Antagonists‐resistant calcium currents in rat embryo motoneurons

Ca²⁺ channels diversity of cultured rat embryo motoneurons was investigated with whole-cell current recordings. In 5–20 mm Ba²⁺, the whole-cell currents were separated in low- (LVA) and high-voltage-activated (HVA) current. The LVA current was evident since the first day in culture, while the HVA component was small and increased with time. Recordings after 4 days revealed ≈ 20% L-, ≈ 45% N- and ≈ 35% P- and R-type currents. P-type currents were revealed only in 40% of motoneurons, in which 20–200 nm ω-Aga-IVA caused 20% irreversible block of total current. The remaining 60% of cells were insensitive even to higher doses of the toxin (500 nm in 5 mm Ba²⁺), suggesting weak expression and heterogeneous distribution of P-type channels compensated by high densities of HVA Ca²⁺ channels resistant to all the antagonists (R-type). A significant residual current could also be resolved after prolonged applications of 5 μm ω-CTx-MVIIC, which allowed separation of N- and P-type currents by the distinct onset of toxin block. The antagonists-resistant current reveals biophysical characteristics typical of HVA channels, but distinct from the α_1E channel. The current activates around ?20 mV in 20 mm Ba²⁺; inactivates slowly and independently of Ca²⁺; is blocked by low [Cd²⁺] and high [Ni²⁺]; and is larger with Ba²⁺ than Ca²⁺. The uncovered R-type calcium current can account for part of the presynaptic Ca²⁺ current controlling neurotransmitter release at the mammalian neuromuscular junction whose activity is resistant to DHP- and ω-CTx-GVIA, and displays anomalous sensitivity to ω-Aga-IVA and ω-CTx-MVIIC ( 1 ) J. Physiol. (Lond.), 482, 283–290; 2 ) Eur. J. Neurosci., 9, 817–823].     

Differential expression of voltage-activated calcium channels in III and XII motoneurones during development in the rat

To further our understanding of the role that voltage-activated Ca2+ channels play in the development, physiology and pathophysiology of motoneurones (MNs), we used whole-cell patch-clamp recording to compare voltage-activated Ca2+ currents in oculomotor (III) and hypoglossal (XII) MNs of neonatal [postnatal day (P)1-5] and juvenile (P14-19) rats. In contrast to III MNs that innervate extraocular muscles, XII MNs that innervate tongue muscles mature more rapidly, fire bursts of low frequency action potentials and are vulnerable to degeneration in amyotrophic lateral sclerosis. In neonates, low voltage-activated (LVA) Ca2+ current densities are similar in XII and III MNs but high voltage-activated (HVA) Ca2+ current densities are twofold higher in XII MNs. The HVA Ca2+ channel antagonists (nimodipine and nifedipine for L-type, omega-agatoxin-TK for P/Q-type and omega-conotoxin-GVIA for N-type) revealed that, while N- and P/Q-type HVA Ca2+ channels are present in both MN pools, a 3.5-fold greater P/Q-type Ca2+ current in XII MNs accounts for their greater HVA Ca2+ currents. Developmentally, LVA and HVA Ca2+ current densities decrease in III MNs but remain unchanged in XII MNs. Thus, the differences between these MN pools increase developmentally so that, in juveniles, the LVA Ca2+ current density is twofold greater and the HVA Ca2+ current density is threefold greater in XII compared with III MNs. We propose that this differential expression of LVA and HVA Ca2+ channels in XII and III MNs during development contributes to their distinct physiology and may also be a factor contributing to the greater susceptibility of XII MNs to degeneration as seen in amyotrophic lateral sclerosis.     

Dopamine inhibits voltage-activated calcium channel currents in rat pars intermedia pituitary cells

Several lines of evidence suggest that dopamine acts as a neurotransmitter that inhibits both hormone secretion and electrical activity in pituitary intermediate cells (melanotrophs). In this study we examined the effects of exogenously applied dopamine on voltage activated calcium currents recorded with the whole-cell mode of the patch-clamp technique from short-term primary cultures of melanotrophs. Two types of calcium currents were distinguished by their voltage dependence and kinetics of inactivation similar to the low voltage-activated currents (LVA; or T-type) and high voltage-activated currents (HVA; N&L-types) of calcium currents. Exogenously applied dopamine (2-20 microM) reversibly reduced both LVA and HVA types of calcium currents. Evidence for these results came from experiments in which LVA and HVA calcium currents were separated by stepping to different membrane potentials from a fixed holding potential (Vh) or by changing Vh. These results suggest that dopamine can regulate the entry of calcium into melanotrophs by acting on at least two different populations of calcium channels thereby affecting hormone secretion and electrical activity.     

Differential expression of voltage-activated calcium currents in zebrafish retinal ganglion cells

We report a study on the characterization of voltage-activated calcium currents (I(Ca)) in retinal ganglion cells (RGCs) and the topographic distribution of RGCs that express different types of I(Ca) in zebrafish retinas. In acutely isolated zebrafish RGCs, both high-voltage-activated (HVA; peak activation potential +7.4 +/- 1.1 mV) and low-voltage-activated (LVA; peak activation potential -33.0 +/- 1.2 mV) I(Ca) were recorded. HVA I(Ca) were recorded in all of the tested RGCs, whereas LVA I(Ca) were recorded in approximately one-third of the tested cells. In RGCs that expressed both HVA and LVA I(Ca), the two currents were readily separated by depolarizing the cell membrane to different voltages from different holding potentials. Among RGCs that expressed LVA I(Ca), some cells expressed large LVA I(Ca) (up to 130 pA), whereas others expressed small LVA I(Ca) (approximately 20 pA). RGCs that expressed large and small LVA I(Ca) were designated as class I and class II cells, respectively, and RGCs that expressed only HVA I(Ca) were designated as class III cells. The topographic distribution of cell classes was similar in various areas of the retina. In the nasal-ventral retina, for example, class III cells outnumbered class I and class II cells by 10.8- and 2.6-fold, respectively. In the temporal and dorsal retinas, the density of class III cells slightly decreased, whereas the density of class I and class II cells increased. The differential expression of I(Ca) in RGCs may correlate with the development and function of the retina.     

Pharmacological characterization of calcium currents and synaptic transmission between thalamic neurons in vitro.

We recorded from pairs of cultured, synaptically connected thalamic neurons. Evoked excitatory postsynaptic currents (EPSCs) reversed at +17 mV and were blocked reversibly by 1 mM kynurenic acid, a glutamate receptor antagonist. NMDA and non-NMDA receptors mediated excitatory post-synaptic responses, as shown by selective block of EPSC components with 50 microM (+/-)-2-amino-5-phosphonopentanoic acid and 10 microM 6,7-dinitroquinoxaline-2,3-dione, respectively. Inhibitory postsynaptic responses were evoked less frequently and were blocked by the GABAA receptor antagonist (-)-bicuculline methochloride. The pharmacological profiles of whole-cell calcium currents and evoked EPSCs were compared. With 50 microM cadmium chloride (Cd), whole-cell low voltage-activated (LVA) calcium currents were reduced in amplitude and high voltage-activated (HVA) calcium currents and excitatory synaptic transmission were completely blocked. This suggests that the residual calcium influx through LVA channels into the presynaptic terminal does not suffice to trigger transmitter release. A saturating concentration of omega-conotoxin GVIA (omega-CgTx) (2.5 microM) blocked one-third of whole-cell HVA calcium currents and evoked EPSCs. The dihydropyridine nifedipine (50 microM) reversibly reduced whole-cell HVA calcium currents in a voltage-dependent manner but not excitatory synaptic transmission. Cd and omega-CgTx did not alter amplitude distributions of miniature EPSCs, demonstrating that the inhibition of synaptic transmission was due to block of presynaptic calcium channels. We conclude that excitatory glutamatergic transmission in thalamic neurons in vitro was mediated mainly by HVA calcium currents, which were insensitive to omega-CgTx and nifedipine.     

Calcium currents in acutely isolated stellate and pyramidal neurons of rat entorhinal cortex

Calcium currents were studied in morphologically identified pyramidal and stellate neurons acutely isolated from layer II/III of rat entorhinal cortex, using the whole-cell patch-clamp configuration. The peak amplitude of high-voltage activated current (HVA) measured at +10 mV was not different in both neuron populations with 0.94±0.08 nA for pyramidal and 1.03±0.08 nA for stellate cells. Stellate neurons had a larger capacitance (14.4±1.1 pF) than pyramidal neurons (9.6±0.8 pF), indicating a 50% larger cell surface. Most striking was the difference between the current density in stellate (79±8 pA/pF) versus pyramidal neurons (113±13 pA/pF). The potential of half maximal inactivation was not different: −37±2 mV (pyramidals) and −37±3 mV (stellates). Half of the cells contained a low-voltage activated calcium current (LVA) with a peak amplitude that was twice as large in stellate as in pyramidal neurons (0.21±0.04 nA resp. 0.11±0.03 nA; at −50 mV). In contrast to the HVA component, the current density of the LVA component was not different between cell types (13±3 pA/pF vs. 13±2 pA/pF). This implies that the relative abundance of LVA and HVA currents in stellate and pyramidal neurons is different which could result in different firing characteristics. The potential of half maximal LVA inactivation was −88±4 mV (pyramidals) and −85±3 mV (stellates). The slope of the voltage dependent steady state inactivation was steeper in stellate (7±1 mV) than in pyramidal cells (10±2 mV).     

Postnatal development of GABAB receptor-mediated modulation of voltage-activated Ca2+ currents in mouse brain-stem neurons.

GABA_B receptors modulate respiratory rhythm generation in adult mammals. However, little is currently known of their functional significance during postnatal development. In the present investigation, the effects of GABA_B receptor activation on voltage-activated Ca²⁺ currents were examined in rhythmically active neurons of the pre-Bötzinger complex (PBC). Both low- (LVA) and high-voltage-activated (HVA) Ca²⁺ currents were present from the first postnatal day (P1). The density of LVA Ca²⁺ currents increased during the first week, whilst the density of HVA Ca²⁺ currents increased after the first week. In the second postnatal week, the HVA Ca²⁺ currents were composed of L- (47 ± 10%) and N-type (21 ± 8%) currents plus a ‘residual’ current, whilst there were no N-type currents detectable in the first few days. The GABA_B receptor agonist baclofen (30 μm ) increased LVA Ca²⁺ currents (30 ± 11%) at P1–P3, but it decreased the currents (35 ± 11%) at P7–P15 without changing its time course. At all ages, baclofen (30 μm ) decreased the HVA Ca²⁺ currents by ≈ 54%. Threshold of baclofen effects on both LVA and HVA Ca²⁺ currents was 5 μm at P1–P3 and lower than 1 μm at P7–P15. The effect of baclofen was abolished in the presence of the GABA_B receptor antagonist CGP 55845A (50 n m ). We conclude that both LVA and HVA Ca²⁺ currents increased postnatally. The GABA_B receptor-mediated modulation of these currents undergo marked developmental changes during the first two postnatal weeks, which may contribute essentially to modulation of respiratory rhythm generation.     

Distribution of L‐type calcium channels in rat thalamic neurones

One major pathway for calcium entry into neurones is through voltage-activated calcium channels. The distribution of calcium channels over the membrane surface is important for their contribution to neuronal function. Electrophysiological recordings from thalamic cells in situ and after acute isolation demonstrated the presence of high-voltage activated calcium currents. The use of specific L-type calcium channel agonists and antagonists of the dihydropyridine type revealed an about 40% contribution of L-type channels to the total high-voltage-activated calcium current. In order to localize L-type calcium channels in thalamic neurones, fluorescent dihydropyridines were used. They were combined with the fluorescent dye RH414, which allowed the use of a ratio technique and thereby the determination of channel density. The distribution of L-type channels was analysed in the three main thalamic cell types: thalamocortical relay cells, local interneurones and reticular thalamic neurones. While channel density was highest in the soma and decreased significantly in the dendritic region, channels appeared to be clustered differentially in the three types of cells. In thalamocortical cells, L-type channels were clustered in high density around the base of dendrites, while they were more evenly distributed on the soma of interneurones. Reticular thalamic neurones exhibited high density of L-type channels in more central somatic regions. The differential localization of L-type calcium channels found in this study implies their predominate involvement in the regulation of somatic and proximal dendritic calcium-dependent processes, which may be of importance for specific thalamic functions, such as those mediating the transition from rhythmic burst activity during sleep to single spike activity during wakefulness or regulating the relay of visual information.     

Differential down-regulation of voltage-gated calcium channel currents by glutamate and BDNF in embryonic cortical neurons

In the embryonic brain, post-mitotic cortical neurons migrate from their place of origin to their final location. Various external factors such as hormones, neurotransmitters or peptides regulate their migration. To date, however, only a few studies have investigated the effects of these external factors on the electrical properties of the newly formed embryonic cortical neurons. The aim of the present study was to determine whether glutamate and brain-derived neurotrophic factor (BDNF), known to regulate neuronal cell migration, could modulate currents through voltage-gated calcium channels (ICa) in cortical neurons isolated from embryonic day 13 (E13) mouse foetuses. Whole cell recordings of ICa showed that E13 cortical cells kept 1 day in vitro expressed functional low- and high-voltage activated (LVA and HVA) Ca2+ channels of T-, L- and N-types. A 1-day glutamate treatment non-specifically inhibited LVA and HVA ICa whereas BDNF down-regulated HVA with N-type ICa being more depressed than L-type ICa. The glutamate-induced ICa inhibition was mimicked by NMDA. BDNF exerted its action by recruiting trkB receptors and SKF-96365-sensitive channels. BAPTA prevented the glutamate- and the BDNF-dependent inhibition of Ica, indicating a Ca2+-dependent mechanism of action. It is proposed that an influx of Ca2+ through NMDA receptors depresses the expression of LVA and HVA Ca2+ channels whereas a Ca2+ influx through SKF-96365-sensitive TRPC (transient receptor potential protein of C subtype) channels preferentially inhibits the expression of HVA Ca2+ channels. Glutamate and BDNF appear as potent modulators of the electrical properties of early post-mitotic neurons. By down-regulating ICa they could exert a neuroprotective action on embryonic cortical neurons.     

Possible modulatory role of voltage-activated Ca(2+) currents determining the membrane properties of isolated pyramidal neurones of the rat dorsal cochlear nucleus.

Voltage-activated Ca(2+) currents have been studied in pyramidal cells isolated enzymatically from the dorsal cochlear nuclei of 6-11-day-old Wistar rats, using whole-cell voltage-clamp. From hyperpolarized membrane potentials, the neurones exhibited a T-type Ca(2+) current on depolarizations positive to -90 mV (the maximum occurred at about -40 mV). The magnitude of the T-current varied considerably from cell to cell (-56 to -852 pA) while its steady-state inactivation was consistent (E(50)=-88.2+/-1.7 mV, s=-6. 0+/-0.4 mV). The maximum of high-voltage activated (HVA) Ca(2+) currents was observed at about -15 mV. At a membrane potential of -10 mV the L-type Ca(2+) channel blocker nifedipine (10 microM) inhibited approximately 60% of the HVA current, the N-type channel inhibitor omega-Conotoxin GVIA (2 microM) reduced the current by 25% while the P/Q-type channel blocker omega-Agatoxin IVA (200 nM) blocked a further 10%. The presence of the N- and P/Q-type Ca(2+) channels was confirmed by immunochemical methods. The metabotropic glutamate receptor agonist (+/-)-1-aminocyclopentane-trans-1, 3-dicarboxylic acid (200 microM) depressed the HVA current in every cell studied (a block of approximately 7% on an average). The GABA(B) receptor agonist baclofen (100 microM) reversibly inhibited 25% of the HVA current. Simultaneous application of omega-Conotoxin GVIA and baclofen suggested that this inhibition could be attributed to the nearly complete blockade of the N-type channels. Possible physiological functions of the voltage-activated Ca(2+) currents reported in this work are discussed.     

Voltage-dependent calcium channels in ventromedial hypothalamic neurones of postnatal rats: modulation by oestradiol and phenylephrine

Oestradiol actions in the hypothalamus play an important role in reproductive behaviour. Oestradiol treatment in vivo induces α_1b-adrenoceptor mRNA and increases the density of α_1B-adrenoceptor binding in the hypothalamus. Oestradiol is also known to modulate neuronal excitability, in some cases by modulating calcium channels. We assessed the effects of phenylephrine, an α₁-adrenergic agonist, on low-voltage-activated (LVA) and high-voltage-activated (HVA) calcium channels in ventromedial hypothalamic (VMN) neurones from vehicle- and oestradiol-treated female rats. Whole-cell and gramicidin perforated-patch recordings were obtained, with barium as the charge carrier. In the absence of phenylephrine, oestradiol treatment increased the magnitude of LVA currents compared to controls, but had no effect on HVA currents. Phenylephrine enhanced HVA currents in a significantly greater proportion of neurones from oestradiol-treated rats (76%) than from vehicle-treated (41%) rats. The L-channel blocker nifedipine abolished this oestradiol effect on phenylephrine-enhanced HVA currents. Preincubating slices with the N-type channel blocker omega-conotoxin GVIA completely blocked the phenylephrine response, suggesting that the N-type channel is essential. Phenylephrine also stimulated LVA currents in approximately two-thirds of neurones in slices from both vehicle- and oestradiol-treated rats. Our data show that oestradiol increases LVA currents in the VMN. Oestradiol also amplifies α₁-adrenergic signalling by increasing the proportion of neurones showing phenylephrine-stimulated HVA currents mediated by N- and L-type calcium channels. In this way, oestradiol may increase excitatory responses to arousing adrenergic inputs to VMN neurones governing oestradiol-dependent reproductive behaviour.     

Development of inward currents in chick sensory and autonomic neuronal precursor cells in culture

The development of ionic inward currents was studied in cultured neuronal precursors from chick sensory dorsal root ganglia (DRG) and compared with neuronal precursors from the cholinergic ciliary ganglia (CG) using whole cell patch-clamp recording. Neuronal precursors devoid of neuron-specific surface markers were isolated during the period of neuronal birth, i.e., at embryonic day (E) 6 from DRG and at E4.5 from CG. All neuronal precursor cells from DRG, as well as CG, showed outward K+ currents directly after they had attached to the substrate. During the first 5 hr in culture, half of the DRG cells had no inward currents at all, whereas the other half displayed a rapidly and fully inactivating Ca2+ current, which was activated with small depolarizing pulses from a holding potential of -80 mV to a -50 mV membrane potential (low-voltage-activated current, LVA). At these early stages, no other inward currents were resolved. TTX-blockable Na+ currents and slowly inactivating classical Ca2+ currents, which were activated with larger depolarizing pulses to a -20 mV membrane potential (high-voltage-activated currents, HVA) appeared concurrently after 15-20 hr in culture. In contrast, more than half of the CG cells showed LVA currents, as well as Na+ currents, as early as during the first 5 hr in culture. The HVA Ca2+ currents from the majority of the cells could be recorded only after 10-15 hr in culture. In both types of precursor-derived neurons, the LVA Ca2+ current preceded the classical HVA Ca2+ current. However, the temporal relation of the first Na+ currents to the first HVA Ca2+ currents seemed to be different in the 2 preparations. In DRG cells, Na+ and HVA Ca2+ currents appeared at the same time, whereas in CG cells, the HVA Ca2+ current showed a time lag with respect to the Na+ current. In addition, the relative amplitudes of the currents differed in the CG and DRG cells. This shows that as early as E4-6, shortly after their terminal mitosis, neurons from distinct peripheral ganglia in chick vary in the development of their basic ionic currents.     

Serotonin enhances a low-voltage-activated calcium current in rat spinal motoneurons

Calcium currents and the effects of 5-HT on these currents were investigated in visually identified motoneurons using whole-cell recording in the neonatal rat spinal cord slice preparation. In current-clamp recording, step depolarizations from a holding potential of about -90 mV produced a low-threshold transient depolarizing response and a high-threshold long-lasting spike. In voltage-clamp recording, low (LVA) and high (HVA) voltage-activated Ca2+ currents were recorded in response to depolarizing voltage steps. Low concentration of Cd2+ (50 microM) did not reduce the amplitude of the LVA current but markedly diminished the HVA current. Bath application of 5-HT (10-50 microM) markedly increased the amplitude of the LVA current without causing a shift in the current (I)-voltage (V) relation. In contrast, 5-HT did not appreciably affect the amplitude of the HVA current. We conclude that 5-HT specifically enhances the LVA Ca2+ current and that this effect together with the previously reported 5-HT-induced inward current (Takahashi and Berger, 1990), would facilitate the excitation of motoneurons.     

Embryonic rat motoneurons express a functional P-type voltage-dependent calcium channel

Only L- and N-type high voltage-activated calcium currents (HVA I_Ca) have been demonstrated in identified embryonic spinal motoneurons. However, pharmacological experiments suggest that other HVA I_Ca, including P-type, govern neurotransmitter release at the adult neuromuscular junction. We sought to analyse if embryonic motoneurons express these other I_Ca, using the whole-cell voltage-clamp method on motoneurons purified by a new metrizamide-panning technique from E15 rat embryos. In addition to L-type dihydropyridine-sensitive and N-type ω-GVIA-sensitive currents, motoneurons express two other HVA I_Ca. One has properties related to the P-type channel currents described in Purkinje cells: it is inhibited by the peptide ω-agatoxin-IVA with a maximal effect at 100–200 nM. The inhibited current has a characteristic sustained component during depolarizing test pulses. Furthermore, 50–100 nM concentration of ω-agatoxin-IVA reduce the increase in cytoplasmic calcium concentration observed after depolarization. The other HVA I_Ca is resistant to saturating concentrations of verapamil, ω-conotoxin GVIA and ω-agatoxin-IVA which block L, N and P-type HVAI_Ca, respectively. These results suggest that it is now possible to dissect, using a simple method of purification, the properties of the I_Ca in embryonic mammalian motoneurons and to provide pharmacological evidence for multiple calcium channels which may be involved in regulation of their activity during development.     

The Secretion of α40-MSH from Xenopus Melanotropes Involves Calcium Influx through ω-Conotoxin-Sensitive Voltage-Operated Calcium Channels

The secretory activity of endocrine cells largely depends on the concentration of free cytosolic calcium. We have studied the mechanisms that are involved in supplying the calcium necessary for the secretion of α-melanophore-stimulating hormone (α-MSH) from melanotrope cells in the pituitary intermediate lobe of the amphibian Xenopus laevis. Using whole-cell voltage clamp, high-voltage activated calcium currents were observed, with a peak current between 0 and +20 mV. Two types of Ca^{2 +}-currents appeared, depending on the experimental setup. An inactivating current, which was observed after a 10 msec depolarizing prepulse, resembled currents through N-type channels as it was clearly inhibited by 1 μM ω-conotoxin. The second type was a non-inactivating current, which was blocked up to 50% by 1 μM nifedipine, indicating its L-type nature. Only a small component of this inactivating current could be blocked by ω-conotoxin. No evidence was found for the presence of transient, low-voltage activated currents. The spontaneous secretion of α-MSH from superfused neurointermediate lobes was dependent on extracellular calcium, as low calcium conditions (10^?4-10^?8 M) rapidly inhibited this process. Under these conditions, secretion was not affected by depolarizing concentrations of potassium chloride. The calcium ionophore A23187 increased secretion under low calcium conditions, but had no effect on spontaneous α-MSH release. Treatment with CoCI₂, a blocker of calcium channels, strongly inhibited the secretory process. These results suggest that spontaneous α-MSH release depends on influx of calcium through voltage-operated calcium channels. Nifedipine did not affect spontaneous secretion from lobes, nor did it affect potassium-induced α-MSH secretion from dispersed melanotropes. Also BAY-K8644, a specific agonist of L-type channels, did not influence α-MSH release, neither under normal nor under low calcium conditions. On the other hand, ω-conotoxin dose-dependently inhibited α-MSH release, to a maximum of 65% at a concentration of 5 μM, and inhibited potassiuminduced secretion by 40%. Thapsigargin, an agent that mobilizes calcium ions from intracellular stores, had no effect on spontaneous α-MSH release under normal or low calcium conditions. From these results it is concluded that the spontaneous release of α-MSH by melanotropes of X. laevis is effectuated by calcium influx through ω-conotoxin-sensitive, voltage-operated N-type calcium channels and that mobilization of calcium from intracellular stores does not play a major role in the regulation of this release.     

Identified glial cells in the early postnatal mouse hippocampus display different types of Ca2+ currents

Based on their typical pattern of membrane currents, four populations of glial cells could be identified in thin brain slices of the postnatal hippocampus. In the present study, we applied the patch-clamp technique to glial cells in the hippocampal CA1 region, which are characterized by a complex pattern of different Na⁺ and K⁻ currents (“complex” cells). These cells were identified as non-neuronal cells, most likely astrocytes, by their glutamine synthetase immunoreactivity. Two types of glial Ca²⁺currents could be identified that differed in their kinetics and pharmacological properties. A low-voltage activated (LVA), fast inactivating component was activated at membrane potentials positive to −60 mV and reached maximum current amplitudes at about −20 mV. This current was sensitive to amiloride and thus displayed properties of neuronal LVA currents. The threshold potential of the second Ca²⁺ current component was at about −40 mV, and peak currents were observed at 0 mV. In contrast to the LVA component, the inactivation of these high-voltage activated (HVA) currents slowed down with increasing depolarizations. This current was sensitive to low concentrations of Cd²⁺ but was not affected by amiloride. A small fraction of the HVA currents was sensitive to nifedipine, and ω-conotoxin GVIA (ω-CgTx) was also found to reduce the glial HVA component. The study provides electrophysiological and pharmacological characterization of different types of Ca²⁺ currents in gray matter glial cells in situ. © 1996 Wiley-Liss, Inc.     

Two types of calcium currents of the mouse bipolar cells recorded in the retinal slice preparation

In the vertebrate retina, the bipolar cell makes reciprocal synapses with amacrine cells at the axon terminal. It has been postulated that amacrine cells may control the transmitter release from bipolar cells by modulating their calcium currents (I_Ca). To clarify this possibility calcium currents were studied in bipolar cells of the mouse retina using a slice preparation. I_Ca was identified by voltage clamp protocols, ionic substitution and pharmacological tools. Depolarization to –30 mV from a holding voltage of –80 mV induced an inward current consisting of an initial transient and a long-lasting sustained component. The transient component was inactivated by holding the membrane at more positive voltages. Addition of 100 μm nifedipine suppressed the sustained component, leaving the transient component almost intact. The sustained component was enhanced when external solution contained 0.1 μm Bay K 8644 or when the external Ca²⁺ was substituted by equimolar Ba²⁺. Omega-conotoxin (10 μm ω-ctxn GVIA) did not alter either component. We concluded that the transient component is a low-voltage activated T-type I_Ca, while the sustained component is a high-voltage activated L-type I_Ca. T-type I_Ca was recorded in all cells tested, while L-type I_Ca was found only in cells that retained axon terminals ramifying in the inner plexiform layer. Thus, it is highly likely that L-type I_Ca is generated at the axon terminal and contributes to the transmitter release from the bipolar cell. The present results confirm that in addition to the T-type I_Ca that had been previously described, bipolar cells of the mammalian retina also contain L-type I_Ca similar to the one that has been reported in bipolar cells of the goldfish. The use of retinal slice preparation allowed us to record this current that was not seen previously in the dissociated mouse bipolar cells.     

The voltage‐dependent conductances of rat neocortical layer I neurons

Whole cell patch-clamp techniques were used to study voltage-dependent sodium (Na⁺), calcium (Ca²⁺), and potassium (K⁺) conductances in acutely isolated neurons from cortical layer I of adult rats. Layer I cells were identified by means of γ-aminobutyric acid (GABA) immunocytochemistry. Positive stainings for the Ca²⁺-binding protein calretinin in a subset of cells, indicated the presence of Cajal–Retzius (C-R) cells. All investigated cells displayed a rather homogeneous profile of voltage-dependent membrane currents. A fast Na⁺ current activated at about −45 mV, was half-maximal steady-state inactivated at −66.6 mV, and recovery from inactivation followed a two-exponential process (τ₁ = 8.4 ms and τ₂ = 858.8 ms). Na⁺ currents declined rapidly with two voltage-dependent time constants, reaching baseline current after some tens of milliseconds. In a subset of cells (< 50%) a constant current level of < 65 pA remained at the end of a 90 ms step. A transient outward current (I_fast) activated ≈–40 mV, declined rapidly with a voltage-insensitive time constant (τ≈ 350 ms) and was relatively insensitive to tetraethylammonium (TEA, 20 mm ). I_fast was separated into two components based on their sensitivity to 4-aminopyridine (4-AP): one was blocked by low concentrations (40 μm ) and a second by high concentrations (6 mm ). After elimination of I_fast by a conditioning prepulse (50 ms to −50 mV), a slow K⁺ current (I_KV) could be studied in isolation. I_KV was only moderately affected by 4-AP (6 mm ), while TEA (20 mm ) blocked most (> 80%) of the current. I_KV activated at about −40 mV, declined monoexponentially in a voltage-dependent manner (τ≈ 850 ms at −30 mV), and revealed an incomplete steady-state inactivation. In addition to I_fast and I_KV, indications of a Ca²⁺-dependent outward current component were found. When Na⁺ currents, I_fast, and I_KV were blocked by tetrodotoxin (TTX, 1 μm ), 4-AP (6 mm ) and TEA (20 mm ) an inward current carried by Ca²⁺ was found. Ca²⁺ currents activated at depolarized potentials at about −30 mV, were completely blocked by 50 μm cadmium (Cd²⁺), were sensitive to verapamil (≈ 40% block by 10 μm ), and were not affected by nickel (50 μm ). During current clamp recordings, isolated layer I neurons displayed fast spiking behaviour with short action potentials (≈ 2 ms, measured at half maximal amplitude) of relative small amplitude (≈ 83 mV, measured from the action potential threshold).     

High-voltage-activated Ca2+ currents show similar patterns of expression in stellate and pyramidal cells from rat entorhinal cortex layer II

High-voltage-activated (HVA) Ca2+ currents were studied in acutely isolated neurons from rat entorhinal cortex (EC) layer II. Stellate and pyramidal cells, the two main neuronal types of this structure, were visually identified based on morphological criteria. HVA currents were recorded by applying the whole-cell, patch-clamp technique, using 5-mM Ba2+ as the charge carrier. In both neuronal types, the amplitude of total HVA Ba2+ currents (IBas) showed a significant tendency to increase with postnatal age in the time window considered [postnatal day 15 (P15) to P28-29]. At P20-P29, when IBa expression reached stable levels, IBa density per unit of membrane area was not different in stellate versus pyramidal cells. The same was also observed when Ca2+, instead of Ba2+, was used as the charge carrier. The pharmacological current subtypes composing total HVA currents were characterized using selective blockers. Again, no significant differences were found between stellate and pyramidal cells with respect to the total-current fractions attributable to specific pharmacological Ca2+ channel subtypes. In both cell types, approximately 52-55% of total IBas was abolished by the L-type channel blocker, nifedipine (10 microM), approximately 23-30% by the N-type channel blocker, omega-conotoxin GVIA (1 microM), approximately 22-24% by the P/Q-type channel blocker, omega-agatoxin IVA (100 nM), and approximately 11-13% remained unblocked (R-type current) after simultaneous application of L-, N-, and P/Q-type channel blockers. The Cav 2.3 (alpha1E) channel blocker, SNX-482 (100 nM), abolished approximately 57-62% of total R-type current. We conclude that HVA Ca2+ currents are expressed according to similar patterns in the somata and proximal dendrites of stellate and pyramidal cells of rat EC layer II.