High-threshold Ca2 Research Articles

A Novel Small Conductance Ca2+-activated K+ Channel Blocker from Oxyuranus scutellatusTaipan Venom: RE-EVALUATION OF TAICATOXIN AS A SELECTIVE Ca2+CHANNEL PROBE

Taicatoxin, isolated from the venom of the Australian taipan snake Oxyuranus scutellatus, has been previously regarded as a specific blocker of high threshold Ca2+ channels in heart. Here we show that taicatoxin (in contrast to a range of other Ca2+ channel blockers) interacts with apamin-sensitive, small conductance, Ca2+-activated potassium channels on both chromaffin cells and in the brain. Taicatoxin displays high affinity recognition of 125I-apamin acceptor-binding sites, present on rat synaptosomal membranes (Ki = 1.45 +/- 0.22 nM) and also specifically blocks affinity-labeling of a 33-kDa 125I-apamin-binding polypeptide on rat brain membranes. Taicatoxin (50 nM) completely blocks apamin-sensitive after-hyperpolarizing slow tail K+ currents generated in rat chromaffin cells (mean block 97 +/- 3%, n = 12) while only partially reducing total voltage-dependent Ca2+ currents (mean block 12 +/- 4%, n = 6). In view of these findings, the use of taicatoxin as a specific ligand for Ca2+ channels should now be reconsidered.

The effects of piracetam and its novel peptide analogue GVS-111 on neuronal voltage-gated calcium and potassium channels

1. 1. With the use of the two-microelectrode voltage-clamp method, three types of voltage-activated ionic currents were examined in isolated neurons of the snail Helix pomatia: high-threshold Ca 2+ current ( I ca ), high-threshold Ca 2+-dependent K + current ( I K( Ca) ) and high-threshold K + current independent of Ca 2+ ( I K( v) ). 2. 2. The effect of bath application of the nootropics piracetam and a novel piracetam peptide analog, ethyl ester of N-phenyl-acetyl-l-prolyl-glycine (GVS-111), on these three types of voltage-activated ionic currents was studied. 3. 3. In more than half of the tested cells, I ca was resistant to both piracetam and GVS-111. In the rest of the cells, I Ca decreased 19±7% with 2 mM of piracetam and 39±14% with 2 μM of GVS-111. 4. 4. I K( V) in almost all cells tested was resistant to piracetam at concentrations up to 2 μM. However, I K( V) in two-thirds of the cells was sensitive to GVS-111, being supressed 49±18% with 1 μM GVS-111. 5. 5. I K( ca) appeared to be the most sensitive current of those studied to both piracetam and GVS-111. Piracetam at 1 mM and GVS-111 at 0.1 μM decreased the amplitude of I K( Ca) in most of the cells examined by 49±19% and 69±24%, respectively. 6. 6. The results suggest that piracetam and GVS-111 suppression of voltage-activated calcium and potassium currents of the neuronal membrane may regulate (both up and down) Ca 2+influx into neurons.

Effects of adrenalectomy on Ca2 currents and Ca2 channel subunit mRNA expression in hippocampal CA1 neurons of young rats

Previously it was found that the amplitude of Ca currents in CA1 hippocampal neurons increases after adrenalectomy (ADX) of young adult rats. Preliminary data suggested that this effect of ADX is age-dependent. In the present study we therefore investigated the effect of ADX on Ca currents in three age groups: rats that were 1, 3, or 6 months old. It appeared that ADX of the youngest age group resulted in a selective enhancement of sustained, high threshold Ca currents. By contrast, ADX of the oldest rats enhanced only the low threshold, transient Ca current amplitude. The age dependency of the ADX-induced effects can be explained by developmental changes in Ca current properties in the adrenally intact rats with which ADX animals were compared. Data from acutely dissociated cells, which lack most of their dendrites, suggest that the ADX-induced changes of Ca current properties are at least partly targeted at currents generated in the distal dendrites. No significant changes were observed with age or after ADX for the mRNA expression of the α1D Ca channel subunit, which forms the ionpore of the sustained high threshold L-type Ca channel. We can therefore presently not exclude that the altered amplitude of Ca current with age and ADX is due to changes in ion channel function rather than in the total number of these channels. Synapse 26:155–164, 1997. © 1997 Wiley-Liss, Inc.

Effects of adrenalectomy on Ca2+ currents and Ca2+ channel subunit mRNA expression in hippocampal CA1 neurons of young rats.

Previously it was found that the amplitude of Ca currents in CA1 hippocampal neurons increases after adrenalectomy (ADX) of young adult rats. Preliminary data suggested that this effect of ADX is age-dependent. In the present study we therefore investigated the effect of ADX on Ca currents in three age groups: rats that were 1, 3, or 6 months old. It appeared that ADX of the youngest age group resulted in a selective enhancement of sustained, high threshold Ca currents. By contrast, ADX of the oldest rats enhanced only the low threshold, transient Ca current amplitude. The age dependency of the ADX-induced effects can be explained by developmental changes in Ca current properties in the adrenally intact rats with which ADX animals were compared. Data from acutely dissociated cells, which lack most of their dendrites, suggest that the ADX-induced changes of Ca current properties are at least partly targeted at currents generated in the distal dendrites. No significant changes were observed with age or after ADX for the mRNA expression of the alpha 1D Ca channel subunit, which forms the ionpore of the sustained high threshold L-type Ca channel. We can therefore presently not exclude that the altered amplitude of Ca current with age and ADX is due to changes in ion channel function rather than in the total number of these channels.

Two parallel signaling pathways couple 5HT1A receptors to N- and L-type calcium channels in C-like rat dorsal root ganglion cells.

The coupling of serotonin receptors to Ca2+ channels was studied in a subpopulation of acutely isolated rat dorsal root ganglion (DRG) cell bodies (type 1 DRG cells), which have membrane properties similar to C-type nociceptive sensory neurons. In these cells, serotonin (5HT) inhibited high-threshold Ca2+ channel current and decreased action potential duration. The inhibitory effects of 5HT and the 5HT1A agonist 8-OH-DPAT were shown to be antagonized by the 5HT1A antagonists spiperone and pindolol, respectively, indicating involvement of a 5HT1A receptor. Several observations suggest that 5HT1A receptors couple to N- and L-type Ca2+ channels by two different signaling pathways in type 1 DRG cells. The inhibition of Ca2+ channel currents produced by 10 microM 5HT occurred in two phases, an initial slowing of current activation rate (kinetic slowing), which was complete within 10 s, and a simultaneous reduction in steady state current amplitude (steady state inhibition), which peaked in approximately 1 min. The kinetic slowing, but not steady state inhibition, was reversed by a positive prepulse to +70 mV (prepulse). Blockade of N-type Ca2+ channels selectively reduced the kinetic slowing and its reversal by prepulses. Chelation of intracellular Ca2+ or blockade of L-type Ca2+ channels selectively reduced the steady state inhibition. Recordings using the cell-attached patch configuration suggest that steady state inhibition required a component that was diffusible in the cytosol, while kinetic slowing occurred via a membrane delimited pathway. The application of 5HT to the cell body outside the patch pipette reduced macroscopic Ca2+ channel currents in 33% of small-diameter DRG cells tested, indicating the participation of a cytosolic diffusible component. Application of 5HT (a membrane impermeant compound) outside the patch pipette produced steady state inhibition only, whereas similar application of membrane permeant 5HT1A agonists, 8-OH-DPAT or 5-methoxy-N,N-dimethyl-tryptamine, produced kinetic slowing and steady state inhibition. Together these data suggest that 5HT1A receptors couple negatively to Ca2+ channels via two pathways: a membrane-delimited pathway that couples to N-channels and actuates voltage-sensitive kinetic slowing and a pathway dependent on a cytosolic diffusible component and free intracellular Ca2+, which couples to L channels and actuates steady state inhibition.

Differential Roles of Apamin- and Charybdotoxin-Sensitive K+Conductances in the Generation of Inferior Olive RhythmicityIn Vivo

The basic electrical rhythmicity of the olivocerebellar system was investigated in vivo using multiple electrode recordings of Purkinje cell (PC) complex spike (CS) activity. CSs demonstrate a 10 Hz rhythmicity, thought to result from the interaction of Ca2+ and Ca2+-dependent K+ conductances present in inferior olivary (IO) neurons. To assess the roles of different K+ channels in generating this rhythmicity, intraolivary microinjections of charybdotoxin (CTX) and apamin were used. Both K+ channel blockers increased average CS spike-firing rates. However, apamin produced a tonic increase in firing with a decrement in the CS rhythmicity. In contrast, after CTX administration, highly rhythmic CS discharges were interleaved with silent periods, suggesting that apamin- and CTX-sensitive K+ channels have distinct rhythmogenic roles in IO neurons. CTX-sensitive channels seem to be functionally coupled to low threshold Ca2+ channels, whereas the apamin-sensitive channels relate to high threshold Ca2+ channels. Blocking intraolivary GABAA receptors increases IO excitability and the spatial distribution of synchronized CS activity while disrupting its rostrocaudal banding pattern (). The present experiments show that K+ channel blockers increase IO excitability without causing widespread synchronization of CS activity. Thus, changes in the IO excitability have relatively little effect in determining the spatial organization of CS synchrony. In contrast, the degree of CS rhythmicity seemed to influence the patterns of CS synchrony. Thus, after CTX, increased CS rhythmicity was associated with increased intraband synchrony and decreased interband synchrony, whereas apamin had the opposite effects on intra- and interband synchronization.

Modeling neural mechanisms for genesis of respiratory rhythm and pattern. I. Models of respiratory neurons.

The general objectives of our research, presented in this series of papers, were to develop a computational model of the brain stem respiratory neural network and to explore possible neural mechanisms that provide the genesis of respiratory oscillations and the specific firing patterns of respiratory neurons. The present paper describes models of single respiratory neurons that have been used as the elements in our network models of the central respiratory pattern generator presented in subsequent papers. The models of respiratory neurons were developed in the Hodgkin-Huxley style employing both physiological and biophysical data obtained from brain stem neurons in mammals. Two single respiratory neuron models were developed to match the two distinct firing behaviors of respiratory neurons described in vivo: neuron type I shows an adapting firing pattern in response to synaptic excitation, and neuron type II shows a ramp firing pattern during membrane depolarization after a period of synaptic inhibition. We found that a frequency ramp firing pattern can result from intrinsic membrane properties, specifically from the combined influence of calcium-dependent K(AHP)(Ca), low-threshold Ca(T) and K(A) channels. The neuron models with these ionic channels (type II) demonstrated ramp firing patterns similar to those recorded from respiratory neurons in vivo. Our simulations show that K(AHP)(Ca) channels in combination with high-threshold Ca(L) channels produce spike frequency adaptation during synaptic excitation. However, in combination with low-threshold Ca(T) channels, they cause a frequency ramp firing response after release from inhibition. This promotes a testable hypothesis that the main difference between the respiratory neurons that adapt (for example, early inspiratory, postinspiratory, and decrementing expiratory) and those that show ramp firing patterns (for example, ramp inspiratory and augmenting expiratory) consists of a ratio between the two types of calcium channels: Ca(L) channels predominate in the former and Ca(T) channels in the latter respiratory neuron types. We have analyzed the dependence of adapting and ramp firing patterns on maximal conductances of different ionic channels and values of synaptic drive. The effect of adjusting specific membrane conductances and synaptic interactions revealed plausible neuronal mechanisms that may underlie modulatory effects on respiratory neuron firing patterns and network performances. The results of computer simulation provide useful insight into functional significance of specific intrinsic membrane properties and their interactions with phasic synaptic inputs for a better understanding of respiratory neuron firing behavior.

Ionic mechanisms involved in the spontaneous firing of tegmental pedunculopontine nucleus neurons of the rat

We have previously defined three types of tegmental pedunculopontine nuclei neurons based on their electrophysiological characteristics: Type I neurons characterized by low-threshold Ca2+ spikes, Type II neurons which displayed a transient outward current (A-current), and Type III neurons having neither low-threshold spikes nor A-current [Kang Y. and Kitai S. T. (1990) Brain Res. 535, 79–95]. In this report, ionic mechanisms underlying repetitive firing of Type I (n=15) and Type II (n=69) neurons were studied in in vitro slice preparations. Type I neurons did not fire rhythmically but their spontaneous firing frequency ranged from 0 to 19.5spikes/s (mean 9.7spikes/s). The spontaneous firing of Type II neurons was rhythmic, with a mean frequency of 9.6spikes/s (range 3.5–16.0spikes/s). Choline acetyltransferase immunohistochemistry combined with biocytin labeling indicated that none of the Type I neurons were immunopositive to choline acetyltransferase, while 60% (42 of 69) of Type II neurons were immunopositive. There was no apparent difference in the electrophysiological membrane properties of immunopositive and immunonegative Type II neurons. At membrane potentials subthreshold for Na+ spikes (−50mV), spontaneous membrane oscillations (11.6Hz) were observed: these underlie the spontaneous repetitive firing of Type I neurons. The subthreshold membrane oscillation was tetrodotoxin sensitive but was not affected by Ca2+-free medium. A similar tetrodotoxin-sensitive subthreshold membrane oscillation (10.5Hz) was also observed in Type II neurons. However, in Type II neurons a membrane oscillation was also observed at higher membrane potentials (>−50mV). This high-threshold oscillation was insensitive to tetrodotoxin and Na+-free medium, but was eliminated in Ca2+-free conditions. The amplitude and frequency of the high-threshold oscillation was increased upon membrane depolarization. At the most prominent oscillatory level (around −40mV), the high-threshold oscillation had a mean frequency of 8.8Hz. The high-threshold Ca2+ spike was triggered from the peak potential (−35 to −30mV) of the high-threshold oscillation. Application of tetraethylammonium chloride (<5mM) increased the amplitude of the high-threshold oscillation, while nifedipine greatly attenuated the high-threshold oscillation without changing the shape of the high-threshold Ca2+ spike. Application of Cd2+ eliminated both the high-threshold oscillation and the high-threshold Ca2+ spike, and ω-conotoxin reduced the size of the high-threshold Ca2+ spike without affecting the frequency of the high-threshold oscillation. Nickel did not have any effect on either the high-threshold oscillation or the high-threshold Ca2+ spike.These data suggest an involvement of N- and L-type Ca2+ channels in the generation of the high-threshold oscillation and the high-threshold Ca2+ spike, respectively. The results indicate that a persistent Na+ conductance plays a crucial role in the subthreshold membrane oscillation, which underlies spontaneous repetitive firing in Type I neurons. On the other hand, in addition to a persistent Na+ conductance for subthreshold membrane oscillation, a voltage-dependent Ca2+ conductance with Ca2+-dependent K+ conductance (for the high-threshold oscillation) may be responsible for rhythmic firing of Type II neurons.

A novel benzothiazine Ca 2+ channel antagonist, semotiadil, inhibits cardiac L-type Ca 2+ currents

The influence of semotiadil fumarate, a novel vasoselective Ca 2+ channel antagonist with a benzothiazine skeleton, was measured on the high-threshold Ca 2+ current I Ca, L in guinea-pig ventricular myocytes prepared by coronary perfusion with collagenase solution. Patch- and voltage-clamp methods were used to measure I Ca, L . Diltiazem, nifedipine and amlodipine were studied for comparison. Semotiadil could be shown to inhibit I Ca, L in a dose-dependent manner in concentrations similar to those of diltiazem but was less effective than amlodipine and nifedipine. The IC 50 for nifedipine and amlodipine was in the range between 0.1 and 1 μM, and that of semotiadil and diltiazem was between 10 and 100 μM. Recovery from inactivation of I Ca, L in the control and under the influence of nifedipine (0.01 μM) and amlodipine (0.1 μM) was complete after 1 s. Semotiadil (0.1 μM) and diltiazem (1 μM) prolonged the time to full recovery to 20 s. This significant delay in the recovery of I Ca, L produced by semotiadil indicates a mode of action similar to that of the verapamil type of Ca 2+ channel antagonists and makes a clear distinction between it and the dihydropyridines, which have no effect on the recovery process. The rate dependence of the effect in combination with a distinct influence of the holding potential underlines the use dependence of the mechanism underlying the effect of semotiadil. The well-known high vasoselectivity of semotiadil in combination with a relatively low Ca 2+ channel antagonistic influence on the heart makes semotiadil an interesting candidate for the treatment of coronary heart diseases. © 1997 Elsevier Science B.V. All rights reserved.

Adenosine A 3 Receptors Potentiate Hippocampal Calcium Current by a PKA-dependent/PKC-independent Pathway

The modulation of high-threshold Ca current ( I Ca) by adenosine receptors was studied using the voltage clamp method on acutely dissociated guinea pig hippocampal CA3 pyramidal neurons. When these neurons were exposed to adenosine in the presence of A 1, A 2a and A 2b receptor antagonists, I Ca potentiation occurred at test potentials of −10 mV, but not at −40 mV. Similar potentiation also occurred using the A 3 agonist N 6-2-(4-aminophenyl)ethyl-adenosine (APNEA), either alone or in the presence of A 1 and A 2 antagonists. The putative A 4 agonist 2-phenylaminoadenosine (CV-1808; Cornfield et al., 1992) did not potentiate I Ca at four concentrations tested between 25 nM and 2500 nM. K 0.5 for the APNEA-induced Zhou et al., 1992). I Ca potentiation by APNEA was blocked by intracellular application of WIPTIDE, a PKA inhibitor ( p < 0.001), but was not affected by protein kinase C (PKC) inhibitor peptide (19–36). These results indicate that: (1) A 3 receptor activation can significantly potentiate I Ca, and (2) because the A 3 receptor has been linked to down-regulation of adenylyl cyclase ( Zhou et al., 1992), PKA appears to be negatively coupled to I Ca. © 1997 Elsevier Science Ltd. All rights reserved.

A ryanodine-sensitive calcium store in ascidian eggs monitored by whole-cell patch-clamp recordings

Using whole cell patch clamp recordings on unfertilized eggs of the ascidian Ciona intestinalis, we are able to detect ryanodine receptors within the oocytes. Our approach is based on measurements of the voltage-activated inward calcium currents. Two types of Ca 2+ currents have been described on the oocyte membrane of Ciona: a low threshold slowly activating current, and a high threshold faster one. We show here that caffeine induces a decrease in the intensity of the Ca 2+ currents, when applied either externally or internally from the mouth of a patch pipette. Caffeine application mimics fertilization which transiently decreases the high threshold Ca 2+ current density during the first meiotic cycle. Ryanodine (> 1nM) has an effect similar to caffeine. This partial decrease in Ca 2+ current density elicited by caffeine or ryanodine is prevented by intracellular application of the calcium chelator BAPTA, then imputable to calcium release. In summary, the depolarization-induced Ca 2+ current intensity allows monitoring of an intracellular calcium store which is sensitive to low concentrations of ryanodine in Ciona oocytes. Further identification of a ryanodine receptor was obtained by immunological staining with antibodies against mammalian skeletal muscle ryanodine receptor. Ryanodine receptors were asymmetrically localized in the cortex of Ciona eggs. We discuss the methodological relevance of our patch-clamp approach, in connection with the possible biological role of such a ryanodine receptor in the early stages of development.

Firing Modes and Membrane Properties in Lemniscal Auditory Thalamus

In neurons of the auditory thalamus, patterned sequences of action potentials encode the features of sound stimuli. The patterns vary with the membrane potential, characterizing states of wakefulness and sleep. We studied the dependence of the patterns on the membrane potential and specific voltage-gated conductances, using whole-cell patch-clamp recordings from neurons in the ventral medial geniculate body (MGBv) of in vitro slices. Thalamocortical neurons, identified with neurobiotin, exhibited different firing patterns to an excitatory input, depending on the initial membrane potential. From depolarized potentials, the neurons fired in a tonic mode. The delay to firing in this mode was regulated by a balance of persistent Na+ and A-type K.+ conductances. When transiently depolarized from hyperpolarized holding potentials, the neurons fired brief phasic responses (burst mode). Phasic responses were induced by low threshold Ca2+ spikes (LTSs); the LTS-amplitude was controlled by Na+ and K+ conductances. Under favourable conditions, an LTS triggered more than one action potential and one or more high threshold Ca2+ spikes (HTSs). Consciously perceived sound signals are transmitted in the tonic mode. During sleep, alerting stimuli may interact with membrane non-linearities, converting hyperpolarized bursting MGBv neurons to the tonic mode.

Mechanisms for signal transformation in lemniscal auditory thalamus.

1. During alertness, lemniscal thalamocortical neurons in the ventral medial geniculate body (MGBv) encode sound signals by firing action potentials in a tonic mode. When they are in a burst firing mode, characteristic of thalamic neurons during some sleep states, the same stimuli may have an alerting function, leading to conscious perception of sound. We investigated the intrinsic membrane properties of MGBv neurons in search of mechanisms that enable them to convert from burst to tonic firing modes, allowing accurate signal coding of sensory stimuli. 2. We studied thalamocortical relay neurons and identified neurons morphologically with injected N-(2-aminoethyl) biotinamide hydrochloride in in vitro slice preparations of young rats. With the use of the whole cell recording method, we examined the contributions of distinct conductances to voltage responses evoked by current pulses. The neurons (n = 74) displayed a narrow range of resting potentials (-68 +/- 4 mV, mean +/- SD) and an average input resistance of 226 +/- 100 M omega. The membrane time constant was 40 +/- 17.6 ms and the action potential threshold was -51.6 +/- 3 mV. 3. Injections of hyperpolarizing current pulses from rest revealed an inward rectification produced by two voltage-dependent components. A fast component, sensitive to blockade with Ba2+ (100-200 microM), was attributed to an inward rectifier, IIR. Such applications also increased input resistance and depolarized neurons, consistent with a blockade of various K+ conductances. Application of Ba2+ often unmasked another voltage-dependent rectification with a slower time course. The second component was sensitive to blockade with Cs+ (1.5 mM), reminiscent of a hyperpolarization-activated current, IH. 4. Depolarizing pulses from rest produced ramp-shaped voltage responses that led to delayed tonic firing. Blockade of Na+ conductances by tetrodotoxin (TTX, 300-600 nM), or extracellular replacement of Ca2+ with Mg2+ (with TTX present), reduced the slope of the ramp and the overall depolarizing response. Application of 4-aminopyridine (4-AP, 100 microM), a blocker of A-type K+ conductances, increased input resistance and the overall depolarizing response. The voltage ramp therefore represents a complex rectification due to voltage-dependent contributions of persistent Na-, Ca2+, and K+ conductances. 5. Depolarizing pulses from potentials of less than -75 mV evoked phasic burst responses, consisting of one to seven action potentials riding on a low-threshold spike (LTS). The LTS was absent in low extracellular Ca2+ conditions and was blocked by application of Ni2+ (0.6 mM), but not by Cd2+ (50 microM). Similar depolarization from less than -80 mV evoked several action potentials, often followed by a TTX-resistant high-threshold spike (HTS) of longer duration. Firing of HTSs always occurred during 4-AP (100 microM) application, inferring that, normally, A-type K+ conductances may control ability to fire an HTS. As in the LTS, a Ca2+ current is a major participant in the HTS because extracellular replacement of Ca2+ with Mg2+ or application of Cd2+ (50 microM) blocked its genesis. After TTX blockade of Na+ conductances, "tonic firing" of HTSs occurred during depolarization above -45 mV. 6. During tonic firing evoked by current pulses, the second and subsequent spikes were longer in duration than the initial action potentials. Low extracellular concentrations of Ca2+ or Cd2+ (50 microM) application reduced the durations of the nonprimary spikes, inferring a contribution of high-threshold voltage-dependent Ca2+ conductances to their repolarizing phase. Also, K+ conductances may contribute to spike repolarization, because 4-AP (100 microM) or tetraethylammonium (2 mM) application led to prolonged action potentials and the generation of plateau potentials. A fast afterhyperpolarization, likely mediated by a Ca(2+)-dependent K+ conductance, limited the tonic firing. Such conductances, therefore, may regulate the re

Temporal specificity of muscarinic synaptic modulation of the Ca(2+)-dependent K+ current (ISAHP) in rat hippocampal neurones.

1. We examined synaptic modulation of the Ca(2+)-dependent K+ current (ISAHP), which underlies the slow after-hyperpolarization (sAHP) in hippocampal CA1 neurones of rat brain slices. ISAHP was evoked in whole-cell voltage-clamp mode by depolarizing pulses, and synaptic afferents to CA1 neurones were stimulated electrically with a paired-pulse protocol. 2. Afferent stimulation delivered 200-1500 ms prior to be depolarizing pulse produced a profound reduction of ISAHP by 58%, but not other Ca(2+)-dependent outward currents that preceded ISAHP. Perfusion of slices with atropine significantly attenuated the synaptic reduction of ISAHP, indicating an event mediated largely by muscarinic receptor activation. When delivered < 400 ms after the depolarizing pulse, similar synaptic stimuli produced no substantial reduction in ISAHP, even in neurons where the duration of ISAHP was prolonged to 8-10 s either by lowering the recording temperature or by intracellular application of a calcium chelator. 3. To examine the effect of cholinergic stimulation of the depolarization-activated Ca2+ influx, high-threshold voltage-activated Ca2+ currents were recorded in the conventional or perforated whole-cell mode. Perfusion of slices with 5-10 microM carbachol for 5-10 min caused no substantial decrease in these Ca2+ currents, suggesting that the synaptic reduction of ISAHP is unlikely to be due to a blockade of depolarization-induced Ca2+ influx which triggers the generation of ISAHP. 4. The present data demonstrate that afferent stimulation reduces ISAHP only if it occurs prior to the depolarization-induced Ca2+ influx. We propose that modulation of inactive sAHP channels by muscarinic stimulation may decrease their sensitivity to the influx of Ca2+, whereas sAHP channels activated by Ca2+ may compete with the receptor-coupled modulation thus rendering the sAHP channels unresponsive to cholinergic afferent stimulation.

Lactoseries carbohydrate antigen, Gal beta 1-4GlcNAc-R, is expressed by a subpopulation of capsaicin-sensitive rat sensory neurons.

1. The membrane properties of dorsal root ganglion (DRG) cells expressing the lactoseries carbohydrate antigen Gal beta 1-4GlcNAc-R were studied and compared with those of DRG cells lacking this antigen. Acutely dissociated rat DRG cells that expressed Gal beta 1-4GlcNAc-R on their outer cell membranes were detected with the use of a primary monoclonal mouse IgM antibody (A5), directed against Gal beta 1-4GlcNAc-R, and a fluorescent secondary antibody (fluorescein-conjugated goat anti-mouse IgM). We found 12.8 micrograms/ml of A5 to be a saturating concentration of primary antibody that labeled approximately 19% of the DRG cells. A battery of membrane properties including action potential (AP) duration; sensitivity to capsaicin; expression of H current (IH), A current (IA), and Ca2+ current subtypes (L, N, and T); and inhibition of high-threshold Ca2+ currents by serotonin (5HT) or 8-hydroxy-2-(di-N-propylamino)-tetralin (8-OH-DPAT) was measured in DRG cells labeled (A5+) and unlabeled (A5-) by a saturating concentration of A5. 2. There was a significant difference in the number of capsaicin-sensitive DRG cells and a significant difference in the magnitude of the capsaicin-induced inward current in A5+ versus A5- DRG cells. Of 35 A5+ cells tested, 33 were sensitive to 1 microM capsaicin, which produced an inward current averaging 4 +/- 0.46 (SE) nA (n = 33). In contrast, only 12 of 33 A5- cells were sensitive to 1 microM capsaicin, which produced an inward current averaging 1.2 +/- 0.52 nA (n = 12). 3. There were also significant differences between A5+ and A5- cells regarding average AP duration, N- and T-type Ca2+ current amplitude, and number of cells that expressed IH and IA. A5+ cells had significantly larger N-type Ca2+ currents and expressed IA more frequently than A5- cells. Conversely, A5- cells had significantly longer AP duration and larger T-type Ca2+ currents, and expressed IH more frequently compared with A5+ cells. 4. A5+ and A5- cells differed regarding the inhibition of high-threshold Ca2+ currents by maximal concentrations of 5HT1A agonists (10 microM 5HT or 1 microM 8-OH-DPAT). Inhibition of Ca2+ currents in A5+ cells by 1 microM 8-OH-DPAT (n = 15) or 10 microM 5HT (n = 18) averaged 4 +/- 0.9%. In contrast, inhibition of Ca2+ currents in A5- cells by 10 microM 5HT (n = 33) averaged 20 +/- 3.8%. 5. Cells for which sufficient data were collected were categorized as type 1, 2, 3, or 4 on the basis of sensitivity to capsaicin and expression of IH, IA, and T-type Ca2+ current amplitude, and the distribution of A5+ and A5- cells among the various groups was observed. The categories were defined as follows: type 1 (capsaicin sensitive, no IH or IA); type 2 (capsaicin sensitive, significant IA); type 3 (capsaicin insensitive, T-type Ca2+ currents < 1 nA, significant IH but no IA); and type 4 (capsaicin insensitive, T-type Ca2+ currents > 2.4 nA). On the basis of this criteria, 6 of 15 type 1 cells and all type 2 cells (n = 19) were A5+. All type 3 cells (n = 8) and all type 4 cells (n = 11) were A5-. 6. As indicated above, the expression of the Gal beta 1-4GlcNAc-R antigen differentiated two subgroups of DRG cells in the type 1 category (A5+, n = 6 and A5-, n = 9). These two groups varied regarding the sensitivity of Ca2+ currents to maximally effective concentrations of 5HTIA agonists. In type 1 A5+ DRG cells, high-threshold Ca2+ currents were not significantly inhibited by 1 microM 8-OH-DPAT (average inhibition = 1.2 +/- 0.8%, n = 6). However, in type 1 A5- cells, high-threshold Ca2+ currents were reduced 47 +/- 6.0% (n = 9) by 10 microM 5HT. 7. The several significant differences in membrane properties between A5+ and A5- DRG cells suggest that the Gal beta 1-4GlcNAc-R antigen is expressed by a distinct subset of DRG cells, consisting predominately of type 1 and type 2 cells. The observation that most A5+ DRG cells were capsaicin sensitive suggests that the Gal beta 1-4GlcNAc-R antigen is expressed primarily by n

Aging Changes in Voltage-Gated Calcium Currents in Hippocampal CA1 Neurons

Previous current-clamp studies in rat hippocampal slice CA1 neurons have found aging-related increases in long-lasting calcium (Ca)-dependent and Ca-mediated potentials. These changes could reflect an increase in Ca influx through voltage-gated Ca channels but also could reflect a change in potassium currents. Moreover, if altered Ca influx is involved, it is nuclear whether it arises from generally increased Ca channel activity, lower threshold, or reduced inactivation. To analyze the basis for altered Ca potentials, whole-cell voltage-clamp studies of CA1 hippocampal neurons were performed in nondissociated hippocampal slices of adult (3- to 5-month-old) and aged (25- to 26-month-old) rats. An aging-related increase was found in high-threshold Ca and barium (Ba) currents, particularly in the less variable, slowly inactivating (late) current at the end of a depolarization step. Input resistance of neurons did not differ between age groups. In steady-state inactivation and repetitive-pulse protocols, inactivation of Ca and Ba currents was not reduced and, in some cases, was slightly greater in aged neurons, apparently because of larger inward current. The current blocked by nimodipine was greater in aged neurons, indicating that some of the aging increase was in L-type currents. These results indicate that whole-cell Ca currents are increased with aging in CA1 neurons, apparently attributable to greater channel activity rather than to reduced inactivation. The elevated Ca influx seems likely to play a role in impaired function and enhanced susceptibility to neurotoxic influences.

Intracellular QX-314 inhibits calcium currents in hippocampal CA1 pyramidal neurons.

1. The effects of intracellular QX-314 on Ca2+ currents were examined in CA1 pyramidal cells acutely isolated from rat hippocampus. In neurons dialyzed with 10 mM QX-314 (bromide salt), the amplitude of the high-threshold Ca2+ current was on average 20% of that in control cells and the current-voltage relationships (I-Vs) were shifted in the positive voltage direction. 2. The positive shift in the I-Vs was due to the presence of intracellular Br-, because it was reproduced by 10 mM NaBr and was not present when the chloride salt of QX-314 was used. 3. Low-threshold (T-type) Ca2+ currents, at test voltages of -50 and -40 mV, were on average < 45% of control amplitude in cells containing 10 mM QX-314 (chloride salt) and < 10% of control amplitude in cells with 10 mM QX-314 (bromide salt). 4. In neurons dialyzed with 1 mM QX-314, high-threshold Ca2+ currents were still significantly different from control and Na+ currents were not completely blocked. 5. The proportions of high-threshold Ca2+ current blocked by omega-conotoxin GVIA, omega-agatoxin IVA, and nimodipine were similar in cells dialyzed with 10 mM QX-314 and control cells, indicating that the drug does not selectively inhibit any of the Ca2+ channel subtypes distinguished by these antagonists.

The α1ECalcium Channel Exhibits Permeation Properties Similar to Low-Voltage-Activated Calcium Channels

The physiological and pharmacological properties of the alpha 1E calcium (Ca) channel subtype do not exactly match any of the established categories described for native neuronal Ca currents. Many of the key diagnostic features used to assign cloned Ca channels to their native counterparts, however, are dependent on a number of factors, including cellular environment, beta subunit coexpression, and modulation by second messengers and G-proteins. Here, by examining the intrinsic pore characteristics of a family of transiently expressed neuronal Ca channels, we demonstrate that the permeation properties of alpha 1E closely resemble those described for a subset of low-threshold Ca channels. The alpha 1A (P-/Q-type), alpha 1B (N-type), and alpha 1C (L-type) high-threshold Ca channels all exhibit larger whole-cell currents with barium (Ba) as the charge carrier as compared with Ca or strontium (Sr). In contrast, macroscopic alpha 1E currents are largest in Sr, followed by Ca and then Ba. The unique permeation properties of alpha 1E are maintained at the single-channel level, are independent of the nature of the expression system, and are not affected by coexpression of alpha 2 and beta subunits. Overall, the permeation characteristics of alpha 1E are distinct from those described for R-type currents and share some similarities with native low-threshold Ca channels.

Mechanism of inhibition of calcium channels in rat nucleus tractus solitarius by neurotransmitters.

1. High-threshold Ca2+ channel currents were measured every 15 s following a 200 ms voltage step from -80 mV to 0 mV in order to study the coupling mechanism between neurotransmitter receptors and Ca2+ channels in neurones acutely isolated from the nucleus tractus solitarius (NTS) of the rat. 2. Application of 30 microM baclofen (GABAB receptor agonist) caused 38.9 +/- 1.2% inhibition of the peak inward Ba2+ current (IBa2+) in most NTS cells tested (n = 85 of 88). Somatostatin, 300 nM, also reduced IBa2+ by 31.3 +/- 1.6% in 53 cells of 82 tested. 3. Activation of mu-opioid-, GABAB- or somatostatin-receptors inhibited both N- and P/Q-type Ca2+ channels. 4. The inhibition of Ca2+ currents by DAMGo (mu-opioid receptor agonist), baclofen and somatostatin was reduced by treatment with pertussis toxin and partially relieved by application of a 50 ms conditioning prepulse to +80 mV. This suggests that a pertussis toxin-sensitive G-protein was involved in the neurotransmitter-mediated action in the observed inhibition of Ca2+ currents. 5. Intracellular loading with an antiserum raised against the amino terminus of Go alpha (GC/2) markedly attenuated the somatostatin-induced inhibition, but did not block the DAMGO- and baclofen-induced inhibition. 6. These findings suggest at least two different pertussis toxin-sensitive G-protein-mediated pathways are involved in receptor-induced inhibition of Ca2+ currents in the NTS.

Functional role of low-voltage-activated dihydropyridine-sensitive Ca channels during the action potential in adult rat sensory neurones.

Neuronal cell firing is crucial to nerve-nerve communication. The ability to produce consecutive action potentials is related to the activation of inward currents after each upstroke. If fast Na current is indeed responsible for the overshoot, it is still unclear which current drives membrane voltage to the Na threshold. In this study we present evidence that in adult rat sensory neurones a dihydropyridine-sensitive Ca channel exists in addition to the well characterized L-type, or high-threshold Ca channel. During stimulated action potential trains, L-type Ca channels open during the excitation wave, whereas activity of the other dihydropyridine-sensitive Ca channel was observed primarily between action potentials. This second Ca pathway shows remarkably long openings at negative potentials after a series of positive prepulses. The nerve action potential and the repetitive firing work as a physiological Ca channel facilitation mechanism. Therefore, we suggest that this novel Ca conductance provides inward current, between two consecutive action potentials, able to modulate the frequency of neuronal bursts.