Ca2+ channels that activate Ca2+-dependent K+ currents in neostriatal neurons

It is demonstrated that not all voltage-gated calcium channel types expressed in neostriatal projection neurons (L, N, P, Q and R) contribute equally to the activation of calcium-dependent potassium currents. Previous work made clear that different calcium channel types contribute with a similar amount of current to whole-cell calcium current in neostriatal neurons. It has also been shown that spiny neurons posses both “big” and “small” types of calcium-dependent potassium currents and that activation of such currents relies on calcium entry through voltage-gated calcium channels. In the present work it was investigated whether all calcium channel types equally activate calcium-dependent potassium currents. Thus, the action of organic calcium channel antagonists was investigated on the calcium-activated outward current. Transient potassium currents were reduced by 4-aminopyridine and sodium currents were blocked by tetrodotoxin. It was found that neither 30 nM ω-Agatoxin-TK, a blocker of P-type channels, nor 200 nM calciseptine or 5 μM nitrendipine, blockers of L-type channels, were able to significantly reduce the outward current. In contrast, 400 nM ω-Agatoxin-TK, which at this concentration is able to block Q-type channels, and 1 μM ω-Conotoxin GVIA, a blocker of N-type channels, both reduced outward current by about 50%. These antagonists given together, or 500 nM ω-Conotoxin MVIIC, a blocker of N- and P/Q-type channels, reduced outward current by 70%. In addition, the N- and P/Q-type channel blockers preferentially reduce the afterhyperpolarization recorded intracellularly.The results show that calcium-dependent potassium channels in neostriatal neurons are preferentially activated by calcium entry through N- and Q-type channels in these conditions.     

Ca2+-activated outward currents in neostriatal neurons

Whole-cell voltage-clamp recordings of outward currents were obtained from acutely dissociated neurons of the rat neostriatum in conditions in which inward Ca2+ current was not blocked and intracellular Ca2+ concentration was lightly buffered. Na+ currents were blocked with tetrodotoxin. In this situation, about 53 +/- 4% (mean +/- S.E.M.; n = 18) of the outward current evoked by a depolarization to 0 mV was sensitive to 400 microM Cd2+. A similar percentage was sensitive to high concentrations of intracellular chelators or to extracellular Ca2+ reduction (<500 microM); 35+/-4% (n=25) of the outward current was sensitive to 3.0 mM 4-aminopyridine. Most of the remaining current was blocked by 10 mM tetraethylammonium. The results suggest that about half of the outward current is activated by Ca2+ entry in the present conditions. The peptidic toxins charybdotoxin, iberotoxin and apamin confirmed these results, since 34 +/- 5% (n = 14), 29 5% (n= 14) and 28 +/- 6% (n=9) of the outward current was blocked by these peptides, respectively. The effects of charybdotoxin and iberotoxin added to that of apamin, but their effects largely occluded each other. There was additional Cd2+ block after the effect of any combination of toxins. Therefore, it is concluded that Ca2+-activated outward currents in neostriatal neurons comprise several components, including small and large conductance types. In addition, the present experiments demonstrate that Ca2+-activated K+ currents are a very important component of the outward current activated by depolarization in neostriatal neurons.     

Cromakalim and lemakalim activate Ca2+-dependent K+ channels in canine colon

The effects of cromakalim (BRL 34915) and its (–) optical isomer, lemakalim (BRL 38227) on the activity of 265-pS Ca²⁺-activated K⁺ channels (BK channels) were examined in cell-attached and inside-out patches from canine colonic myocytes. In cell-attached patches lemakalim increased the open probability (P _o) of BK channels. Mean NP _o, where N is the number of channels per patch, at + 50 mV increased from 0.08 to 0.26 (20 M lemakalim). In inside-out patches, cromakalim and lemakalim increased channel NP _o rapidly and reversibly. This increase in NP _o was due to a shift in half-maximal activation. Glyburide (20 M) prevented the increase in NP _o caused by lemakalim in cell-attached patches and reversed the increase in NP _o in inside-out patches. Under conditions where Ca²⁺-activated K⁺ channels were maximally activated, lemakalim failed to increase current or induce a second type of K⁺ channel activity. When tetraethylammonium (200 M) was added to the pipette solution to block the BK channel half maximally, lemakalim also failed to induce a second type of channel. Adenosine triphosphate (1 or 2 mM) applied to the inner surface of inside-out patches had no effect on P _o of BK channels. Finally, the effects of lemakalim on ensemble average currents, constructed from multiple openings of BK channels in cell-attached patches was found to successfully mimic the effects of the drug on whole-cell membrane currents. We conclude that cromakalim and lemakalim activate BK channels in canine colonic cells. Whether this action participates in the membrane hyperpolarization and the decrease in frequency and duration of slow waves produced by these compounds in intact colonic muscles remains to be investigated.     

Ca2+-dependent large conductance K+ currents in thalamocortical relay neurons of different rat strains

Mutations in genes coding for Ca²⁺ channels were found in patients with childhood absence epilepsy (CAE) indicating a contribution of Ca²⁺-dependent mechanisms to the generation of spike-wave discharges (SWD) in humans. Since the involvement of Ca²⁺ signals remains unclear, the aim of the present study was to elucidate the function of a Ca²⁺-dependent K⁺ channel (BK_Ca) under physiological conditions and in the pathophysiological state of CAE. The activation of BK_Ca channels is dependent on both voltage and intracellular Ca²⁺ concentrations. Moreover, these channels exhibit an outstandingly high level of regulatory heterogeneity that builds the basis for the influence of BK_Ca channels on different aspects of neuronal activity. Here, we analyse the contribution of BK_Ca channels to firing of thalamocortical relay neurons, and we test the hypothesis that BK_Ca channel activity affects the phenotype of a genetic rat model of CAE. We found that the activation of the β₂-adrenergic receptor/protein kinase A pathway resulted in BK_Ca channel inhibition. Furthermore, BK_Ca channels affect the number of action potentials fired in a burst and produced spike frequency adaptation during tonic activity. The latter result was confirmed by a computer modelling approach. We demonstrate that the β₂-adrenergic inhibition of BK_Ca channels prevents spike frequency adaptation and, thus, might significantly support the tonic firing mode of thalamocortical relay neurons. In addition, we show that BK_Ca channel functioning differs in epileptic WAG/Rij and thereby likely contributes to highly synchronised, epileptic network activity.     

Blockade of SK-type Ca2+-activated K+ channels uncovers a Ca2+-dependent slow afterdepolarization in nigral dopamine neurons

Sharp electrode current-clamp recording techniques were used to characterize the response of nigral dopamine (DA)-containing neurons in rat brain slices to injected current pulses applied in the presence of TTX (2 microM) and under conditions in which apamin-sensitive Ca2+-activated K+ channels were blocked. Addition of apamin (100-300 nM) to perfusion solutions containing TTX blocked the pacemaker oscillation in membrane voltage evoked by depolarizing current pulses and revealed an afterdepolarization (ADP) that appeared as a shoulder on the falling phase of the voltage response. ADP were preceded by a ramp-shaped slow depolarization and followed by an apamin-insensitive hyperpolarizing afterpotential (HAP). Although ADPs were observed in all apamin-treated cells, the duration of the response varied considerably between individual neurons and was strongly potentiated by the addition of TEA (2-3 mM). In the presence of TTX, TEA, and apamin, optimal stimulus parameters (0.1 nA, 200-ms duration at -55 to -68 mV) evoked ADP ranging from 80 to 1,020 ms in duration (355.3 +/- 56.5 ms, n = 16). Both the ramp-shaped slow depolarization and the ensuing ADP were markedly voltage dependent but appeared to be mediated by separate conductance mechanisms. Thus, although bath application of nifedipine (10-30 microM) or low Ca2+, high Mg2+ Ringer blocked the ADP without affecting the ramp potential, equimolar substitution of Co2+ for Ca2+ blocked both components of the voltage response. Nominal Ca2+ Ringer containing Co2+ also blocked the HAP evoked between -55 and -68 mV. We conclude that the ADP elicited in DA neurons after blockade of apamin-sensitive Ca2+-activated K+ channels is mediated by a voltage-dependent, L-type Ca2+ channel and represents a transient form of the regenerative plateau oscillation in membrane potential previously shown to underlie apamin-induced bursting activity. These data provide further support for the notion that modulation of apamin-sensitive Ca2+-activated K+ channels in DA neurons exerts a permissive effect on the conductances that are involved in the expression of phasic activity.     

Rat hippocampal neurons in culture: Ca2+ and Ca2+-dependent K+ conductances

Rat hippocampal neurons grown in dissociated cell culture were studied in a medium containing 1 microM tetrodotoxin (TTX) and 25 mM tetraethylammonium (TEA), which eliminated the Na+ and K+ conductances normally activated by depolarizing current injections. In this medium depolarizing current pulses evoked depolarizing regenerative potentials and afterhyperpolarizations in most cells. Both of these events were blocked by close application of Co2+ or Cd2+. These events resemble Ca2+ spikes reported previously in hippocampal pyramidal cells. The membrane potential at which these Ca2+ spikes could be triggered and the rheobase current necessary were dependent on the potential at which the cell was conditioned: the more depolarized the holding potential, the more negative the absolute potential at which a spike could be triggered and the less rheobase current required. The duration of these Ca2+ spikes was also sensitive to the holding potential: the more depolarized the holding level, the longer the duration of the triggered spikes. The amplitude and duration of the Ca2+ spikes were enhanced in a reversible manner by 0.5-1.0 mM 4-aminopyridine (4-AP) delivered in the vicinity of the cell. Two-electrode voltage-clamp analysis of cells studied in TTX, TEA-containing medium revealed an inward current response that peaked in 25-50 ms during depolarizing commands. This response first became detectable during commands to -30 mV. It peaked in amplitude during commands to -10 mV and was enhanced in medium containing elevated [Ca2+]0. It was blocked by either 20 mM Mg2+, 0.2 mM Cd2+, 5 mM Co2+, or 5 mM Mn2+. These results have led us to identify this inward current response as ICa2+. 4-AP enhanced the magnitude and duration of ICa2+ independent of the drug's depressant effects on a transient K+ current also observed under these same experimental conditions. In many but not all cells the Ca2+ spike was followed by a long-lasting hyperpolarization associated with an increase in membrane conductance. This was blocked by Co2+. Under voltage clamp ICa2+ was followed by a slowly developing outward current response that was attenuated by Co2+ or Cd2+. These properties observed under current- and voltage-clamp recording conditions are superficially similar to those previously reported for Ca2+-dependent K+ conductance mechanisms (IC) recorded in these and other membranes. Long-lasting tail currents following activation of IC inverted in the membrane potential range for the K+ equilibrium potential found in these cells.     

Characterisation of Ca2+-dependent inwardly rectifying K+ currents in HeLa cells

The whole-cell configuration of the patch-clamp technique was used to examine K⁺ currents in HeLa cells. Under quasi-physiological ionic gradients, using an intracellular solution containing 10^–7 mol/l free Ca²⁺, mainly outward currents were observed. Large inwardly rectifying currents were elicited in symmetrical 145 mmol/l KCl. Replacement of all extracellular K⁺ by isomolar Na⁺, greatly decreased inward currents and shifted the reversal potential as expected for K⁺ selectivity. The inwardly rectifying K⁺ currents exhibited little or no apparent voltage dependence within the range of from –120 mV to 120 mV. A square-root relationship between chord conductance and [K⁺]₀ at negative potentials could be established. The inwardly rectifying nature of the currents was unaltered after removal of intracellular Mg²⁺ and chelation with ATP and ethylenediaminetetraacetic acid (EDTA). Permeability ratios for other monovalent cations relative to K⁺ were: K⁺ (1.0)>Rb⁺ (0.86)>Cs⁺ (0.12)>Li⁺ (0.08)>Na⁺ (0.03). Slope conductance ratios measured at –100 mV were: Rb⁺ (1.66)>K⁺ (1.0)>Na⁺ (0.09)>Li⁺ (0.08)>Cs⁺ (0.06). K⁺ conductance was highly sensitive to intracellular free Ca²⁺ concentration. The relationship between conductance at 0 mV and Ca²⁺ concentration was well described by a Hill expression with a dissociation constant, K _D, of 70 nmol/l and a Hill coefficient, n, of 1.81. Extracellular Ba²⁺ blocked the currents in a concentration- and voltage-dependent manner. The dependence of the K _D for the blockade was analysed using a Woodhull-type treatment, locating the ion interaction site at 19 % of the distance across the electrical field of the membrane and a K _D (0 mV) of 7 mmol/l. Tetraethylammonium and 4-aminopyridine were without effect whilst quinine and quinidine blocked the currents with concentrations for half-maximum effects equal to 7 mol/l and 3.5 mol/l, respectively. The unfractionated venom of the scorpion Leiurus quinquestriatus (LQV) blocked the K⁺ currents of HeLa cells. The toxins apamin and scyllatoxin had no detectable effect whilst charybdotoxin, a component of LQV, blocked in a voltage-dependent manner with half-maximal concentrations of 40 nmol/l at –120 mV and 189 nmol/l at 60 mV; blockade by charybdotoxin accounts for the effect of LQV. Application of ionomycin (5–10 mol/l), histamine (1 mmol/l) or bradykinin (1–10 mol/l) to cells dialysed with low-buffered intracellular solutions induced K⁺ currents showing inward rectification and a lack of voltage dependence.     

Ca2+ signaling by T-type Ca2+ channels in neurons

Among the major families of voltage-gated Ca²⁺ channels, the low-voltage-activated channels formed by the Ca_v3 subunits, referred to as T-type Ca²⁺ channels, have recently gained increased interest in terms of the intracellular Ca²⁺ signals generated upon their activation. Here, we provide an overview of recent reports documenting that T-type Ca²⁺ channels act as an important Ca²⁺ source in a wide range of neuronal cell types. The work is focused on T-type Ca²⁺ channels in neurons, but refers to non-neuronal cells in cases where exemplary functions for Ca²⁺ entering through T-type Ca²⁺ channels have been described. Notably, Ca²⁺ influx through T-type Ca²⁺ channels is the predominant Ca²⁺ source in several neuronal cell types and carries out specific signaling roles. We also emphasize that Ca²⁺ signaling through T-type Ca²⁺ channels occurs often in select subcellular compartments, is mediated through strategically co-localized targets, and is exploited for unique physiological functions. Lucius Cueni and Marco Canepari contributed equally to this review.     

Differential effects of apamin on Ca2+-dependent K+ currents in bullfrog sympathetic ganglion cells

In B-type neurones of bullfrog sympathetic ganglia, apamin (10 nM) suppressed the Ca2+-dependent K+ current (IAH) involved in the afterhyperpolarization of an action potential, while it did not affect the Ca2+-dependent K+ current (Ic) underlying the spike repolarization. IAH was further separated into two exponential components which were differentially affected by apamin, voltage and alterations in Ca2+ influx, suggesting the existence of 3 different types of Ca2+-dependent K+ channel in bullfrog sympathetic neurones.     

Influence of Ca2+-binding proteins and the cytoskeleton on Ca2+-dependent inactivation of high-voltage activated Ca2+ currents in thalamocortical relay neurons

Ca²⁺-dependent inactivation (CDI) of high-voltage activated (HVA) Ca²⁺ channels was investigated in acutely isolated and identified thalamocortical relay neurons of the dorsal lateral geniculate nucleus (dLGN) by combining electrophysiological and immunological techniques. The influence of Ca²⁺-binding proteins, calmodulin and the cytoskeleton on CDI was monitored using double-pulse protocols (a constant post-pulse applied shortly after the end of conditioning pre-pulses of increasing magnitude). Under control conditions the degree of inactivation (34±9%) revealed a U-shaped and a sigmoid dependency of the post-pulse current amplitude on pre-pulse voltage and charge influx, respectively. In contrast to a high concentration (5.5 mM) of EGTA (31±3%), a low concentration (3 µM) of parvalbumin (20±2%) and calbindin_D28K (24±4%) significantly reduced CDI. Subtype-specific Ca²⁺ channel blockers indicated that L-type, but not N-type Ca²⁺ channels are governed by CDI and modulated by Ca²⁺-binding proteins. These results point to the possibility that activity-dependent changes in the intracellular Ca²⁺-binding capacity can influence CDI substantially. Furthermore, calmodulin antagonists (phenoxybenzamine, 22±2%; calmodulin binding domain, 17±1%) and cytoskeleton stabilizers (taxol, 23±5%; phalloidin, 15±3%) reduced CDI. Taken together, these findings indicate the concurrent occurrence of different CDI mechanisms in a specific neuronal cell type, thereby supporting an integrated model of this feedback mechanism and adding further to the elucidation of the role of HVA Ca²⁺ channels in thalamic physiology.     

Ca2+-dependent inactivation of Ca2+-induced Ca2+ release in bullfrog sympathetic neurons

We studied inactivation of Ca(2+)-induced Ca(2+) release (CICR) via ryanodine receptors (RyRs) in bullfrog sympathetic neurons. The rate of rise in [Ca(2+)](i) due to CICR evoked by a depolarizing pulse decreased markedly within 10-20 ms to a much slower rate despite persistent Ca(2+) entry and little depletion of Ca(2+) stores. The Ca(2+) entry elicited by the subsequent pulse within 50 ms, during which the [Ca(2+)](i) level remained unchanged, did not generate a distinct [Ca(2+)](i) rise. This mode of [Ca(2+)](i) rise was unaffected by a mitochondrial uncoupler, carbonyl cyanide p-trifluromethoxy-phenylhydrazone (FCCP, 1 microm). Paired pulses of varying interval and duration revealed that recovery from inactivation became distinct >or= 50 ms after depolarization and depended on [Ca(2+)](i). The inactivation was prevented by BAPTA (>or= 100 microm) but not by EGTA (相似文献   

Presence of Ca2+-dependent K+ channels in chemosensory cilia support a role in odor transduction

Olfactory receptor neurons (ORNs) respond to odorants with changes in the action potential firing rate. Excitatory responses, consisting of firing increases, are mediated by a cyclic AMP cascade that leads to the activation of cationic nonselective cyclic nucleotide-gated (CNG) channels and Ca2+-dependent Cl- (ClCa) channels. This process takes place in the olfactory cilia, where all protein components of this cascade are confined. ORNs from various vertebrate species have also been shown to generate inhibitory odor responses, expressed as decreases in action potential discharges. Odor inhibition appears to rely on Ca2+-dependent K+ (KCa) channels, but the underlying transduction mechanism remains unknown. If these channels are involved in odor transduction, they are expected to be present in the olfactory cilia. We found that a specific antibody against a large conductance KCa recognized a protein of approximately 116 kDa in Western blots of purified rat olfactory ciliary membranes. Moreover, the antibody labeled ORN cilia in isolated ORNs from rat and toad (Caudiverbera caudiverbera). In addition, single-channel recordings from inside-out membrane patches excised from toad chemosensory cilia showed the presence of 4 different types of KCa channels, with unitary conductances of 210, 60, 12, and 29 and 60 pS, high K+-selectivity, and Ca2+ sensitivities in the low micromolar range. Our work demonstrates the presence of K+ channels in the ORN cilia and supports their participation in odor transduction.     

Single channel Ca2+ currents inHelix pomatia neurons

Unitary Ca²⁺ currents of TEA injected Helix neurons were recorded in the Giga seal situation (6, 7) from microscopic membrane patches exposed to 50 mM [Ca²⁺]_o, O [Na⁺]_o, 20 mM [TEA⁺]_o and 2.5 M [TTX]_o. Constant field assumptions yield a channel permeability of 2.9±1.0×10^–14 cm³s^–1 corresponding to slope conductances of 5 to 15 pS between 0 and –30 mV. Frequency of occurrence of the units strongly increased with depolarization. Mean open time of the Ca²⁺ channels was about 3 ms without obvious dependence on voltage. A similar open time was seen with [Ba²⁺]_o, yielding about double the current strength when compared with [Ca²⁺]_o.     

Norepinephrine selectively reduces slow Ca2+- and Na+-mediated K+ currents in cat neocortical neurons

1. The effects of norepinephrine (NE) and related agonists and antagonists were examined on large neurons from layer V of cat sensorimotor cortex ("Betz cells") were examined in a brain slice preparation using intracellular recording, constant current stimulation and single microelectrode voltage clamp. 2. Application of NE (0.1-100 microM) usually caused a small depolarization from resting potential; hyperpolarizations were rare. Application of NE reversibly reduced rheobase and both the Ca2+- and Na+-dependent portions of the slow afterhyperpolarization (sAHP) that followed sustained firing evoked by constant current injection. The faster Ca2+-dependent medium afterhyperpolarization (mAHP), the fast afterhyperpolarization (fAHP), the action potential, and input resistance were unaffected. 3. The changes in excitability produced by NE application were most apparent during prolonged stimulation. The cells exhibited steady repetitive firing to currents that were formerly ineffective. The slow phase of spike frequency adaptation was reduced selectively and less habituation occurred during repeated long-lasting stimuli. The relation between firing rate and injected current became steeper if firing rate was averaged over several hundred milliseconds. 4. During voltage clamp in TTX, NE application selectively reduced the slow component of Ca2+-mediated K+ current. The faster Ca2+-mediated K+ current was unaffected, as were two voltage-dependent, transient K+ currents, the anomalous rectifier and leakage conductance measured at resting potential. Depolarizing voltage steps in the presence of Cd2+ revealed an apparent time- and voltage-dependent increase of the persistent Na+ current after NE application. The voltage-clamp results suggested ionic mechanisms for all effects seen during constant current stimulation except the depolarization from resting potential. The latter was insensitive to Cd2+ and TTX and occurred without a detectable change in membrane conductance. 5. NE application did not alter Ca2+ spikes evoked in the presence of TTX and 10 mM TEA. Inward Ca2+ currents examined during voltage clamp in TTX (with K+ currents reduced) became slightly larger after NE application. We conclude that NEs reduction of the slow Ca2+-mediated K+ current is not caused by reduction of Ca2+ influx. 6. Effects on membrane potential, rheobase, and the sAHP were mimicked by the beta-adrenergic agonist isoproterenol, but not by the alpha-adrenergic agonists clonidine or phenylephrine at higher concentrations.(ABSTRACT TRUNCATED AT 400 WORDS)     

Small-conductance Ca2+-dependent K+ channels are the target of spike-induced Ca2+ release in a feedback regulation of pyramidal cell excitability

Cooperative regulation of inosiol-1,4,5-trisphosphate receptors (IP(3)Rs) by Ca(2+) and IP(3) has been increasingly recognized, although its functional significance is not clear. The present experiments first confirmed that depolarization-induced Ca(2+) influx triggers an outward current in visual cortex pyramidal cells in normal medium, which was mediated by apamin-sensitive, small-conductance Ca(2+)-dependent K(+) channels (SK channels). With IP(3)-mobilizing neurotransmitters bath-applied, a delayed outward current was evoked in addition to the initial outward current and was mediated again by SK channels. Calcium turnover underlying this biphasic SK channel activation was investigated. By voltage-clamp recording, Ca(2+) influx through voltage-dependent Ca(2+) channels (VDCCs) was shown to be responsible for activating the initial SK current, whereas the IP(3)R blocker heparin abolished the delayed component. High-speed Ca(2+) imaging revealed that a biphasic Ca(2+) elevation indeed underlays this dual activation of SK channels. The first Ca(2+) elevation originated from VDCCs, whereas the delayed phase was attributed to calcium release from IP(3)Rs. Such enhanced SK currents, activated dually by incoming and released calcium, were shown to intensify spike-frequency adaptation. We propose that spike-induced calcium release from IP(3)Rs leads to SK channel activation, thereby fine tuning membrane excitability in central neurons.     

Modulation of a Ca2+-dependent K+-current by intracellular cAMP in rat thalamocortical relay neurons

Voltage-activated calcium channels in thalamic neurons are considered important elements in the generation of thalamocortical burst firing during periods of electroencephalographic synchronization. A potent counterpart of calcium-mediated depolarization may reside in the activation of calcium-dependent potassium conductances. In the present study, thalamocortical relay cells that were acutely dissociated from the rat ventrobasal thalamic complex (VB) were studied using whole-cell patch-clamp techniques. The calcium-dependent potassium-current (I_K(Ca)) was evident as a slowly activating component of outward current sensitive to the calcium ions (Ca²⁺)-channel blocker methoxyverapamil (10 μM) and to substitution of external calcium by manganese. The I_K(Ca) was blocked by tetraethylammonium chloride (1 mM) and iberiotoxin (100 nM), but not apamin (1 μM). In addition, isolated VB neurons were immunopositive to anti-α_(913–926) antibody, a sequence-directed antibody to the α-subunit of “big” Ca²⁺-dependent K⁺-channel (BK_Ca) channels. Activators of the adenylyl cyclase cyclic adenosine monophosphate (cAMP) system, such as forskolin (20 μM), dibutyryl-cAMP (10 mM) and 3-isobutyl-1-methylxanthine (500 μM), selectively and reversibly suppressed I_K(Ca). These results suggest that a rise in intracellular cAMP level leads to a decrease in a calcium-dependent potassium conductance presumably mediated via BK_Ca type channels, thereby providing an additional mechanism by which neurotransmitter systems are able to control electrogenic activity in thalamocortical neurons and circuits during various states of electroencephalographic synchronization and de-synchronization.     

Distinct inhibition of voltage-activated Ca2+ channels by delta-opioid agonists in dorsal root ganglion neurons devoid of functional T-type Ca2+ currents

Both mu- and delta-opioid agonists selectively inhibit nociception but have little effect on other sensory modalities. Voltage-activated Ca(2+) channels in the primary sensory neurons are important for the regulation of nociceptive transmission. In this study, we determined the effect of delta-opioid agonists on voltage-activated Ca(2+) channel currents (I(Ca)) in small-diameter rat dorsal root ganglion (DRG) neurons that do and do not bind isolectin B(4) (IB(4)). The delta-opioid agonists [d-Pen(2),d-Pen(5)]-enkephalin (DPDPE) and deltorphin II produced a greater inhibition of high voltage-activated I(Ca) in IB(4)-negative than IB(4)-positive neurons. Furthermore, DPDPE produced a greater inhibition of N-, P/Q-, and L-type I(Ca) in IB(4)-negative than IB(4)-positive neurons. However, DPDPE had no significant effect on the R-type I(Ca) in either type of cells. We were surprised to find that DPDPE failed to inhibit either the T-type or high voltage-activated I(Ca) in all the DRG neurons with T-type I(Ca). Double immunofluorescence labeling showed that the majority of the delta-opioid receptor-immunoreactive DRG neurons had IB(4) labeling, while all DRG neurons immunoreactive to delta-opioid receptors exhibited Cav(3.2) immunoreactivity. Additionally, DPDPE significantly inhibited high voltage-activated I(Ca) in Tyrode's or N-methyl-d-glucamine solution but not in tetraethylammonium solution. This study provides new information that delta-opioid agonists have a distinct effect on voltage-activated Ca(2+) channels in different phenotypes of primary sensory neurons. High voltage-activated Ca(2+) channels are more sensitive to inhibition by delta-opioid agonists in IB(4)-negative than IB(4)-positive neurons, and this opioid effect is restricted to DRG neurons devoid of functional T-type Ca(2+) currents.     

Elementary currents through Ca2+ channels in Guinea pig myocytes

Elementary Ca2+ and Ba2+ currents were recorded from cell-attached membrane patches of ventricular myocytes from adult guinea pig hearts using the improved patch-clamp technique (Hamill et al. 1981). High concentrations of Ba2+ or Ca2+ (50 or 90 mM) were used in the pipettes to increase the signal-to-noise ratio. All data were derived from elementary current analyses in patches containing only one channel. 1) In response to voltage steps, channel openings occurred singly or in bursts of closely spaced unitary current pulses separated by wider shut intervals. During depolarizations of small amplitude from the resting potential, channel openings occurred almost randomly, whereas during larger depolarizations the events were grouped preferentially at the beginning. 2) Channel openings became more probable with increased depolarization; simultaneously, unitary current amplitudes declined in an ohmic manner. Elementary current amplitudes were slightly larger, when 50 mM Ba2+ replaced 50 mM Ca2+ in the pipettes (slope conductances 9 and 10 pS, respectively), but more than doubled, when Ba2+ was increased to 90 mM (slope conductance 18 pS). Clear outward currents through Ca2+ channels were not observed under these conditions. 3) Peak amplitudes of reconstructed mean currents doubled when 50 mM Ba2+ replaced 50 mM Ca2+ and were larger still when 90 mM Ba2+ was used in the pipettes. The current-voltage relations of the reconstructed mean currents showed a positive shift along the voltage axis as Ba2+ was increased or substituted equimolarly by Ca2+. correspondingly, the open state probability-voltage relations (activation curves) showed a parallel shift as Ba2+ was increased, which was less pronounced when Ba2+ was replaced equimolarly by Ca2+. 4) Determination of Ca2+ channel inactivation using 90 mM Ba2+ in the pipettes indicated an overlap with channel activation in a limited voltage range, resulting in a steady-state "window" current. Inactivation can occur without divalent cation influx. 5) Formation of an inside-out patch resulted in a fast rundown of elementary Ca2+ channel currents. 6) Channel openings were often grouped in bursts. The lifetimes of the open state, the bursts, and the closed states were estimated for Ba2+ and Ca2+ as permeating ions. At least two exponentials were needed to fit the histogram of the lifetimes of all closed states. The lifetimes of the individual openings and bursts were mono-exponentially distributed. The kinetics of the Ca+ channel depended on the voltage and the permeating ion. During +30 mV depolarizations, no significant effect on the permeating ion on channel gating could be detected.(ABSTRACT TRUNCATED AT 400 WORDS)     

Axotomy- and autotomy-induced changes in Ca2+ and K+ channel currents of rat dorsal root ganglion neurons

Sciatic nerve section (axotomy) increases the excitability of rat dorsal root ganglion (DRG) neurons. The changes in Ca2+ currents, K+ currents, Ca2+ sensitive K+ current, and hyperpolarization-activated cation current (I(H)) that may be associated with this effect were examined by whole cell recording. Axotomy affected the same conductances in all types of DRG neuron. In general, the largest changes were seen in "small" cells and the smallest changes were seen in "large" cells. High-voltage-activated Ca2+ channel current (HVA-I(Ba)) was reduced by axotomy. Although currents recorded in axotomized neurons exhibited increased inactivation, this did not account for all of the reduction in HVA-I(Ba). Activation kinetics were unchanged, and experiments with nifedipine and/or omega-conotoxin GVIA showed that there was no change in the percentage contribution of L-type, N-type, or "other" HVA-I(Ba) to the total current after axotomy. T-type (low-voltage-activated) I(Ba) was not affected by axotomy. Ca2+ sensitive K+ conductance (g(K,Ca)) appeared to be reduced, but when voltage protocols were adjusted to elicit similar amounts of Ca2+ influx into control and axotomized cells, I(K,Ca)(s) were unchanged. After axotomy, Cd2+ insensitive, steady-state K+ channel current, which primarily comprised delayed rectifier K+ current (I(K)), was reduced by about 60% in small, medium, and large cells. These data suggest that axotomy-induced increases in excitability are associated with decreases in I(K) and/or decreases in g(K,Ca) that are secondary to decreased Ca2+ influx. Because I(H) was reduced by axotomy, changes in this current do not contribute to increased excitability. The amplitude and inactivation of I(Ba) in all cell types was changed more profoundly in animals that exhibited self-mutilatory behavior (autotomy). The onset of this behavior corresponded with significant reduction in I(Ba) of large neurons. This finding supports the hypothesis that autotomy, that may be related to human neuropathic pain, is associated with changes in the properties of large myelinated sensory neurons.     

ATP suppresses activity of Ca2+ -activated K+ channels by Ca2+ chelation

Ca²⁺-activated maxi K⁺ channels were studied in inside-out patches from smooth muscle cells isolated from either porcine coronary arteries or guinea-pig urinary bladder. As described by Groschner et al. (Pflügers Arch 417:517, 1990), channel activity (NP _o) was stimulated by 3 M [Ca²⁺]_c (1 mM Ca-EGTA adjusted to a calculated pCa of 5.5) and was suppressed by the addition of 1 mM Na₂ATP. The following results suggest that suppression of NP _o by Na₂ATP is due to Ca²⁺ chelation and hence reduction of [Ca²⁺]_c and reduced Ca²⁺ activation of the channel. The effect was absent when Mg ATP was used instead of Na₂ATP. The effect was diminished by increasing the [EGTA] from 1 to 10 mM. The effect was absent when [Ca²⁺]_c was buffered with 10 mM HDTA (apparent pK _Ca 5.58) instead of EGTA (pK _Ca 6.8). A Ca²⁺-sensitive electrode system indicated that 1 mM Na₂ATP reduced [Ca²⁺]_c in 1 mM Ca-EGTA from 3 M to 1.4 M. Na₂ATP, Na₂GTP, Li₄AMP-PNP and NaADP reduced measured [Ca²⁺]_c in parallel with their suppression of NP _o. After the Na₂ATP-induced reduction of [Ca²⁺]_c was re-adjusted by adding either CaCl₂ or MgCl₂, the effect of Na₂ATP on NP _o disappeared. In vivo, intracellular [Mg²⁺] exceeds free [ATP^4–], hence ATP modulation of maxi K⁺ channels due to Ca²⁺ chelation is without biological relevance.