Large-conductance Ca2+-activated potassium channels in secretory neurons.

Large-conductance Ca2+-activated K+ channels (BK) are believed to underlie interburst intervals and contribute to the control of hormone release in several secretory cells. In crustacean neurosecretory cells, Ca2+ entry associated with electrical activity could act as a modulator of membrane K+ conductance. Therefore we studied the contribution of BK channels to the macroscopic outward current in the X-organ of crayfish, and their participation in electrophysiological activity, as well as their sensitivity toward intracellular Ca2+, ATP, and voltage, by using the patch-clamp technique. The BK channels had a conductance of 223 pS and rectified inwardly in symmetrical K+. These channels were highly selective to K+ ions; potassium permeability (PK) value was 2.3 x 10(-13) cm(3) s(-1). The BK channels were sensitive to internal Ca2+ concentration, voltage dependent, and activated by intracellular MgATP. Voltage sensitivity (k) was approximately 13 mV, and the half-activation membrane potentials depended on the internal Ca2+ concentration. Calcium ions (0.3-3 microM) applied to the internal membrane surface caused an enhancement of the channel activity. This activation of BK channels by internal calcium had a KD(0) of 0.22 microM and was probably due to the binding of only one or two Ca2+ ions to the channel. Addition of MgATP (0.01-3 mM) to the internal solution increased steady state-open probability. The dissociation constant for MgATP (KD) was 119 microM, and the Hill coefficient (h) was 0.6, according to the Hill analysis. Ca2+-activated K+ currents recorded from whole cells were suppressed by either adding Cd2+ (0.4 mM) or removing Ca2+ ions from the external solution. TEA (1 mM) or charybdotoxin (100 nM) blocked these currents. Our results showed that both BK and K(ATP) channels are present in the same cell. Even when BK and K(ATP) channels were voltage dependent and modulated by internal Ca2+ and ATP, the profile of sensitivity was quite different for each kind of channel. It is tempting to suggest that BK and KATP channels contribute independently to the regulation of spontaneous discharge patterns in crayfish neurosecretory cells.     

A long lasting Ca2+ -activated outward current in guinea-pig atrial myocytes

Among other characteristics, the steady-state current-voltage relationship of patch-clamped single atrial myocytes from guinea-pig hearts is defined by an outward current hump in the potential region -15 to +40 mV. This hump was reversibly suppressed by Co2+ (3 mM) or nitrendipine (5 microM) and enhanced by Bay K 8644 (5 microM). The maintained outward current component suppressed by Co2+ extended between -15.2 +/- 1.9 mV and +39.5 +/- 1.7 mV (mean +/- SEM of 14 cells) and has an amplitude of 95.7 +/- 9.4 pA at +10 mV. In isochronal I-V curves, the hump was already visible at 400 ms with essentially the same amplitude as at 1500 ms. The Co2+-sensitive outward current underlying the hump was poorly time-dependent during 1.5 s voltage pulses but slowly relaxed upon repolarization. Tail currents reversed near the K+ equilibrium potential under our experimental conditions. The current hump of the steady-state I-V curve was also abolished by caffeine (10 mM) or ryanodine (3 microM), both drugs that interfere with sarcoplasmic reticulum function. Apamin (1 microM) or quinine (100 microM) but not TEA (5-50 mM) markedly reduced its amplitude. However, at similar concentrations as required to inhibit the hump, both apamin and quinine appeared to be poorly specific for Ca2+-activated K+ currents in heart cells since they also inhibited the L-Type Ca2+ current. It is concluded that a long lasting Ca2+-activated outward current, probably mainly carried by K+ ions but not sensitive to TEA, exists in atrial myocytes which is responsible for the current hump of the background I-V curve.     

Permeability characteristics of monovalent cations in atrial myocytes of the rat heart

We investigated the permeability of Cs+ and Na+ through various ion channels in rat atrial myocytes using the whole-cell voltage-clamp technique. With isotonic CsCl (140 mM) on both sides of the membrane and nominally [Ca2+]o-free conditions, depolarising clamp pulses induced an increase of outward currents which showed a biphasic time course. Repolarisation to the holding potential induced inward tail currents. With isotonic NaCl, depolarisation also induced outward currents which showed a monotonic decay, but inward tail currents were not observed. Both in NaCl and CsCl, currents were hardly affected by TEA (10 mM), 4-AP (5 mM) and DIDS (100 microM). Nicardipine (1 M) almost completely blocked time-dependent outward currents in isotonic NaCl solution, leaving only time-independent currents which showed linear I-V relationship. In isotonic CsCl conditions, nicardipine blocked outward current considerably, but there still remained time-dependent outward currents and inward tail currents. Addition of E-4031 (2-20 M) which is known as a specific blocker of the rapidly activating delayed rectifier K+ current (IKr) completely blocked these time-dependent outward and inward currents, leaving only a time-independent current. Time-independent currents recorded in the presence of nicardipine and E-4031 were inhibited by GdCl3, which is known to block non-selective cation (NSC) currents. From these results, it was suggested that NSC current in atrial myocytes can be investigated in isotonic Cs+ or Na+ solution in the presence of Ca2+ channel and IKr blockers.     

Number of K(Ca) channels underlying spontaneous miniature outward currents (SMOCs) in mudpuppy cardiac neurons

Spontaneous miniature outward currents (SMOCs) in parasympathetic neurons from mudpuppy cardiac ganglia are caused by activation of TEA- and iberiotoxin-sensitive, Ca(2+)-dependent K(+) (BK) channels. Previously we reported that SMOCs are activated by Ca(2+)-induced Ca(2+) release (CICR) from caffeine- and ryanodine-sensitive intracellular Ca(2+) stores. In the present study, we analyzed the single channel currents that contribute to SMOC generation in mudpuppy cardiac neurons. The slope conductance of BK channels, determined from the I-V relationship of single-channel currents recorded with cell-attached patches in physiological K(+) concentrations, was 84 pS. The evidence supporting the identity of this channel as the channel involved in SMOC generation was its sensitivity to internal Ca(2+), external TEA, and caffeine. In cell-attached patch recordings, 166 microM TEA applied in the pipette reduced single-channel current amplitude by 32%, and bath-applied caffeine increased BK channel activity. The ratio between the averaged SMOC amplitude and the single-channel current amplitude was used to estimate the average number of channels involved in SMOC generation. The estimated number of channels involved in generation of an averaged SMOC ranged from 18 to 23 channels. We also determined that the Po of the BK channels at the peak of a SMOC remains constant at voltages more positive than -20 mV, suggesting that the transient rise in intracellular Ca(2+) from ryanodine-sensitive intracellular stores in the vicinity of the BK channel reached concentrations most likely exceeding 40 microM.     

BK channels in human glioma cells

Ion channels in inexcitable cells are involved in proliferation and volume regulation. Glioma cells robustly proliferate and undergo shape and volume changes during invasive migration. We investigated ion channel expression in two human glioma cell lines (D54MG and STTG-1). With low [Ca2+]i, both cell types displayed voltage-dependent currents that activated at positive voltages (more than +50 mV). Current density was sensitive to intracellular cation replacement with the following rank order; K+ > Cs+ approximately = Li+ > Na+. Currents were >80% inhibited by iberiotoxin (33 nM), charybdotoxin (50 nM), quinine (1 mM), tetrandrine (30 microM), and tetraethylammonium ion (TEA; 1 mM). Extracellular phloretin (100 microM), an activator of BK(Ca2+) channels, and elevated intracellular Ca2+ negatively shifted the I-V curve of whole cell currents. With 0, 0.1, and 1 microM [Ca2+]i, the half-maximal voltages, V(0.5), for whole cell current activation were +150, +65, and +12 mV, respectively. Elevating [K+]o potentiated whole cell currents in a fashion proportional to the square-root of [K+]o. Recording from cell-attached patches revealed large conductance channels (150-200 pS) with similar voltage dependence and activation kinetics as whole cell currents. These data indicate that human glioma cells express large-conductance, Ca2+ activated K+ (BK) channels. In amphotericin-perforated patches bradykinin (1 microM) activated TEA-sensitive currents that were abolished by preincubation with bis-(o-aminophenoxy)-N,N,N',N'-tetraacetic acid-AM (BAPTA-AM). The BK channels described here may influence the responses of glioma cells to stimuli that increase [Ca2+]i.     

Large-conductance calcium-activated potassium channels in neonatal rat intracardiac ganglion neurons

The properties of single Ca2+-activated K+ (BK) channels in neonatal rat intracardiac neurons were investigated using the patch-clamp recording technique. In symmetrical 140 mM K+, the single-channel slope conductance was linear in the voltage range -60/+60 mV, and was 207+/-19 pS. Na+ ions were not measurably permeant through the open channel. Channel activity increased with the cytoplasmic free Ca2+ concentration ([Ca2+]i) with a Hill plot giving a half-saturating [Ca2+] (K0.5) of 1.35 microM and slope of approximately equals 3. The BK channel was inhibited reversibly by external tetraethylammonium (TEA) ions, charybdotoxin, and quinine and was resistant to block by 4-aminopyridine and apamin. Ionomycin (1-10 microM) increased BK channel activity in the cell-attached recording configuration. The resting activity was consistent with a [Ca2+]i <100 nM and the increased channel activity evoked by ionomycin was consistent with a rise in [Ca2+]i to > or =0.3 microM. TEA (0.2-1 mM) increased the action potential duration approximately equals 1.5-fold and reduced the amplitude and duration of the afterhyperpolarization (AHP) by 26%. Charybdotoxin (100 nM) did not significantly alter the action potential duration or AHP amplitude but reduced the AHP duration by approximately equals 40%. Taken together, these data indicate that BK channel activation contributes to the action potential and AHP duration in rat intracardiac neurons.     

Block of potassium outward currents in the crayfish stretch receptor neurons by 4-aminopyridine, tetraethylammonium chloride and some other chemical substances.

The effects of 4-aminopyridine (4-AP) and tetraethylammonium (TEA) on the outward potassium currents in the rapidly and slowly adapting stretch receptor neurons (SRNs) of the crayfish (Pacifastacus leniusculus) were studied using a two micro-electrode voltage-clamp technique. The leakage current was not affected by either 4-AP or TEA. External 4-AP blocked the peak outward current in a dose-dependent manner (1:1 stoichiometry) with an apparent dissociation constant (Kd) of 2.3 +/- 0.2 mM (mean +/- SEM) in the slowly and 1.4 +/- 0.2 mM in the rapidly adapting SRN, the block being voltage dependent. External application of TEA resulted in a block of the steady state current enhancing the transient characteristics of the current response. The block appeared to deviate from a 1:1 stoichiometry and the apparent Kd for TEA was 9.6 +/- 3.4 mM with a cooperativity factor n = 0.43 +/- 0.03 in the slowly adapting SRN and 34.5 +/- 9.2 mM and 0.37 +/- 0.03 respectively in the rapidly adapting SRN. Low Ca2+, apamin and charybdotoxin, which are known to block Ca(2+)-dependent K-currents, had no effects on the outward current as was also the case with catechol. It is concluded that the different effects of TEA and 4-AP on the outward current in the two types of SRNs can be explained by the presence of at least two, probably heteromultimeric, channel populations having similar sensitivity to 4-AP but different sensitivity to TEA. One channel has a high affinity (Kd = 0.8-1.6 mM) for TEA and the other a low affinity (Kd = 173-213 mM) for TEA. The low-affinity channel seems to dominate in the slowly adapting SRN while both channels are equally common in the rapidly adapting SRN. Further, the present results do not support the existence of a macroscopic Ca(2+)-dependent K+ current in the SRNs.     

K+ currents generated by NMDA receptor activation in rat hippocampal pyramidal neurons

Long lasting outward currents mediated by Ca2+-activated K+ channels can be induced by Ca2+ influx through N-methyl-D-aspartate (NMDA)-receptor channels in voltage-clamped hippocampal pyramidal neurons. Using specific inhibitors, we have attempted to identify the channels that underlie these outward currents. At a holding potential of -50 mV, applications of 1 mM NMDA to the soma of cultured hippocampal pyramidal neurons induced the expected inward currents. In 44% of cells tested, these were followed by outward currents (average amplitude 60 +/- 7 pA) that peaked 2.5 s after the initiation of the inward NMDA currents and decayed with a time constant of 1.4 s. In 43% of those cells exhibiting an outward current, SK channel inhibitors, UCL 1848 (100 nM) and apamin (100 nM) abolished the outward current. In the remainder of the cells, the outward currents were either insensitive or only partly inhibited (44 +/- 4%) by 100 nM UCL 1848. In these cells, the outward currents were reduced by the slow afterhyperpolarization (sAHP) inhibitors, muscarine (3 microM; 43 +/- 9%), UCL 1880 (3 microM; 34 +/- 10%), and UCL 2027 (3 microM; 57 +/- 6%). Neither the BK channel inhibitor, charybdotoxin (100 nM), nor the Na+/K+ ATPase inhibitor, ouabain (100 microM), reduced these outward currents. Irrespective of the pharmacology, the time course of the outward current did not differ. Interestingly, no correlation was observed between the presence of a slow apamin-insensitive afterhyperpolarization and an outward current insensitive to SK channel blockers following NMDA-receptor activation. It is concluded that an NMDA-mediated rise in [Ca2+]i can result in the activation of apamin-sensitive SK channels and of the channels that underlie the sAHP. The activation of these channels may, however, depend on their location relative to NMDA receptors as well as on the spatial Ca2+ buffering within individual neurons.     

Muscarine induces two distinct current responses in adrenal chromaffin cells of the guinea-pig

Muscarine-induced membrane responses were studied in dissociated chromaffin cells of the guinea-pig adrenal medulla, using the whole-cell version of the patch-clamp technique. Bath application of muscarine (1-10 microM) produced two distinct current responses at a holding potential of -40 mV. One is an inward current associated with an increase in current noise. This current response was sustained during stimulation and had a reversal potential of 4.5 +/- 3.4 mV (n = 6) with a negative slope conductance below about -30 mV in 12.5 mM K(+)-containing perfusate. The other is a transient outward current. This was evoked at membrane potentials more positive than -60 mV and completely suppressed by addition of 2 mM TEA to the bath solution, suggesting a possible involvement of the Ca2(+)-dependent K+ channel. Generation of the outward current response was suppressed for at least 60-90 s following 25 s muscarinic stimulation and was facilitated by activation of the nicotinic receptor. The maximum inward current seemed to be produced by 3 microM, whereas the threshold concentration required for generation of the outward current was somewhere between 3 and 10 microM. The outward current was evoked less often in cells treated with 2% collagenase for 1 h than in those treated with 0.2% for 30 min. The results suggest that guinea-pig chromaffin cells have two muscarinic receptors: one is coupled with a cation nonselective channel and the other may be related to a Ca2(+)-dependent K+ channel.     

Properties of large conductance calcium-activated potassium channels in pyramidal neurons from the hippocampal CA1 region of adult rats

The properties of large-conductance Ca(2+)-activated K(+) (BK(Ca)) channels were studied in rat hippocampal CA1 pyramidal neurons by using the patch-clamp technique in the excised-inside-out-patch configuration. The lowest [Ca(2+)](i) in which BK(Ca) channel activities were observed was 0.01 microM with the membrane potential of +20 mV and the [Ca(2+)](i) at which P(O) of the channel is equal to 0.5 was 2 microM. The unitary conductance of the single BK(Ca) channel was 245.4 pS with symmetrical 140 mM K(+) on both sides of the excised membrane. With a fixed [Ca(2+)](i) of 2 microM, P(O) increased e-fold with a 17.0 mV positive change in the membrane potential. Two exponentials, with time constants of 2.8 ms and 19.2 ms at the membrane potential of +120 mV with 2 microM [Ca(2+)](i), were required to describe the observed open time distribution of BK(Ca) channel, suggesting the existence of two distinct open channel states with apparently normal conductance. A BK(Ca) channel occasionally entered an apparent third open channel state with the single channel current amplitude about 45% of the normal amplitude. The properties of BK(Ca) channel, which were found in this study to be more steeply dependent on voltage and more sensitive to [Ca(2+)](i) in adult hippocampal neurons than in cultured or immature hippocampal neurons, may be responsible for the shortened duration of action potential in hippocampal CA1 pyramidal neurons of adult rat.     

Single-channel currents through transient-receptor-potential-like (TRPL) channels

Single-channel current recordings were used to examine the properties and modulation of Drosophila transient-receptor-potential-like (TRPL) channels transiently expressed in HEK and COS cells. Recombinant TRPL channels were constitutively active and characterized by a conductance of 104 pS in on-cell membrane patches with 115 mM Na+ and 2 mM Mg2+ in the pipette solution. In inside-out membrane patches exposed to 115 mM Na+ plus 2 mM Mg2+, 115 mM Na+ plus 10 mM Mg2+, 90 mM Ca2+ and 90 mM Ba2+ on both sides, the single-channel conductances were 72 pS, 36 pS, 48 pS and 46 pS, respectively. The single TRPL channel currents reversed close to 0 mV and displayed a linear voltage dependence between -120 mV and +120 mV. Removal of cations from the pipette and bath solutions abolished inward and outward currents, respectively. Similar currents were not observed in mock-transfected and native cells. The opening probability of TRPL channels increased by depolarizing the membrane and accounted for the outward rectification of whole-cell TRPL currents. In on-cell membrane patches, the TRPL channel activity was enhanced by cell dialysis of 300 microM guanosine 5'-O-(3-thiotriphosphate) (GTP[gamma-S]) and by a rise of intracellular Ca2+ (>2 microM). Constitutively active TRPL channels depolarized the host cells to -10 mV and the membrane potential was restored by cell dialysis with 10 mM BAPTA. The present results suggest that TRPL forms non-selective cationic channels modulated by intracellular Ca2+ in mammalian cells.     

BK channel activation by brief depolarizations requires Ca2+ influx through L- and Q-type Ca2+ channels in rat chromaffin cells.

BK channel activation by brief depolarizations requires Ca2+ influx through L- and Q-type Ca2+ channels in rat chromaffin cells. Ca2+- and voltage-dependent BK-type K+ channels contribute to action potential repolarization in rat adrenal chromaffin cells. Here we characterize the Ca2+ currents expressed in these cells and identify the Ca2+ channel subtypes that gate the activation of BK channels during Ca2+ influx. Selective Ca2+ channel antagonists indicate the presence of at least four types of high-voltage-gated Ca2+ channels: L-, N-, P, and Q type. Mean amplitudes of the L-, N-, P-, and Q-type Ca2+ currents were 33, 21, 12, and 24% of the total Ca2+ current, respectively. Five-millisecond Ca2+ influx steps to 0 mV were employed to assay the contribution of Ca2+ influx through these Ca2+ channels to the activation of BK current. Blockade of L-type Ca2+ channels by 5 microM nifedipine or Q-type Ca2+ channels by 2 microM Aga IVA reduced BK current activation by 77 and 42%, respectively. In contrast, blockade of N-type Ca2+ channels by brief applications of 1-2 microM CnTC MVIIC or P-type Ca2+ channels by 50-100 nM Aga IVA reduced BK current activation by only 11 and 12%, respectively. Selective blockade of L- and Q-type Ca2+ channels also eliminated activation of BK current during action potentials, whereas almost no effects were seen by the selective blockade of N- or P-type Ca2+ channels. Finally, the L-type Ca2+ channel agonist Bay K 8644 promoted activation of BK current by brief Ca2+ influx steps by more than twofold. These data show that, despite the presence of at least four types of Ca2+ channels in rat chromaffin cells, BK channel activation in rat chromaffin cells is predominantly coupled to Ca2+ influx through L- and Q-type Ca2+ channels.     

Voltage-gated potassium currents in rat vas deferens smooth muscle cells

Voltage-gated components of the outward current in single smooth muscle cells isolated from the epididymal part of the rat vas deferens were studied using amphotericin B perforated patch-clamp techniques. The complex kinetics of the net outward current elicited by positive voltage steps from -80 mV to +40 mV suggested the presence of several components. Bath application of 200 nM charybdotoxin, a potent blocker of large-conductance, Ca(2+)-dependent K(+) channels (BK(Ca)), reduced the current amplitude significantly. When BK(Ca) channels were suppressed, fast-inactivating (I(K,f)) and delayed rectifying (I(K,dr)) components of the outward current were identified. I(K,f) was characterized by fast kinetics of current decay, negative steady-state activation and inactivation dependencies and sensitivity to 4-aminopyridine with an apparent K(d) of 0.32 mM, properties similar to those of the A-type K(+) current. In contrast, I(K,dr) activated and inactivated at more positive potentials. The time constant of activation of I(K,dr) was voltage dependent with an e-fold decrease per 21 mV depolarization. I(K,dr) was inhibited by clofilium, a blocker of voltage-gated K(+) channels, with an IC(50) of 12 micro M and was not blocked by 5 mM 4-aminopyridine. The possible significance of the voltage-gated currents is discussed.     

Three pharmacologically distinct potassium channels in molluscan neurones.

1. Potassium currents were studied under voltage-clamp conditions in nerve cell bodies of the nudibranch Tritonia diomedia. 2. Potassium currents could be separated into three distinct components on the basis of their sensitivity to 4-aminopyridine (4-AP), tetraethyl-ammonium (TEA) and to Co2+ and Mn2+ ions. 3. A transient potassium current, similar to the fast outward current described by Connor & Stevens (1971b) and Neher (1971), was blocked by externally applied 4-AP but was much less sensitive to TEA or to Co2+ or Mn2+. A single 4-AP ion binds each receptor with an apparent dissociation constant of 1-5 X 10(-3) M. 4-AP decreases the rates of activation and inactivation and reduces the maximum conductance of transient current channels. 4. Delayed outward current was not effected by 4-AP at concentrations which blocked the transient current, but it could be divided into two components by external application of TEA and Co2+ or Mn2+. 5. A voltage-dependent component of delayed current, termed K-current, was blocked by TEA. Each K-current receptor binds a single TEA ion with an apparent dissociation constant of 8 X 10(-3) M. Co2+ and Mn2+ have little or no effect on K-current. 6. A second component of delayed outward current, termed C-current, depends on Ca2+ entry for its activation. It is similar to the Ca2+ dependent potassium current reported by Meech & Stranden (1975) in Helix cells. C-current is essentially blocked by 30 mM external Co2+ or Mn2+. It is little affected by TEA, however, being reduced by about 20% at a TEA concentration of 100 mM. 7. It is concluded that three sets of potassium selective channels contribute to the outward current and that these channels can be separated pharmacologically.     

Identification of Calcium-Activated Potassium Channels in Cultured Equine Sweat Gland Epithelial Cells

The patch-clamp recording technique was used to examine the properties of the K+ channels in cultured equine sweat gland epithelial cells. With symmetric K+ solutions (140 mM), a single population of K+ channels was identified with a slope conductance of 187 pS and a reversal potential of around 0 mV. The channel was selective for K+ over Na+. Channel activity was increased by membrane depolarization. A 10-fold increase in [Ca2+]i produced an approximate 60 mV negative shift in the open state probability (Popen)-voltage curve. Externally applied tetraethylammonium ions (TEA+) caused a rapid and flickery block of the channel and reduced the unitary current amplitude. TEA+ bound to the blocking site with stoichiometry of 1:1 and with a dissociation constant (Kd) of 186 +/- 27 microM at +40 mV. A weak voltage dependence of Kd was observed. Iberiotoxin (100 nM) reduced Popen but had no effect on single-channel conductance. Neither glibenclamide (10 microM) nor intracellular adenosine 5'-triphosphate (ATP, 1 mM) altered channel activity. In addition, ATP, when applied extracellularly, transiently activated the channel by increasing Popen. Channel activity was low around the resting membrane potential in the intact epithelia, indicating that these channels might not contribute to the resting K+ conductance. However, the channel could be activated in a regulated manner. The K+ channels may play a role in transepithelial fluid secretion in sweat gland.     

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.     

Single voltage-dependent potassium channels in cultured rat hippocampal neurons

Single-channel recordings using the gigohm seal patch-clamp technique were carried out on the somatic membranes of dissociated embryonic rat hippocampal neurons grown in cell culture. The recording medium contained tetrodotoxin to block the voltage-dependent Na+ conductance and Cd2+ to block Ca2+ and Ca2+-activated conductances. In the cell-attached configuration, depolarizing voltage steps activated outward directed single-channel currents with conductance 15-20 pS. The channel openings exhibited a moderate degree of flickering. The mean burst lifetimes ranged from 5 to 13 ms with a tendency to increase slightly at more depolarized potentials (T = 21-25 degrees C). Reversal potential measurements using excised membrane patches indicated that the channels behaved as expected of a K+-selective membrane pore. Channel opening occurred in Ca2+-free EGTA-containing solutions but was never observed in the presence of tetraethylammonium (TEA; 20 mM). The frequency of channel opening increased as the membrane was depolarized by up to 50 mV from resting potential; the fraction of time spent in the open state during the first 300 ms following a step depolarization increased e-fold for a 8-25 mV change in potential. First-latency histograms and simulations of the macroscopic current based on channel data obtained during repeated depolarizing voltage steps indicated that the probability of the channel being in the open state increases gradually with time after a step depolarization. During repeated depolarizing steps the channels appeared to randomly enter and exit a long-lived inactive state. It is concluded that these channels may underly the slowly activating, very slowly inactivating, TEA-sensitive voltage-dependent K+ current (IK) in cultured hippocampal neurons.     

Roles of Ca2+ influx through ATP-activated channels in catecholamine release from pheochromocytoma PC12 cells.

1. Extracellular ATP evokes catecholamine release concomitant with depolarization in pheochromocytoma PC12 cells. Roles of Ca2+ influx through ATP-activated channels during the catecholamine release were investigated. 2. Norepinephrine or dopamine release induced by > or = 100-microM concentrations of ATP was insensitive to 300 microM Cd2+, whereas the release induced by increasing extracellular KCl (50-150 mM) was completely blocked by this concentration of Cd2+. 3. ATP (100 microM) increased the intracellular free Ca2+ concentration measured with fura-2. The increase was not affected by 300 microM Cd2+ or 100 microM nicardipine, suggesting that Ca2+ influx through ATP-activated channels but not through voltage-gated Ca2+ channels contributes to the ATP-evoked catecholamine release. 4. Inward currents permeating through voltage-gated Ca2+ channels were measured using the whole-cell voltage clamp. In the presence of 10 microM ATP, a concentration that induces an ATP-activated channel-mediated current equivalent to that induced by 100 microM ATP during the depolarization in "non-voltage clamped" cells, the Ca2+ current activated by a voltage step to +10 mV was reduced. The reduction in the Ca2+ channel-mediated current was not observed when the extracellular Ca2+ was replaced with Ba2+. 5. The ATP (100 microM)-evoked dopamine release was inhibited by 300 microM Cd2+ when measured with extracellular Ba2+ instead of Ca2+. This effect of Ba2+ may not be related to K+ channel-blocking activity, because the ATP-evoked dopamine release obtained with 5 mM tetraethylammonium (TEA) was not inhibited by Cd2+.(ABSTRACT TRUNCATED AT 250 WORDS)     

Patch-clamp study of the calcium-dependent chloride current in AtT-20 pituitary cells

1. Voltage-clamp recordings were made from cultured AtT-20 pituitary cells using the whole-cell patch-clamp technique. Cells were perfused internally with Cs+ to block K+ currents and bathed externally with either 1 microM tetrodotoxin or with tetraethylammonium (TEA) as a Na+ substitute to block voltage-activated Na+ currents. 2. Depolarizing voltage steps from a holding potential of -80 mV to potentials positive to -30 mV evoked two currents: a fast inward current that activated between -30 and +70 mV and a slowly activating current (designated "slow step current") that was inward between -30 and near 0 mV (the Cl- equilibrium potential) and outward positive to about 0 mV. Repolarization to -80 mV revealed a slowly decaying, inward tail current, whose magnitude with respect to step potential closely matched the current-voltage relationship of the voltage-activated Ca2+ current. 3. Activation of the fast inward current, slow step current, and tail current, was prevented by extracellular application of Cd2+ or removal of extracellular Ca2+. Replacement of extracellular Ca2+ with Ba2+ potentiated the fast inward current but blocked the slow step and tail currents. Intracellular perfusion with greater than 1 mM of the Ca2+ chelators ethyleneglycol-bis(beta-aminoethylether)-N,N'-tetraacetic acid (EGTA) or [1,2-bis(2)aminophenoxy]ethane N,N,N',N'-tetraacetic acid (BAPTA) prevented activation of the slow step and tail currents, but not the fast inward current. 4. The reversal potential of the slow inward current was sensitive to changes in the Cl- equilibrium potential but not to substitution of TEA for Na+. The slow step current, but not the fast inward current, was partially blocked by the Cl- channel blocker, 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid. 5. These data indicate that both the slow inward tail current and the slowly activating, reversible step current were a Ca2+-dependent Cl- current, similar to that described in other neuronal and nonneuronal cell types. The fast inward current was a voltage-activated Ca2+ current, described previously in these and other cells. 6. In the absence of intracellular EGTA, the tail current decayed with complex kinetics, its time course apparently dependent on the magnitude of the voltage-activated Ca2+ current. In the presence of 200 microM intracellular EGTA, the tail current decayed significantly faster and often decayed exponentially.     

Calcium-dependent potassium currents in neurons from cat sensorimotor cortex.

1. Ca(2+)-dependent K+ currents were studied in large pyramidal neurons (Betz cells) from layer V of cat sensorimotor cortex by use of an in vitro brain slice and single microelectrode voltage clamp. The Ca(2+)-dependent outward current was taken as the difference current obtained before and after blockade of Ca2+ influx. During step depolarizations in the presence of tetrodotoxin (TTX), this current exhibited a fast onset of variable amplitude and a prominent slowly developing component. 2. The Ca(2+)-dependent outward current first appeared when membrane potential was stepped positive to -40 mV. Downsteps from a holding potential of -40 mV revealed little or no time-, voltage-, or Ca(2+)-dependent current. When membrane potential was stepped positive to -40 mV, a prolonged Ca(2+)-dependent outward tail current followed repolarization. The decay of this tail current at -40 mV was best described by a single exponential function having a time constant of 275 +/- 75 (SD) ms. The tail current reversed at 96 +/- 5 mV in 3 mM extracellular K+ concentration ([K+]o) and at more positive potentials when [K+]o was raised, suggesting that it was carried predominantly by K+. 3. The Ca(2+)-dependent K+ current consisted of two pharmacologically separable components. The slowly developing current was insensitive to 1 mM tetraethylammonium (TEA), but a substantial portion was reduced by 100 nM apamin. Most of the remaining current was blocked by the addition of isoproterenol (20-50 microM) or muscarine (10-20 microM). 4. The time courses of the apamin- and transmitter-sensitive components were similar when activated by step depolarizations in voltage clamp, but they were quite different when activated by a train of action potentials. Applying the voltage clamp at the end of a train of 90 spikes (evoked at 100-200 Hz) resulted in an Ca(2+)-dependent K+ current with a prominent rapidly decaying portion (time constant approximately 50 ms at -64 mV) and a smaller slowly decaying portion (time constant approximately 500 ms at -64 mV). The rapidly decaying portion was blocked by apamin (50-200 nM), and the slowly decaying portion was blocked by isoproterenol (20-50 microM). 5. When recorded with microelectrodes containing 2 mM dimethyl-bis-(o-aminophenoxy)-N,N,N',N'-tetraacetic acid (dimethyl-BAPTA), which causes prolonged afterhyperpolarizations, the Ca(2+)-dependent K+ current evoked by step depolarizations had an extremely slow onset and decay. The current recorded after a train of evoked spikes had a similar slow decay.(ABSTRACT TRUNCATED AT 400 WORDS)