhibited by ethanol in rat pinealocytes, suggesting an inhibitory action of ethanol on the voltage-dependent Ca2+ channels (VDCC). In this study, using the whole cell version of the patch clamp technique, we found that ethanol reduced the amplitude, but did not change the voltage dependence or the time course of activation or inactivation of the L-type VDCC. The inhibitory effect of ethanol on this current was concentration dependent, and ethanol (100 mM) resulted in a 40% inhibition of this current. However, in fura-2-loaded cells, total increases in intracellular Ca2+ ([Ca2+]i) caused by ethanol and BayK 8644 did not differ from the [Ca2+]i signal caused by BayK 8644 alone, suggesting that the inhibitory action of ethanol on VDCC may not be related to a reduction in [Ca2+]i. Although there was no change in the total [Ca2+]i signal, ethanol (25-200 mM) dose-dependently inhibited the potentiation effects of depolarizing concentrations of K+ and BayK 8644 on the isoproterenol-stimulated cGMP, but not the cAMP, response. Therefore, the cGMP response appears to be more sensitive to the inhibitory action of ethanol, and a site distal to elevation of [Ca2+]i of importance to the potentiation mechanism may be inhibited by ethanol. This was confirmed by the finding that ethanol was effective in inhibiting the A23187 potentiation of isoproterenol-stimulated cGMP response. These results suggest that 1) the L-type VDCC was inhibited by ethanol; 2) the Ca(2+)-mediated potentiation of the isoproterenol-stimulated cGMP response was sensitive to the inhibitory action of ethanol; and 3) although ethanol inhibits the VDCC, it alone cannot explain the inhibitory effect of ethanol on BayK 8644- and K(+)-mediated potentiation of the isoproterenol-stimulated cGMP response.

Tetrandrine inhibits both T and L calcium channel currents in ventricular cells

Tetrandrine, a putative Ca2+ channel blocker, is extracted from the Chinese medicinal herb, Radix stephania tetrandrae. In the present study, the whole-cell version of the patch clamp technique was used to investigate the effects of tetrandrine on both T and L calcium channel currents in primary cultured neonatal rat ventricular cells. We show that tetrandrine inhibits both T and L calcium channel currents in ventricular cells. This inhibition of inward Ca2+ currents is concentration dependent and reversible. Tetrandrine does not shift the I-V relationship of the calcium currents. These results clearly demonstrate that tetrandrine acts as a calcium channel antagonist in ventricular cells. Previous data show that tetrandrine may be regarded as a wide-spectrum calcium channel antagonist.

Modification by solvents of the action of nifedipine on calcium channel currents in neuroblastoma cells

The effect of nifedipine dissolved in different solvents on the two types of calcium channel currents in neuroblastoma cells was investigated using the whole cell version of the patch clamp technique. Nifedipine dissolved in dimethylsulfoxide (nifedipine/DMSO) decreased the transient calcium channel (T channel) current by 50% at a concentration of 10 microM. This inhibitory effect was concentration-dependent and reversible. In contrast, T channel currents were not inhibited by nifedipine at a similar concentration dissolved in acetone or ethanol. Further experiments were carried out with dried nifedipine/DMSO. Dried nifedipine/DMSO powder re-dissolved in acetone or ethanol at a concentration of 10 microM decreased the T channel current by 32% and 37%, respectively. In addition, within the concentration range of 10 nM to 100 microM nifedipine/DMSO inhibited the long-lasting calcium channel (L channel) current more effectively than did nifedipine dissolved in acetone. The concentration of solvent (DMSO, ethanol, acetone) in the bath was fixed at 0.3% to reach different final concentrations of nifedipine. Solvents alone at a final concentration of 0.3% did not show any effect on T or L channel currents. UV absorbance measurements indicated that the combination of nifedipine, solvent and bath solution did not result in precipitation of the dihydropyridine during the experimental protocol. It is concluded that when DMSO is used as the solvent, nifedipine is not only a more effective L channel antagonist but also a T channel antagonist in neuroblastoma cells.

Bay K-8644 in different solvents acts as a transient calcium channel antagonist and a long-lasting calcium channel agonist

This report describes the effect of Bay K-8644 dissolved in various solvents on two types of calcium channel currents in neuroblastoma cells. Transient calcium channel (T channel) currents were not affected by Bay K-8644 dissolved in ethanol (EtOH) or polyethylene glycol (PEG). However, at the same concentration of 0.6 microM, Bay K-8644 dissolved in dimethylsulfoxide (DMSO) (Bay K-8644/DMSO) decreased the T channel current by 50%. The concentration of all three solvents in the bath was fixed at 0.3% to reach different final concentrations of Bay K-8644. At this fixed solvent concentration, the inhibitory effect of Bay K-8644/DMSO on T channel currents was dose-dependent; the solvents alone did not have any effect on T channel currents; and DMSO pretreatment of cells did not render the T channel current sensitive to Bay K-8644 dissolved in EtOH or PEG. Bay K-8644/DMSO was dried using a flash evaporator and redissolved in EtOH or PEG. Dried Bay K-8644 that was redissolved in EtOH or PEG to achieve a final concentration of 0.6 microM inhibited T channel currents by 39 or 35%, respectively. Furthermore, Bay K-8644 (10 nM) increased L channel currents by 80% with DMSO, but only 30% with EtOH as the solvent. These results show that in neuroblastoma cells Bay K-8644/DMSO, within the concentration range examined, is a T channel antagonist and more effective L channel agonist than Bay K-8644 dissolved in the two other solvents.

Tetrandrine: a novel calcium channel antagonist inhibits type I calcium channels in neuroblastoma cells

Tetrandrine, an alkaloid isolated from the Chinese herb, Radix stephaniae tetrandrae, has been used clinically as a hypotensive agent for a long time. Recently, several studies have demonstrated that tetrandrine behaves like a calcium entry blocker. In the present investigation, the whole cell version of the patch clamp technique was used to study the effect of tetrandrine on the type I (transient inward) calcium current in neuroblastoma cells. These results showed that tetrandrine inhibited the transient inward current, without affecting the channel kinetics. The effects of tetrandrine were dose-dependent and reversible but did not depend on the frequency of stimulation (use-dependence) or the membrane potential. These data clearly demonstrate that tetrandrine is a novel and potent antagonist of the transient inward current in neuroblastoma cells.

Parathyroid hormone selectively inhibits L-type calcium channels in single vascular smooth muscle cells of the rat

1. The active synthetic N-terminal fragment of bovine parathyroid hormone, bPTH-(1-34) at a concentration of 1 microM, decreased the peak amplitude of the long-lasting (L-type) calcium channel current by 37% (n = 14, P less than 0.01) in rat tail artery smooth muscle cells. By contrast, this fragment of parathyroid hormone (PTH) (1 microM) had no effect on the transient (T-type) calcium channel current in the same cell preparation. 2. The inhibitory effect of bPTH-(1-34) on L-channel currents was reversible and could be antagonized by the L-channel agonist, Bay K 8644. In contrast, bPTH-(1-34) inhibited Bay K 8644-induced amplification of L-channel currents. 3. The inhibitory effect of bPTH-(1-34) on L-Channel currents was dose dependent with a threshold concentration of less than 10(-7), and voltage dependent with increased inhibition at more positive holding potentials. However, this effect of bPTH-(1-34) was not dependent on different pulse lengths or interpulse intervals. 4. The kinetics of deactivation of L-channel currents were not changed although the instantaneous amplitude of the L-channel tail current was reduced by bPTH-(1-34). 5. Application of bPTH-(1-34) antagonists (10(-6) M-bPTH-(3-34) and 10(-5) M-bPTH-(7-34] did not result in any significant change in the magnitude of L-channel currents (n = 15 and n = 7, respectively). 6. Pre-incubation of cells with bPTH-(3-34) for more than 15 min abolished the inhibitory effect of bPTH-(1-34) on L-channel currents. 7. The present study provides direct evidence to demonstrate the PTH, an endogenous circulating hormone, is a selective inhibitor of L-channel currents in vascular smooth muscle cells.

Two types of voltage-dependent calcium channel currents and their modulation by parathyroid hormone in neonatal rat ventricular cells

The positive inotropic and chronotropic actions of parathyroid hormone (PTH) in cardiac cells are considered to be related to the modulation of calcium influx. The underlying mechanisms, however, are unknown, and direct electrophysiological evidence at the single-cell level is required. In the present study, the whole-cell configuration of the patch-clamp technique was used in neonatal rat ventricular cells to identify both transient (T) and long-lasting (L) voltage-dependent calcium channels according to their electrophysiological and pharmacological characteristics. The active synthetic fragment of bovine PTH, bPTH-(1-34), at a concentration of 1 microM, significantly enhanced the magnitude of L-channel currents by 67.8% (n = 13, p less than 0.01). The steady-state activation curve of L-channel currents was shifted along the voltage axis toward more negative potentials by either bPTH-(1-34) or Bay K-8644. The suppression or amplification of PTH-induced enhancement of inward currents by nifedipine, 1 microM, or Bay K-8644, 5 microM, respectively, further indicated that the effect of PTH was specific for L-type calcium channels. However, bPTH-(1-34) failed to modulate the magnitude or kinetics of T-channel currents. This study directly demonstrates that PTH is a specific endogenous calcium-channel activator in neonatal rat ventricular cells.

The effects of parathyroid hormone on L-type voltage-dependent calcium channel currents in vascular smooth muscle cells and ventricular myocytes are mediated by a cyclic AMP dependent mechanism

The present study demonstrated that L channel currents were decreased in smooth muscle cells, and increased in ventricular myocytes by both bovine parathyroid hormone, (bPTH-(1-34)), and dibutyryl cyclic AMP (db-cAMP), using the whole cell version of the patch clamp technique with Ba2+ as the charge carrier. The effects of bPTH-(1-34) and db-cAMP on L channel currents were additive but not synergistic. Furthermore, the effects of bPTH-(1-34) on L channel currents in these 2 cell preparations were abolished in the presence of a cAMP antagonist. These results suggest that the effects of bPTH-(1-34) on L channel currents in vascular smooth muscle cells and ventricular myocytes are mediated by a cAMP-dependent mechanism.

Flunarizine selectively blocks transient calcium channel currents in N1E-115 cells

The sensitivities of two types of voltage-dependent calcium channel currents in N1E-115 neuroblastoma cells to various agents were studied using the whole cell version of the patch clamp technique. Cells cultured in normal media expressed predominantly transient (T) currents whereas cells cultured in media with dimethylsulfoxide for 1 month expressed predominantly long-lasting (L) currents. Furthermore, by selecting cells with one or two short neurites it was possible to obtain cells which expressed only L channels. The dihydropyridine agonist, Bay K-8644 (5 microM), increased the amplitude of L channel currents by a factor of nearly two, whereas T channel currents were unaffected. Nifedipine (0.1 mM) significantly inhibited L channel currents, whereas T channel currents were insensitive to this treatment. Flunarizine, a diphenylpiperazine, had no effect on L channel currents but selectively inhibited T channel currents in a dose-dependent manner, with a significant effect at a concentration of 1 microM. However, flunarizine did not change the I-V relationships of T channel currents. Furthermore, the voltage dependence of T channel inactivation was shifted toward more negative potential by flunarizine. The present study provides direct evidence of the selective inhibition of T channel currents by flunarizine in N1E-115 neuroblastoma cells.

Specific inhibition of long-lasting, L-type calcium channels by synthetic parathyroid hormone

The effect of an active synthetic N-terminal fragment of bovine parathyroid hormone (bPTH), bPTH-(1-34), on Ca2+ channels was studied in mouse neuroblastoma cells (N1E-115). With the whole-cell variation of the patch-clamp technique, T (transient) and L (long-lasting) types of Ca2+ currents were identified. Pharmacological characterization showed that the L current was amplified by the Ca2+ channel stimulator BAY K-8644, but the T current was unaffected. The administration of bPTH-(1-34) produced dose-related inhibition of the L current, which could be reversed by BAY K-8644. The peptide had no effect on the T current. In addition, use of the fluorescent indicator fura-2 showed that bPTH-(1-34) inhibited the KCl-stimulated increase in intracellular free Ca2+ in neuroblastoma cells with L channels but not in cells with T channels. An inactivated (oxidized) preparation of bPTH-(1-34) failed to affect the L current. High-affinity binding of labeled PTH analog to these neuroblastoma cells was also demonstrated. In addition, bPTH-(1-34) inhibited the L current in cultured vascular smooth muscle cells from rat tail artery. These data indicate that, in some tissues, PTH can act as an endogenous blocker of Ca2+ entry.

Control of calcium channels in neuroblastoma cells (N1E-115)

Neuroblastoma cells (N1E-115) were used as models of transient (T) and long-lasting (L) Ca++ channels. The whole cell version of the patch clamp technique was used to measure inward Ca++ currents, and the fluorescent indicator, Fura-2, was used to measure changes in intracellular Ca++. Cells were cultured and selected during recording so that predominantly T or L channel currents were measured. T channel currents did not respond to dihydropyridine or parathyroid hormone, whereas L channel currents did. BAY-K-8644 increased and nifedipine decreased L channel currents. After a 15 mM KCl challenge, cells with predominantly T channels responded with a transient change in intracellular Ca++, while cells with predominantly L channels showed a sustained response. PTH inhibited the increase in intracellular Ca++ in cells with L channels, but not in those with T channels. PTH may be an example of an endogenous calcium channel blocker, at least in neuroblastoma cells.

A dihydropyridine-sensitive calcium channel in rodent osteoblastic cells

Rat osteogenic sarcoma cells (UMR 106-01) and normal rat trabecular bone osteoblasts (ROB) were studied using the whole cell version of the patch clamp technique to determine the existence of calcium (Ca2+) channels. Pipette and bath solutions were designed to separate Ca2+ channel currents from other voltage-dependent currents, and Ba2+ was used as the charge carrier. In both UMR 106-01 and ROB cells, a Ba2+ current was measured, which expressed the characteristics of an L-channel, such as activation range, dihydropyridine sensitivity, and little or no inactivation. In some cases, this channel was detectable only with BAY-K-8644 in the bath solution. The dihydropyridine agonist increased the current intensity and shifted the peak inward current to more negative potentials. This study, confirming previous observations, demonstrates the existence of a Ca2+ channel in both transformed and normal osteoblastic cells.