Interaction of phencyclidine with voltage-dependent potassium channels in cultured rat hippocampal neurons: comparison with block of the NMDA receptor-ionophore complex

Whole-cell voltage-clamp recording techniques were used to investigate the blockade of voltage-dependent K+ channels by phencyclidine (PCP) in cultured rat hippocampal neurons. All recordings were carried out in the presence of tetrodotoxin (1-2 microM) to eliminate Na+ currents. Step depolarization from a holding potential of -40 mV activated a slowly rising, minimally inactivating K+ current (IK). PCP (0.5-1000 microM) caused a reduction in the maximum conductance of IK [IC50(+30 mV), 22 microM] without altering its voltage dependency. The PCP block of IK diminished at depolarized potentials. Analysis according to the scheme of Woodhull (1973) suggested that block occurs via binding to an acceptor site (presumably within the channel pore) that senses 40-50% of the transmembrane electrostatic field. PCP had no effect on the kinetic properties of IK and the block failed to show use dependency, suggesting that PCP may bind to the IK channel via a hydrophobic mechanism not requiring open channels. For comparison, we also investigated the effect of PCP on the transient K+ current, IA, activated by step depolarization following a 200 msec prepulse to -90 mV (20 mM tetraethylammonium was present in the bathing solution to reduce IK). In contrast to the potent blocking action of PCP on IK, the drug only affected IA at high concentrations [IC50(+30 mV), 224 microM]. At concentrations causing substantial block (300-500 microM), PCP produced an acceleration in the IA inactivation rate, and, for brief (5-6 msec) depolarizing steps, the suppression of IA was use dependent. These observations suggest that PCP block of IA requires open channels. PCP reduced inward current responses induced by the excitatory amino acid agonist N-methyl-D-aspartate (NMDA) at substantially lower concentrations than those required for its effects on K+ channels [IC50(-60 mV), 0.45 microM]. The PCP-like dioxadrol stereoisomer dexoxadrol (10 microM) blocked NMDA-evoked inward current responses, while its behaviorally inactive enantiomer levoxadrol did not. Dexoxadrol and levoxadrol also blocked IK in a stereoselective fashion (IC50's, 73 and 260 microM, respectively), whereas the sigma ligands (+)- and (-)-SKF 10,047 and (+)-3-[3-hydroxyphenyl]-N-(1-propyl)piperidine [(+)-3-PPP] had little effect on the current (IC50's, greater than 300-500 microM). We conclude that PCP causes a selective, voltage-dependent block of IK in hippocampal neurons via a PCP- and not a sigma-type acceptor site.(ABSTRACT TRUNCATED AT 400 WORDS)     

Fluoxetine inhibits A-type potassium currents in primary cultured rat hippocampal neurons

The effects of fluoxetine (Prozac) on the transient A-currents (IA) in primary cultured hippocampal neurons were examined using the whole-cell patch clamp technique. Fluoxetine did not significantly decrease the peak amplitude of whole-cell K+ currents, but it accelerated the decay rate of inactivation, and thus decreased the current amplitude at the end of the pulse. For further analysis, IA and delayed rectifier K+ currents (IDR) were isolated from total K+ currents. Fluoxetine decreased IA (the integral of the outward current) in a concentration-dependent manner with an IC50 of 5.54 microM. Norfluoxetine, the major active metabolite of fluoxetine, was a more potent inhibitor of IA than was fluoxetine, with an IC50 of 0.90 microM. Fluoxetine (3 microM) inhibited IA in a voltage-dependent manner over the whole range of membrane potentials tested. Analysis of the time dependence of inhibition gave estimates of 34.72 microM(-1) s(-1) and 116.39 s(-1) for the rate constants of association and dissociation, respectively. The resulting apparent Kd was 3.35 microM, similar to the IC50 value obtained from the concentration-response curve. In current clamp configuration, fluoxetine (3 microM) induced depolarization of resting membrane potential and reduced the rate of action potential. Our results indicate that fluoxetine produces a concentration- and voltage-dependent inhibition of IA, and that this effect could affect the excitability of hippocampal neurons.     

Levetiracetam does not modulate neuronal voltage-gated Na+ and T-type Ca2+ currents.

This study investigated whether the mechanism of action of levetiracetam (LEV) is related to effects on neuronal voltage-gated Na+ or T-type Ca2+currents. Rat neocortical neurones in culture were subjected to the whole-cell mode of voltage clamping under experimental conditions designed to study voltage-gated Na+ current. Additionally, visually identified pyramidal neurones in the CA1 area of rat hippocampal slices were subjected to the whole-cell mode of voltage clamping under experimental conditions designed to study low-voltage-gated (T-type) Ca2+ current. LEV (10 microM-1 mM) did not modify the Na+ current amplitude and did not change (200 microM) the steady-state activation and inactivation, the time to peak, the fast kinetics of the inactivation and the recovery from the steady-state inactivation of the Na+ current. Likewise, LEV (32-100 microM) did not modify the amplitude and did not change the steady-state activation and inactivation, the time to peak, the fast kinetics of the inactivation and the recovery from the steady-state inactivation of the T-type Ca2+current. In conclusion, neuronal voltage-gated Na+ channels do not appear directly involved in the antiepileptic mechanism of action of LEV, and LEV was devoid of effect on the low-voltage-gated (T-type) Ca2+ current in hippocampal neurones.     

Inhibition of Ca-channels by diazepam compared with that by nicardipine in pheochromocytoma PC12 cells.

The effects of diazepam on voltage-gated Ca channels were studied in PC12 pheochromocytoma cells using whole-cell voltage-clamp techniques. An inward current activated by a depolarizing voltage step to +10 mV from a holding potential of -60 mV in 10.8 mM Ba was larger than that activated in 10.8 mM Ca. The Ba current was completely blocked by a low concentration of Cd (30 microM) and was also sensitive to nicardipine (100 nM to 10 microM). Diazepam (1-100 microM) inhibited the Ba current in a concentration-dependent manner. Neither diazepam nor nicardipine affected the current-voltage relationship or the dependence on holding potentials of the Ba current. Both slightly accelerated the inactivation time course of the Ba current. When diazepam was applied to the cells in combination with nicardipine, the observed inhibition agreed with a value predicted assuming independent blockade by diazepam and by nicardipine. These results suggest that diazepam inhibits Ca channels in a manner similar to nicardipine, but that the binding sites for diazepam are different from those for nicardipine.     

Characterization of a fast transient outward current in neocortical neurons from epilepsy patients

A-type currents powerfully modulate discharge behavior and have been described in a large number of different species and cell types. However, data on A-type currents in human brain tissue are scarce. Here we have examined the properties of a fast transient outward current in acutely dissociated human neocortical neurons from the temporal lobe of epilepsy patients by using the whole-cell voltage-clamp technique. The A-type current was isolated with a subtraction protocol. In addition, delayed potassium currents were reduced pharmacologically with 10 mM tetraethylammonium chloride. The current displayed an activation threshold of about -70 mV. The voltage-dependent activation was fitted with a Boltzmann function, with a half-maximal conductance at -14.8 +/- 1.8 mV (n = 5) and a slope factor of 17.0 +/- 0.5 mV (n = 5). The voltage of half-maximal steady-state inactivation was -98.9 +/- 8.3 mV (n = 5), with a slope factor of -6.6 +/- 1.9 mV (n = 5). Recovery from inactivation could be fitted monoexponentially with a time constant of 18.2 +/- 7.5 msec (n = 5). At a command potential of +30 mV, application of 5 mM 4-aminopyridine or 100 microM flecainide resulted in a reduction of A-type current amplitude by 35% or 22%, respectively. In addition, flecainide markedly accelerated inactivation. Current amplitude was reduced by 31% with application of 500 microM cadmium. All drug effects were reversible. In conclusion, neocortical neurons from epilepsy patients express an A-type current with properties similar to those described for animal tissues.     

Inhibitory effects of pimozide on cloned and native voltage-gated potassium channels

The primary goal of this study was to use the cloned neuronal Kv channels to test if pimozide (PMZD), an antipsychotic drug, modulates the activity of Kv channels. In CHO cells, PMZD blocked Kv2.1, a major neuronal delayed rectifier, in a manner that depends upon time and concentration. The estimated IC50 was 4.2 microM at +50 mV. Tail current analysis shows that PMZD reduced the amplitude of the currents, with no effect on the steady-state activation curve (V(1/2) from 14.1 to 11.1 mV) or the slope (16.7 vs. 14.0 mV). From -120 to -20 mV, PMZD did not impact the deactivation kinetics of Kv2.1. PMZD also blocked Kv1.1, another neuronal delayed rectifier, with 16.1 microM of IC50. When Kv1.1 was co-expressed with Kvbeta1, approximately 50% of the Kv1.1 were converted into an inactivating A-type current and the Kv1.1/Kvbeta1 A-type currents were insensitive to PMZD. PMZD (10 microM) had minimal effect on Kv1.4, and had no effect on the M-current candidates, KCNQ2 and KCNQ3 when co-expressed in Xenopus oocytes. In hippocampal neurons, PMZD inhibited the delayed rectifiers by approximately 60%, and A-type currents were insensitive to PMZD. The results suggest that PMZD inhibits certain neuronal Kv channels in heterologous expression systems and in hippocampal neurons. PMZD was less effective on A-type currents, presumably because its ability to block requires a prolonged opening of the K channels. It is thus conceivable that the time-dependent and/or subunit-specific inhibition of Kv channels may increase the release of neurotransmitters such as serotonin and glutamate.     

Lamotrigine Reduces Voltage-Gated Sodium Currents in Rat Central Neurons in Culture

Summary: Purpose : To study the mechanism or mechanisms of action of lamotrigine (LTG) and, in particular, to establish its effects on the function of NA⁺ channels in mammalian central neurons.
Methods : Rat cerebellar granule cells in culture were subjected to the whole-cell mode of voltage clamping under experimental conditions designed to study voltage-gated Na⁺ currents.
Results : Extracellular application of LTG (10–500 μ M , n = 21) decreased in a dose-related manner a tetrodotoxin-sensitive inward current that was elicited by depolarizing commands (from −80 to +20mV). The peak amplitude of this Na⁺-mediated current was diminished by 38.8 ± 12.2% (mean ± SD, n = 6) during application of 100 μ M LTG, and the dose-response curve of this effect indicated an IC₅₀ 145 μM. The reduction in the inward currents produced by LTG was not associate with any signficant change in the current decay, whereas the voltage dependency of the steady-state inactivation shifted toward more negative values (midpoint of the inactivation curve: –47.5 and –59.0 mV under control conditions and during application of 100 μM LTG, respectively, n = 4).
Conclusions : Our findings indicate that LTG reduces the amplitude of voltage-gated Na⁺ inward current in rat cerebellar granule cells and induces a negative shift of the steady-state inactivation curve. Both mechanisms may be instrumental in controlling the repetitive firing of action potentials (AP) that occurs in neuronal networks during seizure activity.     

Phencyclidine selectively blocks the sustained voltage-dependent potassium conductance in PC12 cells

We investigated the effects of phencyclidine (PCP), a psychotomimetic dissociative anesthetic, and several related drugs on voltage-dependent K+ currents in PC12 cells, a neuron-like clonal cell line derived from a rat pheochromocytoma. Whole-cell voltage clamp recordings demonstrated two kinetically distinct voltage-dependent outward (K+) current components in these cells: a rapidly activating and inactivating component, IA, that was selectively eliminated by 4-aminopyridine (2 mM) and a slowly activating, minimally inactivating (sustained) component, IK, that was specifically blocked by tetraethylammonium (20 mM). PCP (1-100 microM) produced a dose-dependent blockade of both IK and IA, however, at low doses the drug selectively reduced IK with little effect on IA; the IC50s for blockade of IK and IA were 4 and 25 microM, respectively. The blockade of IK was voltage-dependent so that the degree of block decreased with increasing depolarization, indicating that the blocking mechanism is likely one in which the positively charged PCP molecule is drawn into the channel pore. Several PCP related drugs also suppressed IK. Thienyl-PCP (TCP), a drug that is behaviorally more potent than PCP, partially blocked IK at low doses (31% at 1 microM), but even at high doses (25 microM) the degree of block was never as great as that produced by PCP. The optically active PCP congeners (+)-PCMP (1-(1-phenylcyclohexyl)-3-methyl-piperidine) and dexoxadrol were also potent blockers of IK. However, in contrast to the stereospecificity these compounds demonstrate in binding to high-affinity PCP receptors and in eliciting PCP-like behavioral responses, their enantiomers (-)-PCMP and levoxadrol showed similar potencies as the parent compounds in blocking IK. These results demonstrate that PCP and related drugs are powerful, selective blockers of IK in PC12 cells. The structure-activity studies indicate that this effect occurs at a site that is pharmacologically distinct from the behaviorally relevant PCP receptor. Blockade of K+ channels is unlikely to be responsible for the psychotomimetic or anti-convulsant properties of PCP, but could account for the convulsant potential of the drug.     

Neocortical potassium currents are enhanced by the antiepileptic drug lamotrigine

PURPOSE: We used field-potential recordings in slices of rat cerebral cortex along with whole-cell patch recordings from rat neocortical cells in culture to test the hypothesis that the antiepileptic drug (AED) lamotrigine (LTG) modulates K+-mediated, hyperpolarizing currents. METHODS: Extracellular field-potential recordings were performed in neocortical slices obtained from Wistar rats aged 25-50 days. Rat neocortical neurons in culture were subjected to the whole-cell mode of voltage clamping under experimental conditions designed to study voltage-gated K+ currents. RESULTS: In the in vitro slice preparation, LTG (100-400 microM) reduced and/or abolished epileptiform discharges induced by 4-aminopyridine (4AP, 100 microM; n = 10), at doses that were significantly higher than those required to affect epileptiform activity recorded in Mg2+-free medium (n = 8). We also discovered that in cultured cortical cells, LTG (100-500 microM; n = 13) increased a transient, 4AP-sensitive, outward current elicited by depolarizing commands in medium containing voltage-gated Ca2+ and Na+ channel antagonists. Moreover, we did not observe any change in a late, tetraethylammonium-sensitive outward current. CONCLUSIONS: Our data indicate that LTG, in addition to the well-known reduction of voltage-gated Na+ currents, potentiates 4AP-sensitive, K+-mediated hyperpolarizing conductances in cortical neurons. This mechanism of action contributes to the anticonvulsant effects exerted by LTG in experimental models of epileptiform discharge, and presumably in clinical practice.     

Effects of copper on A-type potassium currents in acutely dissociated rat hippocampal CA1 neurons

The effects of copper on voltage-gated A-type potassium currents were investigated in acutely dissociated rat hippocampal CA1 neurons using the whole-cell patch-clamp technique. Extracellular application of various concentrations of copper (1-1000 microM) reversibly reduced the amplitude of voltage-gated A-type potassium currents in a dose-dependent manner with a 50% inhibitory concentration value of 130 microM. Copper (300 microM) increased the V1/2 of the activation curve and state-inactivation curve by 17.2 and 9.0 mV, respectively. Thus, copper slowed down the activation and inactivation process of voltage-gated A-type potassium currents. This study indicated that copper reversibly inhibits the hippocampal CA1 neuronal voltage-gated A-type potassium current in a dose-dependent and voltage-dependent manner, and such actions are likely involved in the regulation of the neuronal excitability and the pathophysiology of Wilson's disease.     

Blockade of U50488H on potassium currents of acutely isolated mouse hippocampal CA3 pyramidal neurons

The actions of the opioid agonist U50488H on IA and IK were examined in acutely isolated mouse hippocampal CA3 pyramidal neurons using the whole-cell patch clamp technique. U50488H caused a concentration dependent, rapidly developing and reversible inhibition of voltage-activated IA and IK. The inhibitory actions were still observed in the presence of 30 microM naloxone or 5 microM nor-binaltorphimine dihydrochloride. The IC50 values for the blockade of IA and IK were calculated as 20.1.9 and 3.7 microM, respectively. In the presence of 3.3 microM U50488H, repetitive stimulation induced use-dependent inhibition of IA and IK. A 10 microM concentration of U50488H positively shifted the half-activation membrane potential of IA by +11 mV, but negatively shifted IK by -14 mV. These results demonstrate that U50488H can directly inhibit neuronal IA and IK without involvement of the activation of kappa-opioid receptors.     

Trans-resveratrol, a red wine ingredient, inhibits voltage-activated potassium currents in rat hippocampal neurons

The red wine ingredient trans-resveratrol was found to exert potent neuroprotective effects in different in vivo and in vitro models. Thus far, the mechanisms underlying the neuroprotection were attributed mainly to its antioxidant properties. The aim of this study was to investigate the actions of trans-resveratrol on voltage-gated K(+) channels, which have been implicated in neuronal apoptosis. Superfusion of trans-resveratrol reversibly inhibited both the delayed rectifier (I(K)) and fast transient K(+) current (I(A)) in rat dissociated hippocampal neurons with IC(50) values of 13.6 +/- 1.0 microM and 45.7 +/- 7.5 microM, respectively. The inhibition on I(K) had a slow onset, was neither voltage dependent nor use dependent. Trans-resveratrol (30 microM) shifted the steady-state inactivation curve of I(K) to the hyperpolarizing direction by 20 mV and slowed down its recovery from inactivation. The inhibition on I(A) was similar to that on I(K), but voltage dependent. Superfusion of trans-resveratrol (30 microM) shifted the steady-state activation curve of I(A) to the depolarizing direction by 17 mV. Intracellular application of trans-resveratrol (30 microM) was ineffective. Based on the comparable effective concentrations, the inhibition of voltage-activated K(+) currents by trans-resveratrol may contribute to its neuroprotective effects.     

4-aminopyridine, a specific blocker of K(+) channels, inhibited inward Na(+) current in rat cerebellar granule cells

The effects of 4-aminopyridine (4-AP), a specific blocker of outward K(+) current, on voltage-activated transient outward K(+) current (I(K(A))) and inward Na(+) current (I(Na)) were investigated on cultured rat cerebellar granule cells using the whole cell voltage-clamp technique. At the concentration of 1-5 mM, 4-AP inhibited both I(K(A)) and I(Na). It reduced the amplitude of peak Na(+) current without significant alteration of the steady-state activation and inactivation properties. The inhibitory effect was not enhanced by repeated depolarizing pulses (0.5 or 0.1 Hz), suggesting that the binding affinity of 4-AP on Na(+) channels is state-independent. In contrast, the effect of 4-AP on Na(+) channels appeared to be voltage-dependent, the weaker inhibition occurred at more depolarization. Moreover, 4-AP slowed both the activation and inactivation kinetics of Na(+) current. These effects were similar to those induced by alpha-scorpion toxin and sea anemone toxins on Na(+) channels in other cell model. Our data demonstrate for the first time that 4-AP is able to block not only A-type K(+) channels, but also Na(+) channels in rat cerebellar granule cells. It is concluded that the inhibition exerted by 4-AP on Na(+) current likely differs from that provoked by local anesthetics. The possibility that the binding site of neurotoxin receptor 3 may be involved is discussed.     

Phencyclidine blocks two potassium currents in spinal neurons in cell culture

We studied the effects of phencyclidine (PCP) on the transient and delayed outward K+ currents recorded from spinal cord neurons grown (10-20 days) in cell culture. Sodium channels were blocked with tetrodotoxin (1 microM) and solutions containing low calcium concentrations in the presence of Mg2+ or Co2+ (5 mM) were used to reduce Ca2+ currents. PCP decreased the amplitude and prolonged the decay phase of the action potentials recorded at a holding potential of -70 mV. PCP (0.1-0.5 mM) was more effective than tetraethylammonium (TEA) or 4-aminopyridine (4-AP) in reducing both transient and delayed currents. The amplitude of the transient current during control experiments was always larger than that of the delayed current. It appeared that 4-AP (5 mM) was more potent in blocking the transient current, while TEA (10 mM) modified the delayed current more effectively. Both currents were also reduced by about 10% when the cell soma was perfused with Co2+. This suggested that a small fraction of the total outward current is a Ca2+-activated K+ current. The PCP-induced blockade of K+ currents in central neurons coupled with the profound synaptic effects of the drug may provide the basis for explaining the psychopathology of this hallucinogenic agent.     

Activation of calcium channel currents in rat sensory neurons by large depolarizations: effect of Guanine nucleotides and (-)-baclofen

Calcium channel currents have been recorded from cultured rat sensory neurons at clamp potentials of between -30 and +120 mV. At large depolarizing potentials between +50 and +120 mV, the current was outward. This outward current was shown to be largely due to ions passing through calcium channels, because it was substantially although generally incompletely blocked by Cd2+ (1 mM) and omega-conotoxin (1 microM). Internal GTP-gamma-S (100 microM) and to a lesser extent GTP (1 mM) reduced the amplitude and slowed the activation of the outward, as well as the inward calcium channel current. Baclofen (100 microM) reversibly inhibited both the inward and outward currents. These results suggest that the effect of baclofen and G protein activation on calcium channel currents is not due to a shift in the voltage-dependence of channel availability.     

Effects of insulin-like growth factor 1 on voltage-gated ion channels in cultured rat hippocampal neurons

Insulin-like growth factor 1 (IGF-1) has important functions in the brain, including metabolic, neurotrophic, neuromodulatory, and neuroendocrine actions, and it is also prevents amyloid beta-induced death of hippocampal neurons. However, its functions on the voltage-gated ion channels in hippocampus remain uncertain. In the present study, we investigated the effects of IGF-1 on voltage-gated potassium, sodium, and calcium channels in the cultured rat hippocampal neurons using the whole-cell patch clamp recordings. Following incubation with different doses of IGF-1 for 24 h, a block of the peak transient A-type K+ currents amplitude (IC50: 4.425 ng/ml, Hill coefficient: 0.621) was observed. In addition, after the application of IGF-1, the amplitude of high-voltage activated Ca2+ currents significantly increased but activation kinetics did not significantly alter (V1/2: -33.45 +/- 1.32 mV, k = 6.16 +/- 1.05) compared to control conditions (V1/2: -33.19 +/- 2.28 mV, k = 7.26 +/- 1.71). However, the amplitude of Na+, K+, and low-voltage activated Ca2+ currents was not affected by the application of IGF-1. These data suggest that IGF-1 inhibits transient A-type K+ currents and enhances high-voltage-activated Ca2+ currents, but has no effects on Na+ and low-voltage-activated Ca2+ currents.     

Two pharmacologically and kinetically distinct transient potassium currents in cultured embryonic mouse hippocampal neurons.

Transient potassium currents in mammalian central neurons influence both the repolarization of single action potentials and the timing of repetitive action potential generation. How these currents are integrated into neuronal function will depend on their specific properties: channel availability at the resting potential, activation threshold, inactivation rate, and current density. We here report on the voltage-gated transient potassium currents in embryonic mouse hippocampal neurons dissected at embryonic days 15-16 and grown in dissociated cell culture for up to 3 d. Two transient potassium currents, A-current and D-current, were isolated based on steady state inactivation and sensitivity to 4-aminopyridine (4-AP) and dendrotoxin (DTx). A-current had an activation threshold of approximately -50 mV and was half-inactivated at approximately -81 mV. A-current relaxations at voltages between -40 and +40 mV could be fit by single exponential functions with time constants of 20-25 msec; these time constants showed little sensitivity to voltage. In contrast, D-current had an activation threshold of between -40 and -30 mV and was half-inactivated at approximately -22 mV. D-current inactivation was voltage dependent; time constants of fitted exponential functions ranged from approximately 7 sec at -40 mV to 200 msec at +40 mV. A slower component of inactivation was also evident. D-current was preferentially blocked by 4-AP (100 microM) and DTx (1 microM). Operationally, A- and D-currents could be cleanly separated based on conditioning pulse potential and 4-AP sensitivity. Total transient potassium current amplitude increased during the time that neurons were in culture (recordings were made between 2 hr after dissociation and 3 d in culture). When normalized for cell capacitance (an index of membrane area), A-current density (pA/pF) decreased and D-current density increased, even during a period between days 1 and 3 when total transient current density remained constant. This observation suggests that A- and D-currents may be reciprocally modulated. Since blockade of D-current (with 100 microM 4-AP) increased both action potential duration and repetitive firing in response to constant current stimulation, long-term modulation of the A-current:D-current ratio may affect the excitability of hippocampal neurons.     

Effects of berberine on potassium currents in acutely isolated CA1 pyramidal neurons of rat hippocampus

The effects of berberine, an isoquinoline alkaloid with antiarrhythmic action, on voltage-dependent potassium currents were studied in acutely isolated CA1 pyramidal neurons of rat hippocampus by using the whole-cell patch-clamp techniques. Berberine blocked transient outward potassium current (IA) and delayed rectifier potassium current (IK) in a concentration-dependent manner with EC50 of 22.94+/-4.96 microM and 10.86+/-1.06 microM, Emax of 67.47+/-4.00% and 67.14+/-1.79%, n of 0.77+/-0.08 and 0.96+/-0.07, respectively. Berberine 30 microM shifted the steady-state activation curve and inactivation curve of IA to more negative potentials, but mainly affected the inactivation kinetics. Berberine 30 microM positively shifted the steady-state activation curve of IK. These results suggested that blockades on K+ currents by berberine are preferential for IK, and contribute to its protective action against ischemic brain damage.     

Three types of early transient potassium currents in Aplysia neurons.

In an attempt to categorize the various early transient K+ currents (A-type K+ currents) present in mature neurons, we have explored these currents in the identified neurons in the abdominal ganglion of the mollusk, Aplysia californica. Three distinct types of A-type K+ currents (IAfast, IAslow, and IAdepol) were found. The activation and the steady-state inactivation properties of two of these currents, IAfast and IAslow, were similar to conventional A-type K+ currents. By contrast, those of the third current, IAdepol, were shifted to more depolarized potentials. Whereas the decay time constants of IAfast were voltage dependent, those of IAslow and IAdepol were almost voltage independent. The recovery from inactivation of IAfast and IAslow was much faster than that of IAdepol. In addition, IAdepol was more sensitive to 4-aminopyridine (4-AP) than other currents and was almost completely blocked by 1 mM 4-AP. All the currents were depressed by forskolin or 1,9-dideoxyforskolin, but not by cAMP analogs. None of these currents were blocked by external tetraethylammonium (50 mM). These results indicate that there are at least three subtypes of A-type K+ currents in the Aplysia CNS. Of these, two currents, IAfast and IAslow, are conventional A-type K+ currents, whereas the third current, IAdepol, is a novel early transient K+ current.     

Voltage clamp analysis of membrane currents in larval muscle fibers of Drosophila: alteration of potassium currents in Shaker mutants

The body wall muscles in Drosophila larvae are suitable for voltage clamp analysis of changes in membrane excitability caused by mutations. Both inward and outward ionic currents are present in these muscle fibers. The inward current is mediated by voltage-dependent Ca2+ channels. In Ca2+-free saline, the inward current is eliminated. The remaining outward K+ currents consist of two distinct components, an early transient IA and a delayed steady IK, which are separable by differences in the rate and voltage dependence of activation and inactivation. The steady-state and kinetic properties of the activation and inactivation processes of these two currents are analyzed. The results provide a basis for quantitative analysis of altered membrane currents in behavioral mutants of Drosophila. Previous studies indicate that mutations in the Shaker (Sh) locus alter excitability in both nerve and muscle in Drosophila. Our results support the idea that the channels mediating IA are molecularly distinct from those mediating IK. All Sh mutations studied specifically affect IA without changing the properties of the calcium current and IK. In certain alleles (ShKS133, Sh102, and ShM) IA is eliminated, permitting detailed studies of IK in isolation of IA. Studies of the alleles that do not eliminate IA provide additional information of the channels. In one such allele, Sh5, voltage dependence of IA activation is shifted to more positive potentials. This is accompanied by a less pronounced shift in the voltage dependence of inactivation. These results suggest that Sh5 mutation affects the voltage-sensitive mechanism of both activation and inactivation processes and that these two processes are not controlled by independent parts of the channel. Furthermore, the differential effects of these alleles on different excitable membranes imply that other genes take part in the control of IA. The effects of Sh5 on muscle depend on developmental stage. In larval muscle, Sh5 reduces the amplitude of IA because of the shift in the current-voltage (I-V) relation. In contrast, in adult Sh5 muscles, IA is reported to be normal in amplitude but shows abnormally rapid inactivation (Salkoff, L., and R. Wyman (1981) Nature 293: 228-230). A different allele, ShrK0120, causes a clear defect in nerve excitability, but analysis of IA in ShrK0120 larval muscle reveals I-V relations, inactivation, and recovery from inactivation similar to those seen in normal fibers. We suggest a possible mechanism of combinations of multiple interacting genes participating in the control of potassium channels to account for the presence of a variety of potassium channels in different excitable membranes.