Distribution of dihydropyridine and omega-conotoxin-sensitive calcium currents in acutely isolated rat and frog sensory neuron somata: diameter-dependent L channel expression in frog.

Calcium channel subtypes in adult rat and frog sensory neuron somata, acutely isolated from dorsal root ganglia (DRG neurons), were studied using Bay K 8644, nimodipine, and omega-conotoxin GVIA (omega-CgTx) as specific probes. The DRG neurons varied in diameter 15-60 microns (rat) and 20-80 microns (frog). Bay K 8644 produced a large increase in calcium currents of small-diameter rat DRG neurons and shifted channel activation and the peak of the I-V curve in the hyperpolarizing direction. At a physiological holding potential (HP) of -60 mV, nimodipine blocked 50% of the peak calcium current in small-diameter frog and rat DRG neurons, indicating a large L channel component. At HP -80 mV, nimodipine blocked a lower percentage of peak current in small-diameter rat and frog DRG neurons than expected (based on experiments at HP -60 mV) probably due to nimodipine's voltage dependence. At HP -60 mV, omega-CgTx blocked 25% and 50% of peak current in small-diameter rat and frog DRG neurons, respectively. Omega-CgTx blocked a larger percentage of current at HP -80 mV than at -60 mV, probably because of the repriming of N channels. Observation of nimodipine- and Bay K 8644-sensitive calcium current in small-diameter rat and frog DRG neurons after omega-CgTx treatment, suggests that omega-CgTx is not a potent L channel blocker. The combination of omega-CgTx and nimodipine blocked all current in small-diameter frog DRG neurons but left a small portion of current unblocked in small-diameter rat DRG neurons at HP -60 mV, suggesting the possibility of omega-CgTx- and nimodipine-insensitive calcium channels in rat DRG neurons. Calcium current in most large-diameter frog DRG neurons was insensitive to nimodipine, but was completely blocked by omega-CgTx. This indicates significant variation in the expression of calcium channel subtypes in small- and large-diameter frog DRG neurons, which may subserve different sensory modalities.     

Multiple types of high-threshold calcium channels in rabbit sensory neurons: high-affinity block of neuronal L-type by nimodipine.

Whole-cell and cell-attached patch recording have been used to characterize multiple types of voltage-dependent calcium channels in neurons freshly dispersed from rabbit dorsal root ganglia. In whole-cell patch recordings, high-threshold current, strongly resistant to inactivation by depolarized holding potentials (L-type; V1/2 = -27.2 mV), was potently inhibited by nimodipine. Assuming 1:1 binding, the dissociation constant for nimodipine binding to the inactivated state of the L-type calcium channel (KI) was 5.3 nM (n = 8). In contrast, a second type of high-threshold current less resistant to inactivation by depolarized holding potentials (N-type; V1/2 = -56.9 mV) was not blocked by nimodipine. Nimodipine-resistant N-type calcium current was inhibited by omega-conotoxin (5 microM). Cell-attached patch recordings of single calcium channel currents demonstrated the existence of three different unitary conductances; 7.4 pS, 13.1 pS, and 24.1 pS. The 24.1 pS high-threshold channel was enhanced by (-) BAY K 8644 and inhibited by nimodipine in a concentration- and voltage-dependent manner. Hyperpolarization reversed this block. These results demonstrate that, as in cardiac and smooth muscle, there is a component of neuronal high-threshold current corresponding to the L-type calcium channel that can be blocked with high affinity by nimodipine.     

Characterization of the electrically evoked release of substance P from dorsal root ganglion neurons: methods and dihydropyridine sensitivity

The mechanism by which dihydropyridines (DHPs) modulate the electrically evoked or KCI-induced release of substance P (SP) from embryonic chick dorsal root ganglion (DRG) neurons was investigated in the present study. The release of SP, as measured by radioimmunoassay (RIA), was characterized in terms of its dependence on extracellular calcium ion, its stimulus-response relationship, its sensitivity to the calcium-channel blocker omega conus toxin (omega-CgTx), and its modulation by the DHPs Bay K 8644 and nifedipine. Here it is reported that omega-CgTx (1 microM) blocked the electrically evoked release of SP. In contrast, the calcium-channel agonist Bay K 8644 (5 microM) facilitated the release of SP (by 45%), whereas the calcium-channel antagonist nifedipine (5 microM) was without effect. When the release of SP was triggered by depolarization of cultures with 60 mM KCI, the actions of the DHPs became much more pronounced. Under these conditions, Bay K 8644 facilitated (by 115%), whereas nifedipine inhibited (by 58%), peptide secretion. Voltage-clamp analysis of DRG cell calcium currents demonstrated that these actions of omega-CgTx, Bay K 8644, and nifedipine are explicable in terms of their effects on the slowly inactivating (L-type) calcium current. On the basis of these findings, it is suggested that the SP release mechanism exhibits DHP sensitivity due to the involvement of L-type calcium channels in the neurosecretory process. This model predicts that the voltage and time-dependent antagonist actions of nifedipine are sufficient to explain its failure to inhibit the electrically evoked release of SP.     

Involvement of voltage-operated calcium channels in alpha-melanocyte-stimulating hormone (alpha-MSH) release from perifused rat hypothalamic slices

The contribution of voltage-operated calcium (VOC) channels in the mechanism of release of alpha-melanocyte-stimulating hormone (alpha-MSH) from hypothalamic neurons was investigated using perifused rat hypothalamic slices. The stimulatory effect of potassium (50 mM) on alpha-MSH release was completely blocked by cadmium (1 mM) a calcium competitor which indifferently blocks T-, L-and N-type VOC channels. To determine the nature of calcium conductances involved in K+-evoked alpha-MSH release, we have investigated the effect of a VOC channel agonist and 3 antagonists on the secretion of the neuropeptide. Administration of synthetic omega-conotoxin fraction GVIA (1 microM), a peptide toxin which blocks both N- and L-type VOC channels, reduced by 33% K+-induced alpha-MSH release. In contrast, the 1,4-dihydropyridine (DHP) antagonist nifedipine, at concentrations up to 100 microM, did not affect the response of hypothalamic alpha-MSH neurons to depolarizing concentrations of KCl. In addition, the secretion of alpha-MSH induced by high K+ concentrations was not reduced by nifedipine (10 microM) in the presence of diltiazem (1 microM), a benzothiazepine derivative which increases the affinity of the DHP antagonist for L-type VOC channels. The DHP agonist BAY K 8644 (0.1-10 microM) did not modify the early phase of the response of alpha-MSH neurons to K+-induced depolarization. In contrast BAY K 8644 (1 or 10 microM) significantly prolonged the duration of K+-induced alpha-MSH release. This sustained release of alpha-MSH induced by BAY K 8644 (10 microM) was totally suppressed by nifedipine (10 microM).(ABSTRACT TRUNCATED AT 250 WORDS)     

Voltage-dependent calcium currents in Purkinje cells from rat cerebellar vermis.

Whole-cell patch clamp recording was used to characterize calcium currents in Purkinje cells dissociated from the cerebellar vermis of 1-3-week postnatal rats. A subset of Purkinje cells had a low-threshold, transient current similar to the T-type current in peripheral neurons. All Purkinje cells had a high-threshold, slowly inactivating current. Only a small component of the high-threshold current was sensitive to dihydropyridine (DHP) antagonists or to the dihydropyridine agonist BAY K8644. omega-Conotoxin had very little effect on the high-threshold current. The results suggest that these Purkinje cells have at least three types of calcium channels: T-type channels (present in only a fraction of cells), DHP-sensitive L-type channels (contributing a small fraction of the high-threshold current), and a predominant type of high-threshold channel that is pharmacologically distinct from L-type and N-type channels characterized in peripheral neurons.     

Modulation of glycine responses by dihydropyridines and verapamil in rat spinal neurons.

Although glycine receptors (GlyRs) are responsible for the main spinal inhibitory responses in adult vertebrates, in the embryo they have been reported to mediate depolarizing responses, which can sometimes activate dihydropyridine-sensitive L-type calcium channels. However, these channels are not the only targets of dihydropyridines (DHPs), and we questioned whether GlyRs might be directly modulated by DHPs. By whole-cell recording of cultured spinal neurons, we investigated modulation of glycine responses by the calcium channel antagonists, nifedipine, nitrendipine, nicardipine and (R)-Bay K 8644, and by the calcium channel, agonist (S)-Bay K 8644. At concentrations between 1 and 10 microM, all these DHPs could block glycine responses, even in the absence of extracellular Ca2+. The block was stronger at higher glycine concentrations, and increased with time during each glycine application. Nicardipine blocked GABAA responses from the same neurons in a similar manner. In addition to their blocking effects, nitrendipine and nicardipine potentiated the peak responses to low glycine concentrations. Both effects of extracellular nitrendipine on glycine responses persisted when the drug was present in the intracellular solution. Thus, these modulations are related neither to calcium channel modulation nor to possible intracellular effects of DHPs. Another type of calcium antagonist, verapamil (10-50 microM), also blocked glycine responses. Our results suggest that some of the effects of calcium antagonists, including the neuroprotective and anticonvulsant effects of DHPs, might result partly from their interactions with ligand-gated chloride channels.     

Calcium Channel Currents in Undifferentiated Human Neuroblastoma (SH-SY5Y) Cells: Actions and Possible Interactions of Dihydropyridines and ω-Conotoxin

Ca²⁺ channel currents were recorded in undifferentiated human neuroblastoma (SH-SY5Y) cells with the whole-cell patch-clamp technique, using 10 mM Ba²⁺ as charge carrier. Currents were only evoked by depolarizations to -30 mV or more positive (holding potential -80 mV), inactivated partially during 200 ms depolarizing steps, and were abolished by 150 μMCd²⁺. Currents could be enhanced by Bay K-8644 and partially inhibited by nifedipine, suggesting that they arose in part due to activation of L-type Ca²⁺ channels. Currents were also inhibited by the marine snail peptide ω-conotoxin GVIA (ω-CgTx). At a concentration of 10 nM inhibition by ω-CgTx was reversible, but at higher concentrations blockade was always irreversible. Although current inhibition by nifedipine was maximal at 1μM, supramaximal concentrations reduced the inhibitory actions of ω-CgTx in a concentration-dependent manner. Ca²⁺ channel currents evoked from a holding potential of -50 mV showed no inactivation during 200 ms depolarizations but declined in amplitude with successive depolarizing steps (0.2 Hz). Current amplitudes could be restored by returning the holding potential to -80 mV. Currents evoked from -50 mV were inhibited by nifedipine and ω-CgTx to a similar degree as those evoked from -80 mV. Our results indicate that undifferentiated SH-SY5Y cells possess L- and N-type Ca²⁺ channels which can be distinguished pharmacologically but cannot be separated by using depolarized holding potentials. Furthermore, these data suggest that nifedipine has a novel action to inhibit blockade of N-type channels by ω-CgTx.     

High-voltage-activated calcium channels in Muller cells acutely isolated from tiger salamander retina

Muller cells mediate retinal function by stabilizing the ionic environment and signal glial network activity via calcium waves. Using whole-cell patch clamp recording, we describe a high-voltage-activated, slowly inactivating Ca channel current in isolated salamander Muller cells that has unusual pharmacological properties. The Ca channel current has an activation midpoint of approximately -8 mV and an inactivation midpoint of approximately -26 mV in 10 mM Ba2+. The time constant for inactivation is approximately 380 ms at potentials positive to zero. The current is blocked by Cd2+ with an EC50 of <100 nM. nisoldipine (10 microM) blocks approximately 50%, while nifedipine (1 microM), diltiazem (20 microM), and verapamil (50 microM) each block one-third of the current. In contrast to its typical actions, BayK 8644 blocks the current by approximately 25%. Blockers of other Ca channel subtypes were also tested: omega-agatoxin IVA (200 nM) blocked only 13% of the Ca channel current, while omega-conotoxin GVIA (1 microM) blocked 84% of the current. Immnohistochemistry supported the presence of alpha1A, alpha1B, alpha1C, and alpha1D Ca channel subunits. Mapping of dihydropyridine-binding sites with DM-BODIPY revealed a distribution of channels over the entire membrane of the Muller cell with a higher density at the apical region. Overall, these observations suggest either the presence of a mix of L- and N-type Ca channels or a single, unconventional HVA Ca channel subtype sharing L- and N-type Ca channel characteristics.     

Voltage-dependent calcium channels regulate melatonin output from cultured chick pineal cells

Chick pineal cells maintained in primary culture display a circadian rhythm of melatonin production and release, and the nocturnal increase in melatonin output is enhanced by elevating extracellular K+. The divalent cations, Co2+, Cd2+, and Mn2+, each reduce nocturnal melatonin output. Nitrendipine and nifedipine also prevent the nocturnal rise in melatonin output, while Bay K 8644 increases it, suggesting a role for voltage-dependent Ca2+ channels in regulating melatonin output. The whole-cell patch-clamp technique was used to record from individual chick pineal cells. Under conditions designed to isolate currents through voltage-dependent Ca2+ channels, biphasic inward currents are elicited by large depolarizing commands (e.g., to 0 mV) from a holding potential of -90 mV; from a holding potential of -40 mV, only a sustained inward current is elicited by steps to 0 mV. Both components of the inward current are blocked by Co2+ or Cd2+. The sustained current is increased in amplitude by Bay K 8644 and blocked by nifedipine, while the transient current is unaffected. Since there is no evidence for vesicular release of melatonin, the "L-type" calcium channels mediating the sustained calcium current appear to be involved in the pathways regulating melatonin synthesis in chick pineal cells.     

Calcium currents in cultured rat cortical neurons

Rat neocortical neurons grown in dissociated cell culture for 4-12 weeks were studied with whole-cell patch-clamp techniques in order to characterize the calcium currents present in these cells. When voltage-dependent Na and K currents were inhibited, depolarizations from negative holding potentials induced inward currents which had 3 components: a low threshold activated, small, relatively persistent component, which was completely inactivated at holding potentials more positive then -60 mV; a higher threshold, relatively persistent component (which was not inactivated at VH = -50 mV); and a higher threshold, larger, transient component. All 3 components were reduced by removal of Ca, and blocked by Cd and Ni at appropriate concentrations. The components were differentially affected by low concentrations of Ni (500 microM), nifedipine (500 microM) and Ba (1.8 mM). Only the first two components were present in very young neurons.     

Characterisation of the L- and N-type calcium channels in differentiated SH-SY5Y neuroblastoma cells: calcium imaging and single channel recording.

We have used single cell imaging of [Ca2+]i and single channel cell-attached patch clamp recording to characterise the Ca2+ channels present on the plasma membrane of retinoic acid-differentiated human neuroblastoma (SH-SY5Y) cells. Exposure to raised K+ (45 or 60 mM) for 1 min resulted in a transient rise in [Ca2+]i which was abolished by cadmium (100 microM). The amplitude of the evoked rise varied from cell to cell. Both omega-Conus toxin (500 nM) and nifedipine (10 microM) reduced, but did not abolish, the rise in [Ca2+]i whereas Bay K 8644 (3 microM) potentiated it. In single channel records both L- and N-type Ca2+ channel openings were observed during membrane depolarisations from a holding potential of -90 mV. L-type channel openings (unitary conductance 22.5 pS) were prolonged by S(+)-PN 202-791 (500 nM) and could still be evoked from a depolarised holding potential (-40 mV). N-type channel openings (unitary conductance 12.5 pS) were unaffected by the dihydropyridine agonist but were inactivated at a holding potential of -40 mV. These results indicate that, in contrast to previous observations using whole cell recording, retinoic acid-differentiated SH-SY5Y cells express both L- and N-type Ca2+ channels.     

BAY K 8644 increases release of acetylcholine at the murine neuromuscular junction

In this study we describe the stimulatory effects of submicromolar concentrations of BAY K 8644 on neurally evoked and spontaneous release of transmitter at the vertebrate neuromuscular junction, a model cholinergic synapse. BAY K 8644 increases mean quantal content. This effect is blocked by pretreatment with the dihydropyridine (DHP) antagonist, nimodipine, but nimodipine itself had no effect on quantal content. Furthermore, BAY K 8644 induces a marked increase in spontaneous quantal release of transmitter as measured by miniature endplate potential frequency. These results are important in that they indicate that DHP-sensitive Ca2+ channels exist at motor nerve terminals and when activated can participate in transmitter release; second, they imply that these elements do not normally participate in transmitter release; third, they indicate a functional effect of DHPs on neurons under somewhat more relevant physiological conditions than those imposed by prolonged K+-induced depolarization, a technique used to evoke transmitter release in subcellular systems and fourth, they indicate an effect of BAY K 8644 on spontaneous release of transmitter, an effect not reported in previous neurochemical experiments.     

Developmental regulation of T‐, N‐ and L‐type calcium currents in mouse embryonic sensory neurones

We investigated the development of a low (T-type) and two high voltage-activated (N- and L-type) calcium channel currents in large diameter dorsal root ganglion neurones acutely isolated from embryonic mice using the whole-cell patch-clamp technique. The low and high voltage-activated barium currents (LVA and HVA) were identified by their distinct threshold of activation and their sensitivity to pharmacological agents, dihydropyridines and ω-conotoxin-GVIA, at embryonic day 13 (E13), E15 and E17–18, respectively, before, during and after synaptogenesis. The amplitude and density of LVA currents, measured during a –40 mV pulse from a holding potential of –100 mV, increased significantly between E13 and E15, and remained constant between E15 and E17–18. The density of global HVA current, elicited by 0 mV pulse, increased between E13 and E15/E17–18. The density of the N-type current studied by the application of ω-conotoxin-GVIA (1 μm ) increased significantly between E13 and E15/E17–18. The use of the dihydropyridine nitrendipine (1 μm ) revealed that the density of L-type current remained constant at each stage of development. Nevertheless, application of dihydropyridine Bay K 8644 (3 μm ) demonstrated a significant slowing of the deactivation tail current between embryonic days 13 and 15, which may reflect a qualitative maturation of this class of calcium channel current. The temporal relationship between the changes in calcium channel pattern and the period of target innervation suggests possible roles of T-, N- and L-type currents during developmental key events such as natural neurone death and onset of synapse formation.     

A study of the mechanism of Ca2+ current inhibition produced by serotonin in rat dorsal raphe neurons

Calcium currents and their modulation by 5-HT were studied using both whole-cell and single-channel patch-clamp techniques in acutely isolated adult rat dorsal raphe neurons. Evidence for three types of Ca channels (T, N, L) was obtained in both whole-cell and single-channel experiments. Approximately 4% of the total high-threshold Ca current (L-type) was sensitive to dihydropyridines (DHPs) while approximately 40% of the Ca current (N-type) was sensitive to omega-conotoxin (omega-CgTx). About 56% of the whole-cell current was insensitive to either DHPs or omega-CgTx and may thus represent a different kind of Ca current. 5-HT reduced raphe neuron Ca currents by approximately 50%, while slowing activation. 5-HT inhibited both omega-CgTx-sensitive and -insensitive Ca current. Inhibition by 5-HT was voltage dependent; prepulses to +80 mV lasting for 20 msec almost completely abolished the 5-HT-mediated inhibition. The voltage dependence of the response to 5-HT suggested that trains of action potentials might overcome the inhibition due to 5-HT. Trains of brief depolarizations were used to simulate action potentials; only about 5% of the 5-HT-induced inhibition was relieved by the trains. These results suggest that while large depolarizations could restore the Ca current inhibited by 5-HT, physiological stimuli, such as trains of action potentials, could not. The action of 5-HT was made irreversible by inclusion of GTP-gamma-S in the patch pipette, suggesting a G-protein mediation of the response to 5-HT.(ABSTRACT TRUNCATED AT 250 WORDS)     

Delayed rectifier currents in rat globus pallidus neurons are attributable to Kv2.1 and Kv3.1/3.2 K(+) channels.

The symptoms of Parkinson disease are thought to result in part from increased burst activity in globus pallidus neurons. To gain a better understanding of the factors governing this activity, we studied delayed rectifier K(+) conductances in acutely isolated rat globus pallidus (GP) neurons, using whole-cell voltage-clamp and single-cell RT-PCR techniques. From a holding potential of -40 mV, depolarizing voltage steps in identified GP neurons evoked slowly inactivating K(+) currents. Analysis of the tail currents revealed rapidly and slowly deactivating currents of similar amplitude. The fast component of the current deactivated with a time constant of 11. 1 +/- 0.8 msec at -40 mV and was blocked by micromolar concentrations of 4-AP and TEA (K(D) approximately 140 microM). The slow component of the current deactivated with a time constant of 89 +/- 10 microseconds at -40 mV and was less sensitive to TEA (K(D) = 0.8 mM) and 4-AP (K(D) approximately 6 mM). Organic antagonists of Kv1 family channels had little or no effect on somatic currents. These properties are consistent with the hypothesis that the rapidly deactivating current is attributable to Kv3.1/3.2 channels and the slowly deactivating current to Kv2.1-containing channels. Semiquantitative single-cell RT-PCR analysis of Kv3 and Kv2 family mRNAs supported this conclusion. An alteration in the balance of these two channel types could underlie the emergence of burst firing after dopamine-depleting lesions.     

Different sensitivities to dihydropyridines of catecholamine release from cat and ox adrenals.

Catecholamine release evoked by quick pulses of Ca2+ (2.5 mM) given sequentially at 30 min intervals to cat and ox adrenal glands perfused continuously with Ca2+ free Krebs-Tris solutions containing 35 or 118 mM K+, was studied. In the feline, the secretory response was highly sensitive to various dihydropyridine (DHP) derivatives. For instance, secretion was completely blocked by nM concentrations of (+)isradipine (IC50 between 3 and 4 nM) and markedly potentiated by (-)Bay-K-8644. In contrast, the bovine secretory responses were resistant to blockade by nitrendipine or (+)isradipine, as well as to potentiation by Bay-K-8644, even at microM concentrations. From these experiments, it seems clear that distinct subtypes of Ca2+ channels might mediate a similar secretory response in ox and cat adrenal chromaffin cells, at least in the present experimental conditions.     

Effect of charybdotoxin and leiurotoxin I on potassium currents in bullfrog sympathetic ganglion and hippocampal neurons.

The effects of charybdotoxin and leiurotoxin I were examined on several classes of K+ currents in bullfrog sympathetic ganglion and hippocampal CA1 pyramidal neurons. Highly purified preparations of charybdotoxin selectively blocked a large voltage- and Ca(2+)-dependent K+ current (IC) responsible for action potential repolarization (IC50 = 6 nM) while leiurotoxin I selectively blocked a small Ca(2+)-dependent K+ conductance (IAHP) responsible for the slow afterhyperpolarization following an action potential (IC50 = 7.5 nM) in bullfrog sympathetic ganglion neurons. Neither of the toxins had significant effects on other K+ currents (M-current [IM], A-current [IA] and the delayed rectifier [IK]) present in these cells. Leiurotoxin I at a concentration of 20 nM had no detectable effect on currents in hippocampal CA1 pyramidal neurons. This lack of effect on IAHP in central neurons suggests that the channels underlying slow AHPs in those neurons are pharmacologically distinct from analogous channels in peripheral neurons.     

The role of dihydropyridine-sensitive voltage-gated calcium channels in potassium-mediated neuronal survival

The survival of isolated neurons from chick embryo ciliary, sympathetic, and dorsal root ganglia is greatly enhanced by concentrations of extracellular potassium that significantly depolarize the neurons (ED50 = 20-25 mM). The survival-promoting effect of elevated potassium on each of these 3 types of neurons appears to be the result of the opening of voltage-gated calcium channels. The dihydropyridine, Bay K 8644, which increases calcium influx through L-type voltage-gated calcium channels in neurons, strongly potentiated the survival-promoting action of elevated potassium (ED50 = 10.8 +/- 7.0 nM). In contrast, chemically closely related dihydropyridines, PN200-110 (ED50 = 0.33 +/- 0.15 nM) and nitrendipine (ED50 = 1.3 +/- 0.3 nM), which block calcium influx through the same voltage-gated channels, completely inhibited potassium-mediated neuronal survival. Chemically different agents that also block calcium influx through voltage-gated channels also inhibited potassium-mediated neuronal survival: the phenylalkylamine verapamil (ED50 = 0.78 +/- 0.38 microM), the benzothiazepine diltiazem (ED50 = 1.7 microM), and the inorganic ion cadmium (ED50 = 5.8 microM). These calcium-channel blockers are not simply toxic to neurons, since they did not inhibit neuronal survival mediated by the neurotrophic proteins, nerve growth factor, basic fibroblast growth factor, or ciliary neurotrophic factor, also suggesting that voltage-gated calcium channels are not involved in the action of these factors. These results suggest that neuronal survival in elevated potassium in ciliary, sympathetic, and dorsal root ganglion neurons is the result of calcium influx through dihydropyridine-sensitive, L-type voltage-gated calcium channels. These findings are discussed in relation to the neuronal toxicity of excitatory amino acids which is also thought to occur through increased calcium influx.     

Involvement of DHP voltage-sensitive calcium channels and protein kinase C in thyroliberin (TRH) release by developing hypothalamic neurons in culture

The intracellular mechanisms regulating the process of thyroliberin (TRH) release were studied using fetal hypothalamic neurons grown in serum-free medium. In particular, we compared the effects of dihydropyridine (DHP) derivatives, omega-conotoxin and phorbol esters on basal and K+-evoked TRH release from 12 days in vitro (DIV) neurons. BAY K 8644, a DHP calcium channel agonist increased in a dose-related manner basal and K+-evoked TRH release. PN 200-110, an antagonist of DHP-sensitive calcium channels, completely suppressed the effect of BAY K 8644, whatever the extracellular K+ concentration, but did not modify basal or K+-evoked TRH release. In contrast, omega-conotoxin partially inhibited the two latter processes. The active phorbol ester 12-O-tetradecanoyl-phorbol-beta-acetate (TPA), and to a lesser extent Sn-1,2-dioctanoylglycerol (DAG), triggered TRH release. This effect was specific, time and dose dependent and only partly dependent on extracellular calcium. Simultaneous addition of BAY K 8644 and TPA to the cells displayed a synergistic effect. The same compounds were studied on younger neurons (6-DIV cultures): BAY K 8644 stimulated TRH release whereas neither 60 mM K+ nor TPA did. These results suggest that TRH release can be mediated at least by two intracellular routes: (i) increase of intracellular calcium mediated by the opening of different types of voltage sensitive calcium channels, and (ii) activation of protein kinase C (PKC). The asynchrony in the maturation of the intracellular mechanisms underlying TRH release may be explained by different subcellular localizations of these mechanisms in neurons and is discussed in relation to synapse differentiation.     

Depolarization-dependent actions of dihydropyridines on synaptic transmission in the in vitro rat hippocampus

Field potential and intracellular recordings were obtained in the in vitro hippocampal slice to study the effects on synaptic transmission of dihydropyridine (DHP) derivatives. Nimodipine or nifedipine by itself had little effect upon the postsynaptic response as determined by field potential analysis. However, facilitation became evident when DHP application was coupled with manipulations which induced a moderate degree of membrane depolarization. In accordance with the hydrophobic nature of these compounds, extensive washing in normal Krebs' solution failed to reverse the facilitation indicating that the DHP effects outlasted the induced depolarization. Nifedipine is photolabile and its actions were reversed when intense light was applied to the slice. Application of the DHP Bay K 8644, resulted in a similar depolarization-dependent increase in neuronal excitability which, upon washout and exposure to light, was at first attenuated and then reversed, resulting in a long-lasting depression of the EPSP that was sensitive to caffeine. This depressant action of Bay K 8644 appeared to be mediated at a site presynaptic to the pyramidal cell because the postsynaptic component of the field potential response to pulsed applications of glutamate was not altered. Intracellular recording from CA1 neurons supports a presynaptic locus for the depressant actions of Bay K 8644; spike threshold for synaptically evoked responses was greatly increased while spike threshold to direct depolarization of the soma was unchanged. These results indicate that DHPs can exert effects on synaptic transmission in hippocampal brain slice under conditions of moderate membrane depolarization.