Hippocampal CA1 pyramidal cells of rats have four voltage-dependent calcium conductances

Differential Modulation of Rhythmic Brain Activity in Healthy Adults by a T-Type Calcium Channel Blocker: An MEG Study

1-octanol is a therapeutic candidate for disorders involving the abnormal activation of the T-type calcium current since it blocks this current specifically. Such disorders include essential tremor and a group of neurological and psychiatric disorders resulting from thalamocortical dysrhythmia (TCD). For example, clinically, the observable phenotype in essential tremor is the tremor itself. The differential diagnostic of TCD is not based only on clinical signs and symptoms. Rather, TCD incorporates an electromagnetic biomarker, the presence of abnormal thalamocortical low frequency brain oscillations. The effect of 1-octanol on brain activity has not been tested. As a preliminary step to such a TCD study, we examined the short-term effects of a single dose of 1-octanol on resting brain activity in 32 healthy adults using magnetoencephalograpy. Visual inspection of baseline power spectra revealed that the subjects fell into those with strong low frequency activity (set 2, n = 11) and those without such activity, but dominated by an alpha peak (set 1, n = 22). Cross-validated linear discriminant analysis, using mean spectral density (MSD) in nine frequency bands as predictors, found overall that 82.5% of the subjects were classified as determined by visual inspection. The effect of 1-octanol on the MSD in narrow frequency bands differed between the two subject groups. In set 1 subjects the MSD increased in the 4.5-6.5Hz and 6.5-8.5 Hz bands. This was consistent with a widening of the alpha peak toward lower frequencies. In the set two subjects the MSD decrease in the 2.5-4.5 Hz and 4.5-6.5 Hz bands. This decreased power is consistent with the blocking effect of 1-octanol on T-type calcium channels. The subjects reported no adverse effects of the 1-octanol. Since stronger low frequency activity is characteristic of patients with TCD, 1-octanol and other T-type calcium channel blockers are good candidates for treatment of this group of disorders following a placebo-controlled study.

Ethanol inhibition of a T-type Ca²+ channel through activity of protein kinase C

BACKGROUND

T-type calcium channels (T-channels) are widely distributed in the central and peripheral nervous system, where they mediate calcium entry and regulate the intrinsic excitability of neurons. T-channels are dysregulated in response to alcohol administration and withdrawal. We therefore investigated acute ethanol (EtOH) effects and the underlying mechanism of action in human embryonic kidney (HEK) 293 cell lines, as well as effects on native currents recorded from dorsal root ganglion (DRG) neurons cultured from Long-Evans rats.

METHODS

Whole-cell voltage-clamp recordings were performed at 32 to 34°C in both HEK cell lines and DRG neurons. The recordings were taken after a 10-minute application of EtOH or protein kinase C (PKC) activator (phorbol 12-myristate 13-acetate [PMA]).

RESULTS

We recorded T-type Ca²⁺ currents (T-currents) from 3 channel isoforms (CaV3.1, CaV3.2, and CaV3.3) before and during administration of EtOH. We found that only 1 isoform, CaV3.2, was significantly affected by EtOH. EtOH reduced current density as well as producing a hyperpolarizing shift in steady-state inactivation of both CaV3.2 currents from HEK 293 cell lines and in native T-currents from DRG neurons that are known to be enriched in CaV3.2. A myristoylated PKC peptide inhibitor (MPI) blocked the major EtOH effects, in both the cell lines and the DRG neurons. However, PMA effects were more complex. Lower concentration PMA (100 nM) replicated the major effects of EtOH, while higher concentration PMA (1 μM) did not, suggesting that the EtOH effects operate through activation of PKC and were mimicked by lower concentration of PMA.

CONCLUSIONS

EtOH primarily affects the CaV3.2 isoform of T-type Ca²⁺ channels acting through PKC, highlighting a novel target and mechanism for EtOH effects on excitable membranes.

Stimulation of Ca²+ signals in neurons by electrically coupled electrolyte-oxide-semiconductor capacitors

Electrolyte-oxide-semiconductor capacitors (EOSCs) are a class of microtransducers for extracellular electrical stimulation that have been successfully employed to activate voltage-dependent sodium channels at the neuronal soma to generate action potentials in vitro. In the present work, we report on their use to control Ca²+ signalling in cultured mammalian cells, including neurons. Evidence is provided that EOSC stimulation with voltage waveforms in the microsecond or nanosecond range activates two distinct Ca²+ pathways, either by triggering Ca²+ entry through the plasma membrane or its release from intracellular stores. Ca²+ signals were activated in non-neuronal and neuronal cell lines, CHO-K1 and SH-SY5Y. On this basis, stimulation was tailored to rat and bovine neurons to mimic physiological somatic Ca²+ transients evoked by glutamate. Being minimally invasive and easy to use, the new method represents a versatile complement to standard electrophysiology and imaging techniques for the investigation of Ca²+ signalling in dissociated primary neurons and cell lines.

VOLTAGE-GATED CALCIUM CHANNELS ARE NOT AFFECTED BY THE NOVEL ANTI-EPILEPTIC DRUG LACOSAMIDE

The novel anti-epileptic drug lacosamide targets two proteins - voltage-gated sodium channels and collapsin response mediator protein 2 (CRMP-2) - suggesting dual modes of action for lacosamide. We recently identified the neurite outgrowth and axonal guidance protein CRMP-2 as a novel partner and regulator of the presynaptic N-type voltage-gated Ca(2+) channel (CaV2.2) [Brittain et al., J. Biol. Chem. 284: 31375-31390 (2009)]. Here we examined the effects of lacosamide on voltage-gated Ba(2+) channels. Lacosamide did not affect Ba(2+) currents via N- and P/Q- channels in rat hippocampal neurons or L-type Ca(2+) channels in a mouse CNS neuronal cell line, respectively. N-type Ba(2+) currents, augmented by CRMP-2 expression, were also unaffected by acute or chronic lacosamide exposure. These results establish that the anti-epileptic mode of action of lacosamide does not involve these voltage-gated Ca(2+) channels.

Effects of T-type calcium channel blockers on cocaine-induced hyperlocomotion and thalamocortical GABAergic abnormalities in mice

RATIONALE

Repetitive cocaine exposure has been shown to induce GABAergic thalamic alterations. Given the key role of T-type (Ca(V)3) calcium channels in thalamocortical physiology, the direct involvement of these calcium channels in cocaine-mediated effects needs to be further explored.

OBJECTIVE

The objective of this study was to investigate the effect of T-type calcium channel blockers on acute and repetitive cocaine administration that mediates thalamocortical alterations in mice using three different T-type blockers: 2-octanol, nickel, and mibefradil.

METHODS

During in vitro experiments, whole-cell patch-clamp recordings were conducted in ventrobasal (VB) thalamic neurons from mice treated with acute repetitive cocaine administration (3 x 15 mg/kg, i.p., 1 h apart), under bath application of mibefradil (10 μM), 2-octanol (50 μM), or nickel (200 μM). After systemic administration of T-type calcium channel blockers, we evaluated locomotor activity and also recorded GABAergic neurotransmission onto VB neurons in vitro.

RESULTS

Bath-applied mibefradil, 2-octanol, or nickel significantly reduced both GABAergic neurotransmission and T-type currents of VB neurons in cocaine-treated mice. In vivo i.p. pre-administration of either mibefradil (20 mg/kg and 5 mg/kg) or 2-octanol (0.5 mg/kg and 0.07 mg/kg) significantly reduced GABAergic mini frequencies onto VB neurons. Moreover, both mibefradil and 2-octanol were able to decrease cocaine-induced hyperlocomotion.

CONCLUSION

The results shown in this study strongly suggest that T-type calcium channels play a key role in cocaine-mediated GABAergic thalamocortical alterations, and further propose T-type channel blockers as potential targets for future pharmacological strategies aimed at treating cocaine's deleterious effects on physiology and behavior.

Mechanisms of inhibition of CaV3.1 T-type calcium current by aliphatic alcohols

Many aliphatic alcohols modulate activity of various ion channels involved in sensory processing and also exhibit anesthetic capacity in vivo. Although the interaction of one such compound, 1-octanol (octanol) with different T-type calcium channels (T-channels) has been described, the mechanisms of current modulation and its functional significance are not well studied. Using patch-clamp technique, we investigated the mechanisms of inhibition of T-currents by a series of aliphatic alcohols in recombinant human Ca(V)3.1 (alpha1G) T-channel isoform expressed in human embryonic kidney (HEK) 293 cells and thalamocortical (TC) relay neurons in brain slices of young rats. Octanol, 1-heptanol (heptanol) and 1-hexanol (hexanol) inhibited the recombinant Ca(V)3.1 currents in concentration-dependent manner yielding IC(50) values of 362 microM, 1063 microM and 3167 microM, respectively. Octanol similarly inhibited native thalamic Ca(V)3.1 T-currents with an IC(50) of 287 microM and diminished burst firing without significant effect on passive membrane properties of these neurons. Inhibitory effect of octanol on T-currents in both native and recombinant cells was accompanied with accelerated macroscopic inactivation kinetics and hyperpolarizing shift in the steady-state inactivation curve. Additionally, octanol induced a depolarizing shift in steady-state activation curves of T-current in TC neurons. Surprisingly, the recovery from fast inactivation at hyperpolarized membrane potentials was accelerated by octanol up 3-fold in native but not recombinant channels. Given the importance of thalamocortical pathways in providing sleep, arousal, and anesthetic states, modulation of thalamic T-currents may at least contribute to the pharmacological effects of aliphatic alcohols.

Mechanisms of inhibition of T-type calcium current in the reticular thalamic neurons by 1-octanol: implication of the protein kinase C pathway

Recent studies indicate that T-type calcium channels (T-channels) in the thalamus are cellular targets for general anesthetics. Here, we recorded T-currents and underlying low-threshold calcium spikes from neurons of nucleus reticularis thalami (nRT) in brain slices from young rats and investigated the mechanisms of their modulation by an anesthetic alcohol, 1-octanol. We found that 1-octanol inhibited native T-currents at subanesthetic concentrations with an IC(50) of approximately 4 muM. In contrast, 1-octanol was up to 30-fold less potent in inhibiting recombinant Ca(V)3.3 T-channels heterologously expressed in human embryonic kidney cells. Inhibition of both native and recombinant T-currents was accompanied by a hyperpolarizing shift in steady-state inactivation, indicating that 1-octanol stabilized inactive states of the channel. To explore the mechanisms underlying higher 1-octanol potency in inhibiting native nRT T-currents, we tested the effect of the protein kinase C (PKC) activator phorbol 12-myristate 13-acetate (PMA) and PKC inhibitors. We found that PMA caused a modest increase of T-current, whereas the inactive PMA analog 4alpha-PMA failed to affect T-current in nRT neurons. In contrast, 12-(2-cyanoethyl)-6,7,12,13-tetrahydro-13-methyl-5-oxo-5H-indolo(2,3-a)pyrrolo(3,4-c)-carbazole (Go 6976), an inhibitor of calcium-dependent PKC, decreased baseline T-current amplitude in nRT cells and abolished the effects of subsequently applied 1-octanol. The effects of 1-octanol were also abolished by chelation of intracellular calcium ions with 1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid. Taken together, these results suggest that inhibition of calcium-dependent PKC signaling is a possible molecular substrate for modulation of T-channels in nRT neurons by 1-octanol.

A selective T-type Ca2+ channel blocker R(-) efonidipine

Recently, novel compound R(-) efonidipine was reported to selectively block low-voltage-activated (LVA or T-type) Ca2+ channels in peripheral organs. We examined how R(-) efonidipine acts on T-type and high-voltage-activated (HVA) Ca2+ channels in mammalian central nervous system (CNS) neurons. Furthermore, we compared the effects of R(-) efonidipine with those of flunarizine and mibefradil on both T-type and HVA Ca2+ channels in rat hippocampal CA1 neurons by using the nystatin perforated-patch clamp technique. Flunarizine and mibefradil nonselectively inhibited both T-type and HVA Ca2+ channels, though the dose-dependent blocking potency of flunarizine on T-type Ca2+ channels was slightly stronger than that of mibefradil. In contrast, R(-) efonidipine inhibited only T-type Ca2+ channels and did not show any effect on HVA Ca2+ channels. The inhibitory actions of R(-) efonidipine or flunarizine were similar on both Ba2+ and Ca2+ current components passing through T-type Ca2+ channels. In addition, flunarizine but not R(-) efonidipine inhibited voltage-dependent Na+ channels and Ca2+-activated K+ channels. Thus, it appears that R(-) efonidipine is a selective blocker for T-type Ca2+ channels. It could be used as a pharmacological tool in future studies on T-type Ca2+ channels.

Recruitment of apical dendritic T-type Ca2+ channels by backpropagating spikes underlies de novo intrinsic bursting in hippocampal epileptogenesis

A single episode of status epilepticus (SE) induced in rodents by the convulsant pilocarpine, produces, after a latent period of > or = 2 weeks, a chronic epileptic condition. During the latent period of epileptogenesis, most CA1 pyramidal cells that normally fire in a regular pattern, acquire low-threshold bursting behaviour, generating high-frequency clusters of 3-5 spikes as their minimal response to depolarizing stimuli. Recruitment of a Ni(2+)- and amiloride-sensitive T-type Ca(2+) current (I(CaT)), shown to be up-regulated after SE, plays a critical role in burst generation in most cases. Several lines of evidence suggest that I(CaT) driving bursting is located in the apical dendrites. Thus, bursting was suppressed by focally applying Ni(2+) to the apical dendrites, but not to the soma. It was also suppressed by applying either tetrodotoxin or the K(V)7/M-type K(+) channel agonist retigabine to the apical dendrites. Severing the distal apical dendrites approximately 150 microm from the pyramidal layer also abolished this activity. Intradendritic recordings indicated that evoked bursts are associated with local Ni(2+)-sensitive slow spikes. Blocking persistent Na(+) current did not modify bursting in most cases. We conclude that SE-induced increase in I(CaT) density in the apical dendrites facilitates their depolarization by the backpropagating somatic spike. The I(CaT)-driven dendritic depolarization, in turn, spreads towards the soma, initiating another backpropagating spike, and so forth, thereby creating a spike burst. The early appearance and predominance of I(CaT)-driven low-threshold bursting in CA1 pyramidal cells that experienced SE most probably contribute to the emergence of abnormal network discharges and may also play a role in the circuitry reorganization associated with epileptogenesis.

Protective effect of nilvadipine against glutamate neurotoxicity in purified retinal ganglion cells

We determined the effect of nilvadipine, a dihydropyridine-type calcium channel blocker, in preventing glutamate neurotoxicity in purified retinal ganglion cells (RGCs). RGCs were purified from dissociated rat retinal cells (postnatal days 6-8), using a modified two-step panning method, and cultured in serum-free medium containing neurotrophic factors and forskolin. RGC survival after exposure to glutamate (25 microM) with nilvadipine or other calcium channel blockers was measured by calcein-acetoxymethyl ester staining after 3 days in culture. Changes in the level of intracellular Ca(2+) ([Ca(2+)](i)) were measured with fura-2 fluorescence. Induction of apoptosis was evaluated using the TDT-dUTP terminal nick-end labeling technique. The neurotoxic effects of low doses of glutamate were blocked by a specific alpha-amino-3-dihydro-5-methylisoxazole-4-propionate-kainate receptor antagonist, 6,7-dinitroquinoxaline-2,3-dione (20 microM). Simultaneous application of nilvadipine (1-100 nM) with glutamate protected against glutamate neurotoxicity in a dose-dependent manner. Calcium-imaging experiments showed that the glutamate-evoked [Ca(2+)](i) increase was significantly blocked by nilvadipine (P<0.001), but not nifedipine and diltiazem, in about 50% of RGCs. In addition, the application of nilvadipine significantly reduced glutamate-induced apoptosis (P<0.001). These findings suggest that nilvadipine may partly inhibit glutamate-induced apoptotic cell death by blocking calcium influx via voltage-dependent calcium channels in purified RGCs.

Neuronal populations of rat cerebral cortex and hippocampus expressed a higher density of L-type Ca 2+ channel than corresponding cerebral vessels

Dihydropyridine (DHP)-type Ca2+ antagonists block primarily L-type Ca2+ channels and are used in the therapy of hypertension. They were also proposed for the treatment of several central nervous system disorders. In brain, these compounds bind both neuronal and vascular Ca2+ channels, but no studies have evaluated comparatively their density at neuronal and vascular level. This study has analyzed the pharmacological profile and the anatomical localization of L-type Ca2+ channels in rat frontal cortex, hippocampus and in forebrain pial and intracerebral arteries by radioligand binding assay and high resolution light microscope autoradiography. The DHP derivative [3H]nicardipine was used as a radioligand. Binding of [3H]nicardipine was consistent with the labeling of L-type Ca2+ channels. In frontal cortex, the highest density of binding sites was found in nerve cell body region, followed by the neuropil and the wall of intracerebral arteries. In hippocampus, the density of binding sites was higher in the nerve cell body region than in the neuropil of CA1, CA3, and CA4 subfields. In the dentate gyrus, a higher density of silver grains was developed in neuropil than in nerve cell body of granule neurons. With the exception of dentate gyrus, neuronal binding sites were more expressed than vascular binding sites in the hippocampus. In pial arteries [3H]nicardipine binding density decreased concomitant with the reduction of vessel diameter, whereas in intracerebral arteries [3H]nicardipine binding density displayed an opposite pattern. The above findings indicate that in brain the density of neuronal L-type Ca2+ channels was significantly higher than that of vascular ones. This may account for more pronounced neuronal than vascular effects after pharmacological manipulation of cerebral Ca2+ channels.

Upregulation of a T-type Ca2+ channel causes a long-lasting modification of neuronal firing mode after status epilepticus

A single episode of status epilepticus (SE) causes numerous structural and functional changes in the brain that can lead to the development of a chronic epileptic condition. Most studies of this plasticity have focused on changes in excitatory and inhibitory synaptic properties. However, the intrinsic firing properties that shape the output of the neuron to a given synaptic input may also be persistently affected by SE. Thus, 54% of CA1 pyramidal cells, which normally fire in a regular mode, are persistently converted to a bursting mode after an episode of SE induced by the convulsant pilocarpine. In this model, intrinsic bursts evoked by threshold-straddling depolarizations, and their underlying spike afterdepolarizations (ADPs), were resistant to antagonists of N-, P/Q-, or L-type Ca2+ channels but were readily suppressed by low (30-100 microm) concentrations of Ni2+ known to block T- and R-type Ca2+ channels. The density of T-type Ca2+ currents, but not of other pharmacologically isolated Ca2+ current types, was upregulated in CA1 pyramidal neurons after SE. The augmented T-type currents were sensitive to Ni2+ in the same concentration range that blocked the novel intrinsic bursting in these neurons (IC50 = 27 microm). These data suggest that SE may persistently convert regular firing cells to intrinsic bursters by selectively increasing the density of a Ni2+-sensitive T-type Ca2+ current. This nonsynaptic plasticity considerably amplifies the output of CA1 pyramidal neurons to synaptic inputs and most probably contributes to the development and expression of an epileptic condition after SE.

Molecular pharmacology of T-type Ca2+ channels

Over the past few years increasing attention has been focused on T-type calcium channels and their possible physiological and pathophysiological roles. Efforts toward elucidating the exact role(s) of these calcium channels have been hampered by the lack of T-type specific antagonists, resulting in the subsequent use of less selective calcium channel antagonists. In addition, the activity of these blockers often varies with cell or tissue type, as well as recording conditions. This review summarizes a variety of compounds that exhibit varying degrees of blocking activity towards T-type Ca2+ channels. It is designed as an aid for researchers in need of antagonists to study the biophysical and pathological nature of T-type channels, as well as a starting point for those attempting to develop potent and selective antagonists of the channel.

Kinetic parameters of calcium currents in maturing acutely isolated CA1 cells

Calcium currents were recorded in CA1 hippocampal cells from immature (P(4-10)) and older (P(22-55)) rats, using whole-cell voltage clamp techniques. Parameters defining the voltage-dependence of activation (tau(m)) and inactivation (tau(h)), steady-state inactivation and activation were determined at both stages of maturation. Current density increased with maturation. A transient low voltage activated (l.v.a.) current was found in P(4-10) cells, but not in the older cells. At voltages less negative than -30 mV, current inactivation was best described by two exponentials (tau(hf), tau(hs)); the ratio of the amplitudes of the two components changed with maturation, with a dominance of the faster component (tau(hf)) in the younger cells. The voltage dependence of tau(hf) followed a simple dependence model, decreased with increasing depolarization, in all cells at both stages of maturation. In P(4-10) cells, tau(hs) was voltage insensitive (range -25 to +30 mV); in P(22-55) cells, the voltage dependence of tau(hs) was found to be complex. Two current components were identified from the voltage dependence of the conductance in both groups. The first, more hyperpolarized component, the l.v.a. current found in P(4-10) cells; this was absent in the older cells, in which we found a component with a different voltage dependence. The voltage dependence of the conductance of the second, more depolarized component did not differ in younger and older cells. In the course of maturation, the steady-state inactivation of the second component underwent a hyperpolarizing shift and a decrease in voltage sensitivity.

High-voltage-activated calcium channel messenger RNA expression in the 140-3 neuroblastoma-glioma cell line

Expression of calcium channel alpha1 subunits in oocytes or cell lines has proven to be a powerful method in the analysis of structure-function relations, but these experimental systems are of limited value in the examination of neuron-specific functions such as transmitter release. Cell lines derived from neurons are often capable of these functions, but their intrinsic calcium channel alpha1 subunits are complicating factors in experimental design. We have examined the biophysical and molecular properties of calcium channels in a little studied neuroblastoma-glioma hybrid cell line, 140-3, a close relative of the NG108-15 cell line, to test whether this cell line might serve a role as an expression system for neural mechanisms. This cell was selected as it contains an intact transmitter release mechanism yet secretes little in response to depolarization. Patch-clamp recording revealed only a prominent low-threshold, rapidly inactivating calcium current with a single-channel conductance of approximately 7 pS that was identified as T type. A search for calcium channel alpha1 subunit messenger RNA in the 140-3 cells with three different tests only revealed alpha1C, whereas alpha1A-alpha1C were present in the parent NG108-15 line. We made a particular effort to search for alpha1E, since this subunit has been associated with a low-voltage-activated current. Our findings suggest that, since the principal nerve terminal-associated calcium channels (alpha1A, alpha1B, alpha1E) are absent in the 140-3 cell, this cell line may prove a particularly useful model for the analysis of the role of high-voltage-activated calcium channels in complex functions of neuronal cells.

Mibefradil inhibition of T-type calcium channels in cerebellar purkinje neurons

The antihypertensive agent mibefradil completely and reversibly inhibited T-type calcium channels in freshly isolated rat cerebellar Purkinje neurons. The potency of mibefradil was increased at less hyperpolarized holding potentials, and the apparent affinity was correlated with the degree of channel inactivation. At 35 degrees, the apparent dissociation constant Kapp was 1 microM at a holding voltage of -110 mV (corresponding to noninactivated channels) and 83 nM at a holding voltage of -70 mV (corresponding to 65% inactivation). The increased affinity was attributable mainly to a decreased off-rate. Mibefradil also inhibited P-type calcium channels in Purkinje neurons, but inhibition was much less potent. At a holding potential of -70 mV, the Kapp for mibefradil inhibition of P-type channels was approximately 200-fold higher than that for inhibition of T-type channels. Mibefradil should be a useful compound for distinguishing T-type channels from high voltage-activated calcium channels in neurons studied in vitro.

Effect of nilvadipine on the voltage-dependent Ca2+ channels in rat hippocampal CA1 pyramidal neurons

Effects of nilvadipine on the low- and high-voltage activated Ca2+ currents (LVA and HVA ICa, respectively) were compared with other organic Ca2+ antagonists in acutely dissociated rat hippocampal CA1 pyramidal neurons. The inhibitory effects of nilvadipine, amlodipine and flunarizine on LVA ICa were concentration- and use-dependent. The apparent half-maximum inhibitory concentrations (IC50s) at every 1- and 30-s stimulation were 6.3x10-7 M and 1.8x10-6 M for flunarizine, 1.9x10-6 M and 7.6x10-6 M for nilvadipine, and 4.0x10-6 M and 8.0x10-6 M for amlodipine, respectively. Thus, the strength of the use-dependence was in the sequence of nilvadipine>flunarizine>amlodipine. Nilvadipine also inhibited the HVA ICa in a concentration-dependent manner with an IC50 of 1.5x10-7 M. The hippocampal CA1 neurons were observed to have five pharmacologically distinct HVA Ca2+ channel subtypes consisting of L-, N-, P-, Q- and R-types. Nilvadipine selectively inhibited the L-type Ca2+ channel current which comprised 34% of the total HVA ICa. On the other hand, amlodipine non-selectively inhibited the HVA Ca2+ channel subtypes. These results suggest that the inhibitory effect of nilvadipine on the neuronal Ca2+ influx through both LVA and HVA L-type Ca2+ channels, in combination with the cerebral vasodilatory action, may prevent neuronal damage during ischemia.

Properties of Ba2+ currents arising from human alpha1E and alpha1Ebeta3 constructs expressed in HEK293 cells: physiology, pharmacology, and comparison to native T-type Ba2+ currents

Currents arising from human alpha1E and alpha1Ebeta3 Ca2+ channel subunits expressed in HEK-293 cells were examined with whole-cell recording methods and compared to properties of T-current in DRG neurons studied under identical ionic conditions. Coexpression of alpha1E subunit with the beta3 subunit shifted activation to more negative potentials. Activation and deactivation of both variants were comparable at most voltages, with deactivation becoming faster, but less voltage-dependent, at more negative potentials. The inactivation time course for alpha1E and alpha1Ebeta3 currents was best described by at least two exponential components. Recovery from inactivation was markedly voltage-dependent and similar for both constructs. In comparison to alpha1E and alpha1Ebeta3 constructs, T current activation was shifted to more negative potentials, activation was typically slower, deactivation exhibited a steeper voltage-dependence, and recovery from inactivation was less voltage-dependent. Over most of the activation range, native T current inactivated more completely and in a single exponential fashion. Despite some pharmacological similarities (e.g. octanol, barbiturates) between alpha1E and T-type currents, aspects of blockade by amiloride and phenytoin appear to distinguish alpha1E current from T-type currents. The results define several distinguishing features of alpha1E currents that distinguish them from native T-type currents.

Maturational change of KCl-induced Ca2+ increase in the rat brain synaptosomes

To investigate maturational change in the susceptibility of voltage-dependent calcium (Ca2+) channels (VDCC) in the brain to excessive depolarization, which is likely to occur during hypoxia or ischemia, we studied depolarization-induced increases in Ca2+ concentration in cortical synaptosomes ([Ca2+]i) obtained from young (8, 15, 22, 36, and 43-day-old) and adult rats using fura 2-AM as a Ca2+ indicator. The effects of Ca2+ antagonists on the increase were also studied. The maximal increase in [Ca2+]i caused by 50 mM KCl-induced depolarization was significantly lower in 8-day-old rats (73.3 nM) compared with that in adult rats (133.6 nM). On the other hand, the time necessary for [Ca2+]i to decrease to 50% of its maximal level (tau) was significantly shorter in immature rats compared with that in adult rats and was particularly short in 8- and 15-day-old rats (0.28 and 0.40 min vs. 3.85 for adult rats). The maximal increase in [Ca2+]i in 22-day-old rats and tau in adult rats were markedly reduced by verapamil, omega-agatoxin IVA, and omega-conotoxin GVIA (antagonists of L-, P-, and N-type Ca2+ channels, respectively) to similar extents, while a mixture of the three antagonists markedly decreased both maximal increase and tau in 8- and 22-day-old and adult rats. These results indicate that depolarization-induced Ca2+ influx through VDCCs in immature rat brain is less pronounced than that in adult rats, and suggest that the susceptibility of all of L-, N-, and P-type Ca2+ channels is increased during maturation in the first few weeks after birth. This lower susceptibility to depolarization might be involved in the resistance to hypoxia in immature animals.

Contribution of T-type calcium channels to afterdischarge generation in rat hippocampal slices

To clarify the possible involvement of Ca2+ channel subtypes in epileptogenesis, the CA1 region of rat hippocampal slices was examined for the pharmacological effects of Ca2+ channel blockers on ictal-like afterdischarges (ADs) observed following the repetition of high-frequency electrical stimulation, as well as on interictal-like bursts of population spikes following single stimuli in the presence of bicuculline. Ni2+ and amiloride, which predominantly block T-type Ca2+ channels, suppressed the number of spikes in ADs at concentrations of these two channel blockers sufficient to eliminate this type of Ca2+ channel in acutely dissociated and cultured hippocampal neurons. On the other hand, neither the L-type Ca2+ channel blocker nifedipine nor the N-type Ca2+ channel blocker City, omega-conotoxin GVIA had any effect on the generation of ADs. In addition, none of these T-, L- and N-type channel blockers had any effect on the bicuculline-induced, interictal-like epileptiform discharges. We therefore conclude that the activation of T-type Ca2+ channels, which is distinct from the mechanisms involved in interictal activity, may play a causative role in the generation of ictal-like ADs.

Pharmacological properties of T-type Ca2+ current in adult rat sensory neurons: effects of anticonvulsant and anesthetic agents

We have used the whole cell patch-clamp method to study pharmacological properties of low-voltage-activated (LVA) Ca2+ current in freshly dissociated neurons from dorsal root ganglia of adult rats. Inward barium current [in the presence of internal fluoride to reduce L-type high-voltage-activated (HVA) and external 1 microM omega-conotoxin GVIA to block N-type HVA current- was evoked from negative holding potentials of -90 mV to test potentials of -25 mV and showed complete inactivation during 200-ms test pulses. Amiloride blocked approximately 90% of current with half-maximal block (EC50) of 75 microM and a Hill coefficient (n) of 0.99. LVA current was blocked completely by inorganic Ca2+ channel blockers: lanthanum (EC50 = 0. 53 microM) > zinc (EC50 = 11.3 microM) > cadmium (EC50 = 20 microM)> nickel (EC50 = 51 microM). The antiepileptics, ethosuximide (EC50 = 23.7 mM, n = 1.4), phenytoin (EC50 = 7.3 microM, n = 1.3), alpha-methyl-alpha-phenylsuccinimide (EC50 = 170 microM, n = 2.1), and valproic acid (EC50 = 330 microM, n = 1.9) maximally blocked approximately 100, 60, 26, and 17% of T current, respectively. Another antiepileptic, carbamazepine (</=100 microM), and convulsants such as pentylenetetrazole (1 mM) and tert-butyl-bicyclo [2.2.2] phosphorothionate (50 microM) had no effect on T current. Barbiturates completely blocked T current: thiopental (EC50 = 153 microM, n =1.2) > pentobarbital (EC50 = 334 microM, n = 1.2) > methohexital (EC50 = 502 microM, n = 1.3) > phenobarbital (EC50 = 1. 7 mM, n = 1.2). Blockade by thiopental and pentobarbital did not show voltage or use dependence. General anesthetics blocked T current completely and reversibly: propofol (EC50 = 12.9 microM, n = 1.3) > octanol(EC50 = 122 microM, n = 1.2) > etomidate (EC50 = 205 microM, n =1.3) > isoflurane (EC50 = 303 microM, n = 2.3) > halothane (EC50 = 655 microM, n = 2.0) > ketamine (EC50 = 2.5 mM, n = 1.1). Mibefradil, a novel Ca2+ channel blocker, blocked dorsal root ganglion T current in a voltage- and use-dependent fashion with an EC50 of approximately 3 microM (n = 1.3). When compared with results on other T currents, these data indicate that significant differences exist among different T currents in terms of pharmacological sensitivities. Furthermore, differences in pharmacological sensitivity of T currents among peripheral neurons, CNS, and neuroendocrine cells may contribute to the spectrum of effects of particular analgesic, anticonvulsant, and anesthetic drugs.

GABA-ergic transmission in deep cerebellar nuclei

gamma-Aminobutyric acid (GABA) is the inhibitory transmitter released at Purkinje cell axon terminals in deep cerebellar nuclei (DCN). Neurons in DCN also receive excitatory glutamatergic inputs from the inferior olive. The output of DCN neurons, which depends on the balance between excitation and inhibition on these cells, is involved in cerebellar control of motor coordination. Plasticity of synaptic transmission observed in other areas of the mammalian central nervous system (CNS) has received wide attention. If GABA-ergic and/or glutamatergic synapses in DCN also undergo plasticity, it would have major implications for cerebellar function. In this review, literature evidence for GABA-ergic synaptic transmission in DCN as well as its plasticity are discussed. Studies indicate that fast inhibitory postsynaptic potentials (IPSPs) and currents (IPSCs) in neurons of DCN are mediated by GABAA receptors. While GABAB receptors are present in DCN, they do not appear to be activated by Purkinje cell axons. The IPSPs undergo paired-pulse, as well as frequency-dependent, depressions. In addition, tetanic stimulation of inputs can induce a long-term depression (LTD) of the IPSPs and IPSCs. Excitatory synapses do not appear to undergo long-term potentiation or LTD. The LTD of the IPSP is not input-specific, as it can be induced heterosynaptically and is associated with a reduced response of DCN neurons to a GABAA receptor agonist. Postsynaptic Ca2+ and protein phosphatases appear to contribute to the LTD. The N-methyl-D-aspartate receptor-gated, as well as the voltage-gated Ca2+ channels are proposed to be sources of the Ca2+. It is suggested that LTD of GABA-ergic transmission, by regulating DCN output, can modulate cerebellar function.

Development of HVA and LVA calcium currents in pyramidal CA1 neurons in the hippocampus of the rat

High voltage activated (HVA) and low voltage activated (LVA) calcium currents were recorded in acutely dissociated CA1 hippocampal pyramidal neurons of the rat during the first three postnatal weeks as well as in adults. Measured in whole cell voltage clamp the amplitude of the HVA calcium current increased steadily and reached adult values after 20 postnatal days (P20). Using the perforated patch configuration with amphotericin B the amplitude of the HVA component was more than five times smaller, but the time course of development was the same. The LVA component also increased with age but reached adult values already around P13. The amplitude and developmental pattern of this component were not different when measured with the perforated patch technique. The results indicate a different role for intracellular modulators on these calcium currents, but exclude them as important factors in the developmental pattern. The fast development of the LVA component could lead to calcium dependent action potentials (and calcium spikes) in immature cells. The complex developmental pattern of the relative amplitude of the two currents will either lead to specific variations in the intracellular calcium homeostasis or will have to be accompanied by an adequate developmental pattern of buffering and extrusion mechanisms.

Effects of hypertonia on voltage-gated ion currents in freshly isolated hippocampal neurons, and on synaptic currents in neurons in hippocampal slices

We studied the effects of hypertonia on voltage-gated currents of freshly isolated hippocampal CA1 neurons, using open pipette whole-cell as well as gramicidin-perforated patch-clamp recording. Extracellular osmolarity (pi(o)) was raised by adding mannitol (50 or 100 mmol/l) to the bathing solution. Hypertonia depressed voltage-gated sodium, potassium and calcium currents in all trials. The threshold activation voltage of the currents did not change during hypertonic depression, but maximal activation of Ca2+ current shifted to a more negative potential, suggesting stronger depression of high- compared to low-voltage activated currents. During 30 min high pi(o) treatment (recorded with open pipette), the depression reached maximum in 10-15 min of exposure. The depression of the computed transient component of the K+ current recorded by open pipette was statistically not significant. Following hypertonic treatment recovery of the I(Na), the sustained I(K) and sustained I(Ca) were incomplete compared to control cells maintained in normal solution for an equal length of time. In hippocampal tissue slices hypertonia (+25, +50 and +100 mmol/l fructose) reversibly depressed excitatory postsynaptic currents (EPSCs). We conclude that the shutdown of membrane ion currents by elevated pi(o) is not selective, but the degree of the suppression varies among current types. Raising pi(o) in human patients, possibly combined with mild artificial acidosis, may be useful in the prevention and treatment of acute crises associated with excessive excitation or depolarization of neurons.

Differential sensitivity to intracellular pH among high- and low-threshold Ca2+ currents in isolated rat CA1 neurons

The effects of intracellular pH (pHi) on high-threshold (HVA) and low-threshold (LVA) calcium currents were examined in acutely dissociated rat hippocampal Ca1 neurons with the use of the whole cell patch-clamp technique (21-23 degrees C). Internal pH was manipulated by external exposure to the weak base NH4Cl or in some cases to the weak acid Na-acetate (20 mM) at constant extracellular pH (7.4). Confocal fluorescence measurements using the pH-sensitive dye SNARF-1 in both dialyzed and intact cells confirmed that NH4Cl caused a reversible alkaline shift. However, the external TEA-Cl concentration used during ICa recording was sufficient to abolish cellular acidification upon NH4Cl wash out. With 10 mM N-2-hydroxyethylpiperazine-N'-2-ethanesulfonic acid (HEPES) in the pipette, NH4Cl exposure reversibly enhanced HVA currents by 29%, whereas exposure to Na-acetate markedly and reversibly depressed HVA Ca currents by 62%. The degree to which NH4Cl enhanced HVA currents was inversely related to the internal HEPES concentration but was unaffected when internal ethylene glycol-bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid (EGTA) was replaced by equimolar bis-(o-aminophenoxy)-N,N,N',N'-tetraacetic acid (BAPTA). When depolarizing test pulses were applied shortly after break-in (Vh = -100 mV), NH4Cl caused a proportionally greater increase in the sustained current relative to the peak. The dihydropyridine Ca channel antagonist nifedipine (5 microM) blocked nearly all of this sustained current. A slowly inactivating nifedipine-sensitive (L-type) HVA current could be evoked from a depolarized holding potential of -50 mV; NH4Cl enhanced this current by 40 +/- 3% (mean +/- SE) and reversibly shifted the tail-current activation curve by +6-8 mV. L-type currents exhibited more rapid rundown than N-type currents; HVA currents remaining after prolonged cell dialysis, or in the presence of nifedipine, inactivated rapidly and were depressed by omega-conotoxin (GVIA). NH4Cl enhanced these N-type currents by 76 +/- 9%. LVA Ca currents were observed in 32% of the cells and exhibited little if any rundown. These amiloride-sensitive currents activated at voltages negative to -50 mV, were enhanced by extracellular alkalosis and depressed by extracellular acidosis, but were unaffected by exposure to either NH4Cl or NaAC. These results demonstrate that HVA Ca currents in hippocampal CA1 neurons are bidirectionally modulated by internal pH shifts, and that N-type currents are more sensitive to alkaline shifts than are L- or T-type (N > L > T). Our findings strengthen the idea that distinct cellular processes governed by different Ca channels may be subject to selective modulation by uniform shifts in cytosolic pH.

Multiple channel types contribute to the low-voltage-activated calcium current in hippocampal CA3 pyramidal neurons

Hippocampal neurons exhibit low-voltage-activated (LVA) and high-voltage-activated (HVA) calcium currents. We characterized the LVA current by recording whole-cell Ca2+ currents from acutely isolated rat hippocampal CA3 pyramidal neurons in 2 mM Ca2+. Long depolarizing steps to -50 mV revealed two components to the LVA current: transient and sustained. The transient phase had a fast decay time constant of 59 msec. The sustained phase persisted throughout the depolarization, even for steps lasting several seconds. The transient current was inhibited by the classic T-type channel antagonists Ni2+ and amiloride. The anticonvulsant phenytoin preferentially blocked the sustained phase, but ethosuximide had no effect. Steady-state inactivation of the transient component was half-maximal at -80 mV. Nimodipine, an L-type channel antagonist, partly inhibited the sustained current. BayK-8644, an L-type channel agonist, potentiated the sustained current. Calciseptine, another L-type channel antagonist, inhibited the sustained component. omega-Conotoxin-MVIIC, a nonselective toxin for HVA channels, had no effect on either of the LVA current components. omega-Grammotoxin-SIA, another nonselective toxin, partially inhibited the sustained component. The voltage dependence of activation of the nimodipine-sensitive current could be fit with a single Boltzmann, consistent with a homogenous population of L-type channels in CA3 neurons. Half-maximal activation of the nimodipine-sensitive current occurred at -30 mV, considerably more negative than the remaining HVA current. These results suggest that in physiologic Ca2+ more than one type of Ca2+ channel contributes to the LVA current in CA3 neurons. The transient current is carried by T-type channels. The sustained current is carried, at least in part, by dihydropyridine-sensitive channels. Thus, the designation "low-voltage-activated" should not be limited to T-type channels. These findings challenge the traditional designation of L-type channels as exclusively HVA and reveal a possible role in subthreshold Ca2+ signaling.

A TTX-sensitive conductance underlying burst firing in isolated pyramidal neurons from rat neocortex

Pyramidal neurons were acutely isolated from neocortex slices of 14- to 20-day-old rats and patch-clamped under physiological conditions. Current-clamp recordings revealed firing patterns corresponding to those previously reported in slices as regular spiking (RS) and intrinsically bursting (IB), i.e., single action potentials (AP), trains of regular spikes and bursts with depolarizing after-potentials (DAP). In IB neurons, intracellular perfusion with KF blocked the high-voltage-activated Ca2+ and the Ca(2+)-dependent K+ currents, revealing APs with a 10-30 ms shoulder at -35 mV (shoulder AP), which was the supporting plateau of the intraburst spikes. The use of the A channel blocker, 4-aminopyridine, caused a three-fold reduction in the AP repolarizing rate. A study of the de- and repolarizing rates modulating the spike shape (shoulder AP, burst or single APs) suggested that the percentage of available A channels could play a crucial role in burst formation. Blockade of the residual T-type Ca2+ current by Ni2+ did not inhibit the AP shoulder, whereas it was completely and reversibly inhibited by 30 nM TTX, which did not affect AP amplitude. The AP rising rate was only halved by 100 nM TTX. The data concerning the A channel-mediated burst formation and the role of the TTX-sensitive conductance have been successfully simulated in a model cell. We suggest that bursting is an intrinsic property of the membrane of neocortex neurons, and is sustained by TTX-sensitive slowly inactivating and/or persistent Na+ conductances.

Calcium currents in pyramidal CA1 neurons in vitro after kindling epileptogenesis in the hippocampus of the rat

Calcium is an important second messenger which plays a role in the regulation of neuronal excitability and in many forms of synaptic plasticity. In kindling epileptogenesis, a model of focal epilepsy, calcium plays an important role. The in situ patch-clamp technique was used to record calcium currents in slices obtained from kindled rats and controls. We found that low-voltage-activated calcium currents, probably of dendritic origin, were larger after kindling (80%). The transient high-voltage-activated calcium currents were also enhanced after kindling (50% higher). The increase of the current is accompanied by a decrease in the time constant of inactivation. The change was still present six weeks after the kindling stimulations were stopped. These data demonstrate that low-voltage-activated calcium currents are involved in epileptogenesis. Their enhancement in the dendrites will boost synaptic depolarization and result in enhanced calcium influx, which is critically dependent on the specific activation pattern.

Effects of extracellular pH on voltage-gated Na+, K+ and Ca2+ currents in isolated rat CA1 neurons

1. The effects of extracellular H+ (pHo) in the pathophysiological range (pH 6-8) on voltage-gated sodium, potassium, and calcium currents were examined in acutely dissociated rat hippocampal CA1 neurons using the whole-cell patch clamp technique. All experiments were conducted in Hepes-buffered solutions and were performed at room temperature (21-23 degrees C). 2. TTX-sensitive sodium currents, evoked by both step and ramp depolarization, were reversibly depressed by moderate acidosis and enhanced slightly by alkaline exposure. Changes in current amplitude were coincident with small reversible shifts (+/- 3 mV) in the voltage dependence of activation. In contrast, sodium current activation and decay kinetics as well as steady-state inactivation were unaffected by acidosis. 3. Outward potassium currents could be separated into a transient, rapidly inactivating current (IA) and a sustained, slowly inactivating component (IK). Steady-state activation of both currents was unaffected by an increase or decrease in pHo. Similarly, IK activation and IA decay kinetics remained stable during pHo exchange. In contrast, the steady-state inactivation (h infinity) of both potassium currents was reversibly shifted by approximately +10 mV during acid exposure, but remained unchanged during alkaline treatment. 4. Calcium currents were found to be predominantly of the high-voltage-activated (HVA) type, which could be carried by Ba2+ and inhibited completely by cadmium. Moderate acidosis (pH 6.9-6.0) reversibly depressed HVA Ca2+ current amplitude and caused a positive shift in its voltage dependence. For both of these parameters, alkaline treatment (pH 8.0) had the opposite effect. The depression of HVA Ca2+ currents by low pHo was unaffected by raising the internal Hepes concentration from 10 to 50 mM in the patch pipette. A Hill plot of the effect of pH on Ca2+ current amplitude revealed a pK value (defined as the mid-point of the titration curve) of 7.1 and a slope of 0.6. 5. The rate of Ca2+ current activation was unaffected by pHo at positive potentials, but below 0 mV the activation rate increased at low pH and decreased at high pH, becoming significant at -20 mV. At this membrane voltage, a second HVA current was revealed during acid exposure as the whole-cell HVA current was depressed. Ca2+ current decay was described by two time constants, both of which were significantly reduced at pH 6.4 and slightly enhanced at pH 8.0. Steady-state Ca2+ current inactivation reached 50% near -50 mV and was not affected at either pH extreme. 6. These results demonstrate that extracellular pH shifts within the pathophysiological range are capable of modulating both the conductance and gating properties of voltage-gated ion channels in hippocampal CA1 neurons. The effects we describe are consistent with the wellknown effects of pHo on neuronal excitability and strengthen the idea that endogenous pHo shifts may help regulate cell activity in situ.

Acamprosate (calcium acetylhomotaurinate) enhances the N-methyl-D-aspartate component of excitatory neurotransmission in rat hippocampal CA1 neurons in vitro

The taurinate analog acamprosate (calcium acetylhomotaurinate) has received considerable attention in Europe for its ability to prevent relapse in abstained alcoholics. To determine the mechanism of acamprosate actions in the CNS, we superfused acamprosate onto rat hippocampal CA1 pyramidal neurons using an in vitro slice preparation. In current-and voltage-clamp recordings, acamprosate (100 to 100 microM) superfusion had little effect on resting membrane potential or input slope resistance. Acamprosate had no effect on Ca(2+)-dependent action potentials when tetrodotoxin was used to block Na+ spikes. In whole-cell voltage-clamp recordings, and in the presence of tetraethylammonium and Cs+ to block K+ channels, acamprosate had little effect on a Cd(2+)-sensitive inward current likely to be a high voltage-activated Ca2+ current. However, in both current- and voltage-clamp recordings, acamprosate significantly increased the N-methyl-D-aspartate (NMDA) component of excitatory postsynaptic potentials evoked by stimulation of Schaffer collaterals in the stratum radiatum, in the presence of the selective non-NMDA (R,S)-alpha-amino-3-hydroxy-5-methylisoxazole-4-proprionic acid kainate) glutamate receptor antagonist 6-cyano-7-nitro-quinoxaline-2,3-dione and the GABAA receptor antagonist bicuculline. Acamprosate had inconsistent or no effects on the stratum radiatum-evoked non-NMDA component of the excitatory postsynaptic potentials, in the presence of bicuculline and the NMDA antagonist DL-2-amino-5-phosphonovalerate. Acamprosate, on average, had little effect on the late inhibitory postsynaptic potentials thought to be mediated by GABAB receptors. In the presence of tetrodotoxin to block synaptic transmission, acamprosate dramatically increased inward current responses in most CA1 neurons to exogenous NMDA applied by pressure or superfusion, with reversal on washout of acamprosate. These data suggest that acamprosate may act postsynaptically to increase the NMDA component of excitatory transmission to hippocampal CA1 pyramidal neurons. Considering the known interaction of ethanol with NMDA receptors, this acamprosate modulation of NMDA receptor-mediated neurotransmission could provide a mechanism of action underlying the clinical efficacy of acamprosate.

Ca(2+)-antagonistic action of bevantolol on hypothalamic neurons in vitro: its comparison with those of other beta-adrenoceptor antagonists, a local anesthetic and a Ca(2+)-antagonist

The Ca(2+)-antagonistic action of bevantolol, a beta 1-adrenoceptor antagonist, on high- and low-voltage activated Ca2+ currents (HVA- and LVA-ICa) was examined on neurons dissociated from rat brain. Bevantolol (10(-6) to 10(-4) M) inhibited concentration-dependently both ICa. The IC50 value of bevantolol for LVA-ICa was 4 x 10(-5) M, while bevantolol at 10(-4) M inhibited HVA-ICa by 28.5 +/- 7.7%. The potency of bevantolol in inhibiting both ICa was greater than those of propranolol, labetalol and lidocaine, while the inhibitory action of bevantolol on voltage-activated Na+ current was weakest among them. Bevantolol may possess Ca(2+)-antagonistic action that is independent from local anesthetic action.

How has molecular pharmacology contributed to our understanding of the mechanism(s) of general anesthesia?

This review discusses the mechanism(s) of general anesthesia from a pharmacological viewpoint; in particular, the ability of drugs to produce many different effects is emphasised. The problems of experimental measurement of general anesthesia are discussed, and the possibilities for antagonism and potentiation of anesthesia considered. Physicochemical studies on anesthesia are described, as are the advancement of ideas beyond consideration of lipids and proteins as separate sites of action. The importance of studies on different areas of the brain is highlighted, and the review finishes with a survey of the effects of general anesthetics on synaptic transmission which emphasises the problems of extrapolation from in vitro to in vivo.

Norepinephrine modulates high voltage-activated calcium channels in freshly dissociated rat nucleus tractus solitarii neurons

The effects of norepinephrine on the low- and high-voltage-activated calcium channels in the neurons acutely dissociated from the nucleus tractus solitarius of 2- to 3-week-old rats were investigated in the nystatin perforated patch recording configuration under voltage-clamp conditions. The norepinephrine had no effect on the low voltage-activated calcium channel but inhibited the high voltage-activated calcium channel in a concentration-, time- and voltage-dependent manner. The norepinephrine slowed the activation phase of the high voltage-activated calcium channel current and the maximum inhibition was 30% of the total current amplitude measured 10 ms after the current activation. The inhibitory effect was eliminated by applying larger depolarizing prepulses. The pretreatment with pertussis toxin completely blocked the norepinephrine effect on high-voltage activated calcium channels, suggesting the contribution of pertussis toxin-sensitive Gi/Go-proteins to the norepinephrine-induced inhibition. Yohimbine but not prazosin nor propranolol antagonized the norepinephrine-induced inhibition, suggesting the involvement of alpha 2-adrenoceptor in norepinephrine-induced inhibition of the high voltage-activated calcium channels. omega-Conotoxin-GVIA, omega-agatoxin-IVA, nicardipine and omega-conotoxin-MVIIC blocked the high voltage-activated calcium channel current by 26, 9, 36 and 11% of the total current respectively, suggesting the existence of N-, P-, L- and Q-type calcium channels in the nucleus tractus solitarii neurons. The current being insensitive to these calcium channel antagonists, termed R-type calcium channel current, also existed. This residual R-type calcium channel was completely blocked by adding 200 microM CD2+. The norepinephrine significantly inhibited N- and P-type calcium channels.(ABSTRACT TRUNCATED AT 250 WORDS)

Excitatory amino acid induced currents of isolated murine hypothalamic neurons and their suppression by 2,3-butanedione monoxime

Ionic currents induced by excitatory amino acids were investigated for freshly isolated murine hypothalamic neurons with whole cell recording techniques. L-glutamate or N-methyl-D-aspartate (NMDA), in combination with glycine, resulted in a rapidly rising current which decayed in the continued presence of agonist. In contrast, kainate currents did not decay. While quisqualate-induced current maintained a steady amplitude in the continued presence of agonist, a rapid decay phase appeared at holding potentials negative to -50 mV. Co-application of 2,3-butanedione monoxime (BDM) reversibly inhibited the currents due to each agonist. Detailed study of BDM suppression of kainate-induced current revealed two components. A component with a rapid onset did not involve phosphatase action since 500 microM ATP-gamma-S or a protein kinase inhibitor (H-7, 200 microM) did not alter current suppression or recovery after BDM. Thus, the probable mechanism for this component of BDM's effect is direct block of the kainate-activated ion channel. However, preincubating neurons with 30 mM BDM reduced their subsequent response to kainate alone. This persistent effect of BDM was not seen for neurons dialyzed with a solution containing ATP-gamma-S during conventional whole cell recording. Furthermore, exposure to H-7 prevented recovery of the kainate response suppressed by preincubation in BDM. These findings suggest that BDM causes sustained suppression of the kainate response of hypothalamic neurons via a "chemical phosphatase" action.

Nicardipine and treatment of cerebrovascular diseases with particular reference to hypertension-related disorders

Nicardipine is a second generation dihydropyridine-type Ca2+ antagonist with high vascular selectivity and strong cerebral and coronary vasodilatory activity. The compound is used in the treatment of hypertension, primarily in the elderly. In this review the main evidence of the cerebrovascular activity of nicardipine in preclinical studies using in vitro and in vivo models is detailed. A particular physico-chemical property of nicardipine is the almost complete protonation in acid environment. This allows its accumulation in ischemic brain regions and makes it a candidate for the treatment of cerebrovascular disorders characterised by impaired brain perfusion. The main clinical data on the use of nicardipine in cerebral ischemia and related disorders, subarachnoid haemorrhage and stroke, are also reviewed. These studies included 5940 patients affected by chronic cerebrovascular insufficiency (cerebral ischemia, cerebral atherosclerosis mainly associated with hypertension, transient ischemic attacks, sequelae of cerebral infarction, thrombosis or embolia, hypertensive encephalopathy), 1540 patients affected by sequelae of subarachnoid haemorrhage and 206 patients affected by stroke. Both preclinical studies and clinical trials have shown that nicardipine is a safe Ca2+ antagonist with powerful cerebrovascular activity. This suggests its possible use in cerebrovascular disorders in which blockade of Ca2+ channels of the L-type and/or selective cerebral vasodilatation is desirable. Further studies are necessary to establish if modulation of neuronal Ca2+ channels of the L-type by nicardipine may have a neuroprotective effect independent by the cerebrovascular activity of the compound.

Ion channel involvement in anoxic depolarization induced by cardiac arrest in rat brain

Anoxic depolarization (AD) and failure of ion homeostasis play an important role in ischemia-induced neuronal injury. In the present study, different drugs with known ion-channel-modulating properties were examined for their ability to interfere with cardiac-arrest-elicited AD and with the changes in the extracellular ion activity in rat brain. Our results indicate that only drugs primarily blocking membrane Na+ permeability (NBQX, R56865, and flunarizine) delayed the occurrence of AD, while compounds affecting cellular Ca2+ load (MK-801 and nimodipine) did not influence the latency time. The ischemia-induced [Na+]e reduction was attenuated by R56865. Blockade of the ATP-sensitive K+ channels with glibenclamide reduced the [K+]e increase upon ischemia, indicating an involvement of the KATP channels in ischemia-induced K+ efflux. The KATP channel opener cromakalim did not affect the AD or the [K+]e concentration. The ischemia-induced rapid decline of extracellular calcium was attenuated by receptor-operated Ca2+ channel blockers MK-801 and NBQX, but not by the voltage-operated Ca2+ channel blocker nimodipine, R56865, and flunarizine.

Ca(2+)- and Cl(-)-dependent, NMDA receptor-mediated neuronal death induced by depolarization in rat hippocampal organotypic cultures

The neurotoxicity induced by depolarization with high-K+ was investigated in rat hippocampal organotypic slice cultures. The exposure of cultures to 90 mM K+ solution for 30 min caused a severe neuronal injury in CA1 region while less damage was observed in CA3 and dentate gyrus over the following day. This neurotoxicity was prevented in a concentration dependent manner by NMDA antagonist MK-801 or CPP. Non-NMDA antagonist, DNQX, had no protective effect. Omission of Ca2+ from the exposure solution prevented the neurotoxicity. Voltage-dependent Ca2+ channel blockers, nifedipine and flunarizine, failed to prevent the neurotoxicity. These results suggest that the Ca2+ influx through the NMDA receptor is predominantly involved in this neurotoxicity. Apparent tissue swelling was observed immediately after the depolarization. This swelling was completely inhibited by omission of Cl- from the exposure solution, accompanied with complete protection against neurotoxicity. This suggests that Cl(-)-dependent tissue swelling also largely contributes to the neurotoxicity. Depolarization with application of MK-801 (10 microM) or omission of Ca2+ from the solution still caused apparent swelling, despite these treatment protected neuronal death. We hypothesize that Cl(-)-dependent tissue swelling may be involved in the release of the excitatory amino acid, which activates the NMDA receptor.

Spatial changes in calcium signaling during the establishment of neuronal polarity and synaptogenesis

Calcium imaging techniques were used to obtain a clear although indirect evidence about the distribution of functional glutamate receptors of NMDA and non-NMDA type in cultured hippocampal neurons during establishment of polarity and synaptogenesis. Glutamate receptors were expressed and were already functional as early as one day after plating. At this stage NMDA and non-NMDA receptors were distributed in all plasmalemmal areas. During the establishment of neuronal polarity, responses to either types of glutamate receptors became restricted to the soma and dendrites. Compartmentalization of glutamate receptors occurred at stages of development when synaptic vesicles were already fully segregated to the axon. Formation of synapses was accompanied by a further redistribution of receptors, which segregated to synapse-enriched portions of dendrites. Receptor compartmentalization and dendritic redistribution as well as accumulation of synaptic vesicles at synaptic sites occurred also in neurons cultured in the presence of either the sodium channel blocker tetrodotoxin or glutamate receptor antagonists. These results indicate that signals generated by neuronal electrical activity or receptor activation are not involved in the establishment of neuronal polarity and synaptogenesis.

Corticosteroid receptor-dependent modulation of calcium currents in rat hippocampal CA1 neurons

Pyramidal CA1 neurons in the rat hippocampus contain mineralocorticoid (MRs) and glucocorticoid receptors (GRs) for corticosterone, which, in activated form, act as transcription factors of the genome. The relative MR and GR occupation changes throughout the day, with predominant MR occupation under rest in the morning and additional GR occupation in the evening and after stress. We examined the effect of MR and GR activation on Ca currents in hippocampal slices from adrenalectomized (ADX) rats under whole-cell voltage-clamp conditions. In slices from ADX rats, where MRs and GRs are unoccupied, Ca currents (particularly in the low-voltage range) were larger than in neurons from the sham-operated controls; these effects became apparent with a delay of > or = 3 days after ADX. Selective occupation of MRs in tissue from ADX rats greatly (by 70%) and persistently (up to 3 h) reduced transient but also sustained Ca conductances. Voltage dependency and kinetic properties of the currents were not affected. Occupation of GRs as well as MRs by corticosterone (30 nM) resulted in relatively large Ca currents, comparable to those recorded in tissue from mildly stressed sham-operated control animals. Interestingly, exclusive occupation of GRs with 30 nM RU 28362 was not sufficient to induce large Ca currents. The data suggest that the changes in MR and GR occupation throughout the day, related to circadian and stress-induced corticosterone release, are linked to marked alterations in Ca currents, with small Ca currents in the morning and large currents in the evening or after stress.(ABSTRACT TRUNCATED AT 250 WORDS)

Cardiac T-type calcium current: pharmacology and roles in cardiac tissues

A low threshold, voltage-gated calcium current is reported in most cardiac tissues but rarely in ventricular cells. This article reports some recently described characteristics and discusses their possible pathophysiologic implications. It also reviews the alterations induced in this current by a variety of chemical agents including several neuromediators in cardiac and other tissues.

Dihydropyridine-sensitive calcium channels and barbiturate tolerance and withdrawal

We have shown previously that the dihydropyridine calcium channel antagonist nitrendipine, given chronically, prevents the development of ethanol tolerance and physical dependence. The present study examines the effects on barbiturate tolerance and physical dependence. Nitrendipine, given acutely during withdrawal, provided little protection against barbiturate withdrawal, as measured by convulsive behaviour on handling. When nitrendipine was given chronically concurrently with the barbiturate, a prolonged protection against the withdrawal syndrome was seen. Acute nitrendipine significantly increased the latency of seizures in response to the partial benzodiazepine inverse agonist FG7142 during barbiturate withdrawal, but there was no effect on the seizure incidence in response to bicuculline. Chronic treatment with nitrendipine did not alter the development of tolerance to the ataxic or general anaesthetic actions of barbiturates, but evidence was found of a possible interaction between nitrendipine and pentobarbitone, which may have been pharmacokinetic. The results suggest that neuronal calcium channels may be involved to some degree in the development of the changes responsible for barbiturate withdrawal, but to a less extent than found previously for ethanol dependence.

A whole cell patch-clamp study on the pacemaker potential in dopaminergic neurons of rat substantia nigra compacta

A whole-cell patch-clamp recording was obtained from dopamine (DA) neurons (n = 68) in the substantia nigra compacta (SNc) in in vitro slice preparations in order to study the underlying current for pacemaker-like slow depolarization (PLSD) which was considered as a basis for rhythmic firing of DA neurons. SNc DA neurons were identified immunohistochemically after recording. Results demonstrated that: (1) Under current clamped condition in the presence of TTX, DA neurons (n = 5) displayed the oscillation of membrane potential with high threshold spikes. An application of a hyperpolarizing and depolarizing current pulse (at the membrane potential where oscillation was no longer seen) induced a prominent anomalous rectification and pacemaker-like slow depolarization (PLSD), respectively. (2) Under voltage-clamped conditions in the presence of TTX, a command pulse positive to -50 mV from a holding potential of -80 mV induced a persistent Ca2+ current which was usually preceded by either a transient K+ (n = 7) or a transient Ca2+ (n = 4) current recorded with a patch pipette containing potassium gluconate (145 mM). (3) When outward currents were suppressed by 140 mM CsCl and 10 mM EGTA intercellularly applied through the patch pipette, a command pulse positive to -50 to -40 mV induced either a persistent Ca2+ current alone (n = 4) or a persistent Ca2+ current preceded by a transient Ca2+ current (n = 11). (4) The threshold for activation of the persistent Ca2+ current (Ip) was around -60 to -55 mV. The amplitude of Ip produced by a command pulse stepped to -50 mV from a holding potential of -80 mV was -78 +/- 42 pA (n = 23). (5) The threshold for activation of transient Ca2+ current (IT) was around -70 to -65 mV and inactivated completely at -70 to -65 mV (n = 11). The peak amplitude of IT evoked at -60 to -55 mV from a holding potential of more negative than -80 mV was 489 +/- 170 pA (n = 11). (6) The decay time constant of IT was 28 +/- 12 ms at -60 mV (n = 8) and that of IP was 2.35 +/- 1.37 s at -50 mV (n = 11) when recorded with a pipette containing 10 mM EGTA and 140 mM CsCl. (7) The decay of IP was apparently accelerated by decreasing the concentration of EGTA in the pipette solution from 10 to 1 mM.(ABSTRACT TRUNCATED AT 400 WORDS)

[Role of voltage-dependent ion channels in epileptogenesis]

The aim of this review is to gather information in favour of the involvement of voltage-dependent ion channels in epileptogenesis. Although, up to now, no study has shown that epilepsy is accompanied by a modification in the activity to these channels, the recently acquired knowledge of their physiology allows to presume would favor their involvement in epileptogenesis. The results from electrophysiological studies are as follows: a persistent sodium current increases neuronal excitability whereas potassium currents have an inhibitory role. In particular, calcium-dependent potassium current are involved in the post-hyperpolarization phases which follows PDS. Calcium currents are also involved in the genesis of the "bursting pacemaker" activity displayed by the neurons presumed to be inducers of the epileptic activity. Biochemical data has shown that as a consequence of epileptic activity, sodium and calcium channels are down regulated. This down-regulation could be a way to reduces neuronal hyperexcitability. Pharmacological data demonstrate the drugs which activate calcium channels or which inhibit potassium channels have a convusilvant effect. On the contrary, agents which block calcium or sodium channels or which properties. Among the latter ones, some antiepileptic drugs can be found. In summary situations which lead to increase in calcium and sodium currents and/or to an inhibition in potassium currents are potentially epileptogenic.

Effect of KB-2796, a new diphenylpiperazine Ca2+ antagonist, on voltage-dependent Ca2+ currents and oxidative metabolism in dissociated mammalian CNS neurons

The effects of KB-2796, 1-[bis(4-fluorophenyl)methyl]-4-(2,3,4- trimethoxybenzyl)piperazine-2HCl, on the low- and high-voltage activated Ca2+ currents (LVA and HVA ICa, respectively) and on oxidative metabolism were studied in neurons freshly dissociated from rat brain. KB-2796 reduced the peak amplitude of LVA ICa in a concentration-dependent manner with a threshold concentration of 10(-7) M when the LVA ICa was elicited every 30 s in the external solution with 10 mM Ca2+. The concentration for half-maximum inhibition (IC50) was 1.9 x 10(-6) M. At 10(-5) M or more of KB-2796, a complete suppression of the LVA ICa was observed in the majority of neurons tested. There was no apparent effect on the current-voltage (I-V) relationship and the current kinetics. KB-2796 delayed the reactivation and enhanced the inactivation of the Ca2+ channel for LVA ICa voltage- and time-dependently, suggesting that KB-2796 preferentially binds to the inactivated Ca2+ channel. KB-2796 at a concentration of 3.0 x 10(-6) M also decreased the peak amplitude of the HVA ICa without shifting the I-V relationship. In addition, KB-2796 reduced the oxidative metabolism (the formation of reactive oxygen species) of the neuron in a concentration-dependent manner with a threshold concentration of 3 x 10(-6) M. It is suggested that the inhibitory action of KB-2796 on the neuronal Ca2+ influx and the oxidative metabolism, in combination with a cerebral vasodilatory action, may reduce ischemic brain damage.

Effects of flunarizine and diltiazem on physical dependence on barbital in rats

The effects of flunarizine and diltiazem both on development of physical dependence on barbital and on barbital withdrawal signs in rats were examined using the drug-admixed food (DAF) method. Rats were chronically treated with barbital or barbital in combination with flunarizine (fixed at 1.5 mg/g of food) or diltiazem (fixed at 0.75 mg/g of food)-admixed food on the schedule of gradually increasing doses of barbital. Motor incoordination during the treatment was potentiated by coadministration of flunarizine, but not by coadministration of diltiazem. After the termination of drug treatment, the body weight loss and withdrawal scores were significantly suppressed in the group coadministered flunarizine, but not in that coadministered diltiazem. There were no significant differences in plasma barbital levels after the withdrawal between groups. In the substitution test, flunarizine (20 and 40 mg/kg, IP) significantly suppressed the body weight loss and withdrawal scores after the withdrawal, but diltiazem (20 mg/kg, IP) did not. These results indicated that flunarizine suppressed both the development of physical dependence on barbital and barbital withdrawal signs, mainly according to the suppression of convulsions, but not diltiazem, which is known to poorly penetrate into the brain. Therefore, the present findings suggest that central calcium channels may be involved in both the development of physical dependence on barbital and the appearance of barbital withdrawal signs.

Muscle contracture and twitch depression induced by arsenite in the mouse phrenic nerve-diaphragm

The purpose of this investigation was to explore the possible mechanism of muscle contracture and twitch depression induced by arsenite in the mouse diaphragm. Arsenite-contracture was dependent on extracellular Ca2+; both EGTA and Ca(2+)-channel blockers (nifedipine and verapamil) inhibited arsenite-contracture. However, the activators caffeine and ryanodine and the inhibitor ruthenium red of the Ca2+ releasing channel of sarcoplasmic reticulum (SR) all exerted a profound inhibitory action on arsenite-contracture. Neither the Ca(2+)-release nor the Ca(2+)-ATPase activity of SR. were affected by 50 microM arsenite. These findings indicate a possibility that arsenite induced muscle contracture by enhancing Ca(2+)-entry which further induced Ca(2+)-release from SR. Moreover, the possible mechanism of twitch blockade induced by arsenite was studied by an electrophysiological technique. The frequency of miniature endplate potential (m.e.p.p.) was initially increased but eventually abolished by arsenite, while the amplitude of m.e.p.p. remained unaffected and that of endplate potential rapidly declined. It is considered that arsenite increased the spontaneous release of transmitter by enhancing Ca2+ entry into the nerve terminal and inhibited the evoked transmitter release possibly by acting at a certain site which governs transmitter release.

Inhibitory effects of calcium channel antagonists on motor dysfunction induced by intracerebroventricular administration of paraquat

This study reports the effects of Ca2+ channel blockers (Ca antagonists) on intraneuronal Ca2+ ([Ca2+]i) movements and on the disturbance of rotarod performance produced in rats by intracerebroventricular administration of paraquat. Paraquat (50 nmol) produced a decrement in rotarod performance which was present at 30 min. and maximal at 60 min. and was not associated with overt behavioural changes; larger doses of paraquat (100-400 nmol intracerebroventricularly) produced paresis and convulsions which severely disrupted rotarod behaviour. The disruption of rotarod performance after paraquat (50 nmol intracerebroventricularly) was significantly reduced by giving Ca antagonists (flunarizine, verapamil and nicardipine) not only intraperitoneally 15 min. after paraquat but also intracerebroventricularly immediately before paraquat. The order of pharmacological potency was flunarizine > or = verapamil > nicardipine. In contrast, intracerebroventricular administration of Bay K 8644, a Ca agonist, enhanced the disruption of rotarod performance caused by paraquat (50 nmol). In in vitro studies, paraquat markedly potentiated the rapid increase in [Ca2+]i levels evoked by 50 mM KCl in rat brain synaptosomal fraction, although paraquat alone produced a small prolonged rise in [Ca2+]i levels which had a slow onset. The above results suggest that paraquat induced neurotoxicity is associated with increased [Ca2+]i levels in brain neuronal cells, and that paraquat might effect on membrane activity instability.