Action of quinidine on ionic currents of molluscan pacemaker neurons

Choline and NMDG directly reduce outward currents: reduced outward current when these substances replace Na+ is alone not evidence of Na+-activated K+ currents

Choline chloride is often, and N-methyl-d-glucamine (NMDG) sometimes, used to replace sodium chloride in studies of sodium-activated potassium channels. Given the high concentrations used in sodium replacement protocols, it is essential to test that it is not the replacement substances themselves, as opposed to the lack of sodium, that cause any observed effects. We therefore compared, in lobster stomatogastric neurons and leech Retzius cells, the effects of applying salines in which choline chloride replaced sodium chloride, and in which choline hydroxide or sucrose was added to normal saline. We also tested, in stomatogastric neurons, the effect of adding NMDG to normal saline. These protocols allowed us to measure the direct effects (i.e., effects not due to changes in sodium concentration or saline osmolarity or ionic strength) of choline on stomatogastric and leech currents, and of NMDG on stomatogastric currents. Choline directly reduced transient and sustained depolarization-activated outward currents in both species, and NMDG directly reduced transient depolarization-activated outward currents in stomatogastric neurons. Experiments with lower choline concentrations showed that adding as little as 150 mM (stomatogastric) or 5 mM (leech) choline reduced at least some depolarization-activated outward currents. Reductions in outward current with choline chloride or NMDG replacement alone are thus not evidence of sodium-activated potassium currents. NEW & NOTEWORTHY We show that choline or N-methyl-d-glucamine (NMDG) directly (i.e., not due to changes in extracellular sodium) decrease outward currents. Prior work studying sodium-activated potassium channels in which sodium was replaced with choline or NMDG without an addition control may therefore be artifactual.

Gap Junction Blockers: An Overview of their Effects on Induced Seizures in Animal Models

BACKGROUND

Gap junctions are clusters of intercellular channels allowing the bidirectional pass of ions directly into the cytoplasm of adjacent cells. Electrical coupling mediated by gap junctions plays a role in the generation of highly synchronized electrical activity. The hypersynchronous neuronal activity is a distinctive characteristic of convulsive events. Therefore, it has been postulated that enhanced gap junctional communication is an underlying mechanism involved in the generation and maintenance of seizures. There are some chemical compounds characterized as gap junction blockers because of their ability to disrupt the gap junctional intercellular communication.

OBJECTIVE

Hence, the aim of this review is to analyze the available data concerning the effects of gap junction blockers specifically in seizure models.

RESULTS

Carbenoxolone, quinine, mefloquine, quinidine, anandamide, oleamide, heptanol, octanol, meclofenamic acid, niflumic acid, flufenamic acid, glycyrrhetinic acid and retinoic acid have all been evaluated on animal seizure models. In vitro, these compounds share anticonvulsant effects typically characterized by the reduction of both amplitude and frequency of the epileptiform activity induced in brain slices. In vivo, gap junction blockers modify the behavioral parameters related to seizures induced by 4-aminopyridine, pentylenetetrazole, pilocarpine, penicillin and maximal electroshock.

CONCLUSION

Although more studies are still required, these molecules could be a promising avenue in the search for new pharmaceutical alternatives for the treatment of epilepsy.

The cellular building blocks of breathing

Respiratory brainstem neurons fulfill critical roles in controlling breathing: they generate the activity patterns for breathing and contribute to various sensory responses including changes in O2 and CO2. These complex sensorimotor tasks depend on the dynamic interplay between numerous cellular building blocks that consist of voltage-, calcium-, and ATP-dependent ionic conductances, various ionotropic and metabotropic synaptic mechanisms, as well as neuromodulators acting on G-protein coupled receptors and second messenger systems. As described in this review, the sensorimotor responses of the respiratory network emerge through the state-dependent integration of all these building blocks. There is no known respiratory function that involves only a small number of intrinsic, synaptic, or modulatory properties. Because of the complex integration of numerous intrinsic, synaptic, and modulatory mechanisms, the respiratory network is capable of continuously adapting to changes in the external and internal environment, which makes breathing one of the most integrated behaviors. Not surprisingly, inspiration is critical not only in the control of ventilation, but also in the context of "inspiring behaviors" such as arousal of the mind and even creativity. Far-reaching implications apply also to the underlying network mechanisms, as lessons learned from the respiratory network apply to network functions in general.

Comparison of salicylate- and quinine-induced tinnitus in rats: development, time course, and evaluation of audiologic correlates

BACKGROUND

Salicylate and quinine have been shown to reliably induce short-term tinnitus when administered at high doses. The present study compared salicylate and quinine-induced tinnitus in rats using the gap prepulse inhibition of acoustic startle (GPIAS).

METHODS

Twenty-four rats were divided into 2 groups; the first group (n = 12) was injected with salicylate (300 mg kg d), whereas the second (n = 12) was treated with quinine orally at a dose of 200 mg kg d. Animals were treated daily for 4 consecutive days. All rats were tested for tinnitus and hearing loss before and 2, 24, 48, 72, and 96 hours after the first drug administration. Tinnitus was assessed using GPIAS; hearing function was measured with distortion product otoacoustic emissions (DPOAEs) and auditory brainstem response.

RESULTS

Salicylate treatment induced transient tinnitus with a pitch near 16 kHz starting 2 hours posttreatment, persisting over the 4-day treatment period and disappearing 24 hours later. Animals in the quinine group showed GPIAS changes at a higher pitch (20 kHz); however, changes were more variable among animals, and the mean data were not statistically significant. Hearing function varied across treatments. In the salicylate group, high-level DPOAEs were slightly affected; most changes occurred 2 hours posttreatment. Low-level DPOAEs were affected at all frequencies with a progressive dose-dependent effect. In the quinine group, only high-level DPOAEs were affected, mainly at 16 kHz.

CONCLUSION

The present study highlights the similarities and differences in the frequency and the time course of tinnitus and hypoacusis induced by salicylate and quinine. Transient tinnitus was reliably induced pharmacologically with salicylate, whereas hearing loss remained subclinical with only minor changes in DPOAEs.

Potassium channel blockers quinidine and caesium halt cell proliferation in C6 glioma cells via a polyamine-dependent mechanism

Potassium channels are ubiquitous in cells and serve essential functions in physiology and pathophysiology. Potassium channel blockers have been shown to block tumour growth by arresting cells at the G(0)/G(1) checkpoint of the cell cycle. We investigated the effect of quinidine and caesium (Cs(+)) on cell proliferation, LDH (lactate dehydrogenase) release, free internal calcium, membrane potential, polyamine concentration, ODC (ornithine decarboxylase) activity and polyamine uptake in C6 glioma cells. The EC(50) for reducing cell proliferation was 112 microM for quinidine, whereas Cs(+) was less effective with an EC(50) of 4.75 mM. KCl or sucrose did not affect proliferation. LDH release was augmented by quinidine. Quinidine caused a transient increase in free internal calcium but decreased calcium after a 48 h incubation period. Further 300 microM quinidine depolarized the cell membrane in a similar range as did 30 mM KCl. Quinidine decreased cellular putrescine beyond detection levels while spermidine and spermine remained unaffected. ODC activity was reduced. Addition of putrescine could not override the antiproliferative effect owing to a reduced activity of the polyamine transporter. Our study indicates that the antiproliferative effect of quinidine is not due to a simple membrane depolarization but is caused by a block of ODC activity.

Ethanol excitation of dopaminergic ventral tegmental area neurons is blocked by quinidine

The dopaminergic (DA) neurons in the ventral tegmental area (VTA) are important for the reinforcing effects of ethanol. We have shown that ethanol directly excites DA VTA neurons and reduces the afterhyperpolarization (AHP) that follows spontaneous action potentials in these neurons. These data suggested that ethanol may be increasing the firing rate of DA VTA neurons by modulating currents that contribute to the AHP, either by reducing a K+ current or by increasing the inward current Ih. In the present study, different blockers of K+ channels and Ih were tested to determine whether any could prevent the ethanol excitation of DA VTA neurons. Extracellular single-unit recordings and whole-cell patch-clamp recordings were made from DA VTA neurons in brain slices from Fischer-344 rats and ethanol (40-120 mM) and channel blockers were applied in the bath. Ethanol excitation was not reduced by blockade of Ih with cesium (5 mM) or ZD7288 (30 microM), or by block of G-protein-coupled inwardly rectifying K+ channels with barium (500 microM). Tetraethylammonium (TEA) ion (2-10 mM), which blocks the large conductance calcium-dependent potassium K+ current and some types of delayed rectifier currents, had no effect on the ethanol-induced excitation. Interestingly, ethanol excitation of DA VTA neurons was blocked by quinidine (20-80 microM), a drug that blocks many types of delayed rectifier K+ channels, including some insensitive to TEA. This effect of quinidine was concentration-dependent and reversible. These results suggest that ethanol excites DA VTA neurons by reducing a quinidine-sensitive K+ current.

Influence of quinine on catecholamine release evoked by cholinergic stimulation and membrane depolarization from the rat adrenal gland

The present study was attempted to investigate the effect of quinine on secretion of catecholamines (CA) evoked by cholinergic stimulation and membrane depolarization from the isolated perfused rat adrenal gland. The perfusion of quinine (15-150 microM) into an adrenal vein for 60 min produced dose- and time-dependent inhibition in CA secretion evoked by ACh (5.32 x 10(-3) M), high K+ (5.6 x 10(-2) M), DMPP (10(-4) M for 2 min), McN-A-343 (10(-4) M for 2 min), cyclopiazonic acid (10(-5) M for 4 min) and Bay-K-8644 (10(-5) M for 4 min). Also, under the presence of pinacidil (10(-4) M), which is also known to be a selective potassium channel activator, CA secretory responses evoked by ACh, high potassium, DMPPF McN-A-343, Bay-K-8644 and cyclopiazonic acid were also greatly reduced. When preloaded along with quinine (5 x 10(-5) M) and glibenclamide (10(-6) M), a specific blocker of ATP-regulated potassium channels, CA secretory responses evoked by ACh, high potassium, DMPP, McN-A-343, Bay-K-8644 and cyclopiazonic acid were recovered as compared to those of quinine-treatment only. Taken together, these results demonstrate that quinine inhibits CA secretion evoked by stimulation of cholinergic (both nicotinic and muscarinic) receptors as well as by membrane depolarization through inhibiting influx of extracellular calcium and release in intracellular calcium in the rat adrenomedullary chromaffin cells. These findings suggest that activation of potassium channels may be involved at least in inhibitory action of quinine on CA secretion from the rat adrenal gland.

Blockade of the delayed rectifier potassium current in Drosophila by quinidine and related compounds

Quinidine is a potent blocker of the delayed rectifier K+ channels (IK). Although it has been used for understanding the physiology of K+ channels in many organisms and for treating cardiac arrhythmia in humans, mechanisms of its interaction with the channel molecule are not well understood. As a first step in understanding these mechanisms, we used the Shaker mutant of Drosophila in which the delayed rectifier can be resolved in complete isolation from other currents and determined the importance of the major groups of quinidine (methoxy, quinoline, quinuclide and the bridge groups) in the blockade of IK. It appears that the quinoline moiety, while possessing little channel-blocking activity by itself, may provide a template for positioning the groups that may be important for affinity and blockade. These groups, in the order of importance in imparting inhibitory activity to quinoline, seemed to be quinuclide > methylene bridge > 6-methoxy group. In particular, the quinoline ring and the quinuclide group, when linked-together by a hydroxymethylene bridge, might be responsible for a major part of the IK blocking activity of quinidine. Action of quinidine was not affected by either quinuclidine, which did not block IK, or by quinoline.

Salicylate and quinine affect the central nervous system

Spontaneous local field potential (LFP) spindle frequencies in cat primary auditory cortex (AI) were estimated from the LFP-trigger autocorrelogram before and after application of sodium salicylate and quinine sulfate. A significant decrease (from 8.7 Hz to 7.6 Hz) was observed. The best modulation frequencies for 251 single units recorded in AI response to periodic click train stimulation also decreased (from 10 Hz to 8.6 Hz) after application of these tinnitus-inducing drugs. The results strongly suggest a central effect of salicylates and quinine in addition to their peripheral ototoxic effects.

Gating charge and ionic currents associated with quinidine block of human Kv1.5 delayed rectifier channels

1. The mechanism of quinidine-induced ionic and gating current inhibition was studied in human Kv1.5 (hKv1.5) delayed rectifier channels expressed in human embryonic kidney cells. In the steady state, quinidine produced a voltage-dependent block between +30 and +120 mV (Kd at +60 mV = 7.2 microM) with an equivalent electrical distance, delta, of 0.29 +/- 0.06 and 0.26 +/- 0.05 at 10 and 50 microM quinidine, respectively. The apparent affinity at 0 mV (Kd) was 25 microM at 10 microM quinidine and 38 microM at 50 microM quinidine. The data suggested a quinidine binding site that sensed 20-30% of the transmembrane electrical field, from the inside. Non-steady-state measurements indicated rapid open channel block with mean time constants of 2.1 +/- 0.9 and 1.2 +/- 0.2 ms at 10 and 50 microM quinidine, respectively. 2. 'On' gating current (on-Ig) was unaffected over a wide range of potentials and between 10 and 100 microM quinidine. On-gating charge (Qon) was similarly conserved in the steady state between -100 and +50 mV. On return to -100 mV, quinidine slowed the off-gating current (off-Ig) after depolarizations more positive than -25 mV. After depolarizations to +50 mV, only 59 +/- 3.4% (10 microM quinidine) and 6.6 +/- 9.5% (100 microM quinidine) of the charge returned within 25 ms, compared with 100% in control. Due to the conservation of Qon in subsequent pulses, the remaining charge must have returned during the subsequent 10 s interpulse interval. 3. A threshold for quinidine action on off-Ig was established positive to -25 mV. The voltage dependence of Qoff immobilization at more positive potentials than +20 mV had an equivalent electrical distance of 0.32 +/- 0.04 (10 microM quinidine) and 0.20 +/- 0.32 (100 microM quinidine) with calculated Kd values of 21.6 +/- 4.6 and 16.2 +/- 8.4 microM at 10 and 100 microM quinidine, respectively. These characteristics of block are in good agreement with values obtained from ionic data. 4. Simultaneous measurements of ionic and gating currents confirmed, after subtraction, an ionic current threshold at -21.8 +/- 1.8 mV. The gating current data confirm directly that ionic current block by quinidine occurs by binding at a site on the hKv1.5 channel that becomes accessible when the channel opens. There was no evidence for action of quinidine on kinetic states prior to the open state at concentrations of quinidine up to 100 microM.

Effects of quinine on neural activity in cat primary auditory cortex

The effect of systemically applied quinine on single-unit firing activity in primary auditory cortex was investigated in seven cats. A dose of 100 or 200 mg/kg of quinine hydrochloride was administered intramuscularly and recordings from the same units were performed prior to application and continuously up to on average 5.5 h after administration. All animals showed 10-40 dB of threshold shift about 30 min after administration and some animals showed recovery during the course of the investigation. Significant increases were found in spontaneous firing rates for low-firing-rate units (initial firing rate < 1 spike/s). For high-firing-rate units (initial firing rate > 1 spike/s) no significant changes were observed. There were no significant changes in modal and mean interspike interval. The time-to-rebound peak in the autocorrelation function for spontaneous firings was not altered significantly. The rate of burst occurrence showed no significant change. The best modulation frequency in response to stimulation with periodic click trains decreased after administration, but the limiting rate did not change. Peak cross-correlation coefficients for the spontaneous firings of simultaneously recorded cells showed a significant increase and the correlogram's central peak was significantly narrower after quinine application. Dose effects were only present for cross-correlation results and temporal modulation transfer functions. The results for both spontaneous firing rate, peak width in the cross-correlogram and click stimulation were similar to those observed in salicylate-treated cats (Ochi and Eggermont, 1996). The other findings were different from those observed after salicylate. It is obvious that the effects of quinine on the auditory system are not the same as those of salicylate. The increased synchronization of the spontaneous firings across different neurons observed after application of both drugs may be related to tinnitus.

Quinine, intracellular pH and modulation of hemi-gap junctions in catfish horizontal cells

Quinine increases the conductance of hemi-gap junctions in horizontal cells. We investigated the mechanisms of alkalinization and the hypothesis that quinine-induced alkalinization produced these conductance increases. We found that quinine-induced alkalinizations were not blocked by cobalt, amiloride, or DIDS. Therefore, this suggests that the alkalinization is not likely due to net proton flux through opened hemi-gap channels nor is it likely due to an action on Cl-/HCO3- exchanger or Na+/H+ exchanger, both of which are known to regulate pHi in the horizontal cells. Quinine increased hemi-gap conductance even when cells were recorded with patch pipets containing up to 80 mM HEPES. We conclude that quinine-induced alkalinization cannot account solely for the hemi-gap junctional conductance increases.

Effects of the quinoline derivatives quinine, quinidine, and chloroquine on neuromuscular transmission

The quinoline derivatives quinine, its stereoisomer quinidine, and chloroquine may worsen or provoke disorders of neuromuscular transmission. In this study, we investigate effects of these drugs on neuromuscular transmission by conventional microelectrode as well as patch-clamp techniques. At 5 x 10(-5) M, quinine, quinidine, and chloroquine reduced the quantal content of the end-plate potential by 37-45%. Between 10(-6) and 10(-4) M, all 3 drugs progressively decreased the amplitude and decay time constant of miniature end-plate potential (MEPP) and miniature end-plate current (MEPC); at 5 x 10(-3) M, the MEPP became undetectable. The effect on the MEPP was not reversed by 1 microgram/mL neostigmine. Single-channel patch-clamp analysis of the effects of quinine showed that this agent causes a long-lived open-channel as well as a closed-channel block of AChR. Tests for competitive inhibition or desensitization of the acetylcholine receptor (AChR) by quinine in concentrations that had a marked effect on the MEPC and on single-channel open and closed intervals were negative. Because quinoline drugs adversely affect both presynaptic and postsynaptic aspects of neuromuscular transmission at concentrations close to those employed in clinical practice, they should not be used, or used with caution, in disorders that compromise the safety margin of neuromuscular transmission.

Quinidine-induced open channel block of K+ current in rat ventricle

1. The effects of quinidine on calcium-independent outward K+ currents in rat ventricular myocytes were studied using whole-cell patch clamp techniques. 2. Quinidine sulphate (6 microM) significantly prolonged repolarization of the ventricular action potential. This effect was larger during early repolarization (25% level) than at later times (90% level). 3. Quinidine reduced the amplitude of a transient outward current, and accelerated its rate of decay by approximately 4 fold at membrane potentials between 0 to +50 mV. Quinidine also reduced the amplitude of a slowly inactivating, tetraethylammonium-sensitive 'pedestal' component of the outward current. 4. The quinidine-induced block of the transient outward current was dependent on time and membrane potential. Maximal block occurred with depolarizations of about 100 ms duration, and longer depolarizations (up to 1.5 s) produced little additional block. The membrane potential dependence of quinidine-induced block was very similar to the membrane potential dependence of activation of the transient outward current. The membrane potential dependence of steady-state inactivation of the transient outward current was not significantly affected by quinidine. 5. These results show that quinidine blocks outward K+ currents in rat ventricular cells. The time and potential dependence of this block suggests that quinidine blocks the transient outward K+ current by acting primarily on the open state of these channels.

Different mechanisms of the inhibition of the transient outward current in rat ventricular myocytes

The mechanism of drug-induced inhibition of the transient outward current, Ito, has been investigated in rat ventricular myocytes using the whole cell patch clamp technique. Ito was activated by 300 ms depolarizing voltage clamp steps in 10 mV increments from -50 mV up to +40 mV. At +40 mV, Ito peaked after about 3 ms, and the time course of inactivation was appropriately described by two time constants, tau fast = 17 ms and tau slow = 203 ms. Verapamil, quinidine sulfate and nifedipine preferentially depressed Ito at the end of the 300 ms depolarizing voltage clamp step; the inactivation of Ito was accelerated by all drugs, whereas peak Ito was less affected. The time course of drug action at +40 mV was calculated by the fractional changes of Ito. Verapamil, quinidine sulfate and nifedipine exerted a block of Ito increasing during the depolarizing voltage clamp step. The onset of block in response to verapamil, quinidine sulfate and nifedipine (30 mumol/each) was appropriately described by monoexponential functions with time constants tau on = 9.3, 1.7 and 1.1 ms, respectively. Relief from block by verapamil, quinidine sulfate and nifedipine at -50 mV was assessed by comparison of the recovery process of peak Ito from inactivation with or without drugs. tau off amounted to 695 ms in the case of quinidine sulfate; verapamil and nifedipine did not significantly affect the recovery process so that the determination of the time course of relief from block was not possible.(ABSTRACT TRUNCATED AT 250 WORDS)

Anomalous permeation of Na+ through a putative K+ channel in rat superior cervical ganglion neurones

1. An unanticipated inward tail current was recorded from freshly isolated adult rat superior cervical ganglion (SCG) neurones using the whole-cell variant of the patch-clamp technique. The tail current was present when Na+ was substituted for tetraethylammonium (TEA) as the primary monovalent cation in external solutions designed to isolate Ca2+ channel currents (0.5 microM tetrodotoxin present and K+ omitted). 2. The tail current was observed following step potentials positive to -30 mV and reached half-activation near -9.0 mV. The decay of the tail current was voltage dependent and could be described with two time constants. Between potentials of -120 and -70 mV, tau f, the fast component, varied from 3 to 8 ms and tau s, the slow component, changed from 12 to 30 ms, respectively. 3. The tail current was not carried by Ca2+, and did not appear to flow through a voltage-gated Ca2+ channel or a Ca(2+)-dependent channel as it persisted in the absence of external Ca2+ or in the presence of the Ca2+ channel blocker, Cd2+ (0.1 mM). 4. Varying the external [Cl-] did not alter the reversal potential of the tail current indicating that Cl- was not the charge carrier. 5. The reversal potential of the tail current changed in accordance with the Nernst relationship when [Na+]i/[Na]o was altered. Our results suggested that this 'unusual or unanticipated current' (Iu) was carried primarily by Na+. 6. Iu was inhibited by the K+ channel-blocking agents quinidine (0.1 mM), external Ba2+ (5 mM) and internal Cs+ (145 mM). TEA (20 mM either internally or externally) and dendrotoxin (10 microM) were not effective inhibitors of Iu. 7. The decay time constants of the tail current and parameters of activation and inactivation of Iu were similar to those of TEA-insensitive delayed rectifier-type K+ channel currents observed in the presence of 145 mM external K+. 8. Iu was reduced in the presence of either external or internal K+. The interaction of external K+ with Na+ on the Iu tail amplitude was reminiscent of anomalous mole-fraction behaviour. 9. Ion permeability studies revealed that the channel producing Iu had a permeability sequence to monovalent cations of 3.5:2.5:2:1:0.5 for Rb+, K+, Cs+, Na+ and Li+, respectively. 10. These data suggest that in the absence of external K+, the ion selectivity of a TEA-insensitive K+ channel in sympathetic neurones is profoundly diminished. Under these conditions, Na+ traversing a K+ channel can generate an unanticipated inward current.(ABSTRACT TRUNCATED AT 400 WORDS)

Properties of the inactivating outward current in single smooth muscle cells isolated from the rat anococcygeus

The properties of the voltage- and time-dependent outward current in single smooth muscle cells isolated from the rat anococcygeus were studied. The outward current was activated by depolarizations to membrane potentials positive to -40 mV. Activation followed third order kinetics; at +20 mV, the time for the current to reach half its maximal amplitude was around 55 ms. The current inactivated with a time course that could best be described by a single exponential with a time constant around 1500 ms. The steady-state inactivation curve was voltage dependent over the range -110 to -30 mV, with a half-inactivation point of -67 mV. Recovery from inactivation followed an exponential time course with a time constant of around 770 ms at -90 mV. Deactivating tail current analysis revealed that a 10-fold change in the extracellular potassium ion concentration resulted in a 42 mV change in the reversal potential of the current. The current was blocked by 4-aminopyridine, tetraethylammonium, quinine and verapamil with IC50's--the concentrations producing 50% inhibition of the peak current--of 2 mM, 4 mM, 12 microM and 20 microM respectively. The current was not blocked by Toxin I (100 nM) or glibenclamide (10 microM). The current was still present in cells containing 5 mM EGTA; in these cells, replacing extracellular calcium with cadmium depressed the peak current by around 12%. This could be explained, at least in part, by a negative shift in the voltage dependence of inactivation.

Potassium transport in lamprey (Lampetra fluviatilis) erythrocytes: Evidence for K+ channels

1. Unidirectional K+ (86Rb) influx in lamprey red blood cells was studied under different conditions. 2. The influx of 86Rb was markedly inhibited by 1 mM Ba2+ when cells were incubated in saline containing 4 mM K+. In K(+)-free media, the influx rate constant of 86Rb was lower, and 1 mM Ba2+ had no blocking effect. 3. Treatment of the red cells with 0.1 mM ouabain in the absence of external K+ resulted in the appearance of the component of 86Rb influx inhibited by 1 mM Ba2+, quinine, TEA or amiloride. 4. Similar results were obtained in red cells incubated in Na(+)-free media MgCl2-sucrose. 5. The results obtained provide evidence for the existence of K+ channels in the red cell membrane of the lamprey. Under physiological conditions (in the presence of 4 mM K+) the total rate constant for the 86Rb influx in erythrocytes was about 1.9/hr, including ouabain-sensitive (0.6/hr), Ba(2+)-sensitive (1.1/hr) and residual (0.2/hr) components.

Kinetic description of the activation of the delayed potassium current of the land snail Zachrysia guanensis in terms of the Hodgkin-Huxley formalism

A description of the activation phase of the land snail Zachrysia guanensis delayed potassium current (IK) is presented. It was found that IK activation kinetics may be congruent with the Hodgkin-Huxley scheme if one assumes that the proportion of n particles at the beginning of the pulse is not zero. In this case IK activation may be treated as carried by a homogeneous channel population, which may be relevant in view of the reported heterogeneity of the inactivation phase of this current.

Differential responses of two identified neurons of the pond snail Lymnaea stagnalis to the convulsant drug pentylenetetrazol

The convulsant drug pentylenetetrazol (PTZ) induces tonic depolarization in the identified B1 neuron of Lymnaea stagnalis. Another identified neuron, right parietal dorsal 1 (RPD1), gives the opposite response: tonic hyperpolarization and cessation of spontaneous firing. These effects are mimicked by intracellular injection of calcium ions and reversed following injection of ethylene glycol-bis(beta-aminoethyl ether) N,N,N,'N'-tetraacetic acid (EGTA). Responses to PTZ are retained in the presence of extracellular cobalt ions to block calcium influx. Under voltage clamp, PTZ or injection of calcium ions induces a slow inward current in B1, which is abolished in zero sodium saline. In RPD1 the current response to PTZ or intracellular calcium ions is outward, and is blocked by potassium channel blockers. Thus, differential responses of the two neurons to PTZ appear to be mediated via increased intracellular calcium ions, leading to activation of specific ion currents in each cell type.

Whole-cell and single channel K+ and Cl- currents in epithelial cells of frog skin

Whole-cell and single channel currents were studied in cells from frog (R. pipiens and R. catesbiana) skin epithelium, isolated by collagenase and trypsin treatment, and kept in primary cultures up to three days. Whole-cell currents did not exhibit any significant time-dependent kinetics under any ionic conditions used. With an external K gluconate Ringer solution the currents showed slight inward rectification with a reversal potential near zero and an average conductance of 5 nS at reversal. Ionic substitution of the external medium showed that most of the cell conductance was due to K and that very little, if any, Na conductance was present. This confirmed that most cells originate from inner epithelial layers and contain membranes with basolateral properties. At voltages more positive than 20 mV outward currents were larger with K in the medium than with Na or N-methyl-D-glucamine. Such behavior is indicative of a multi-ion transport mechanism. Whole-cell K current was inhibited by external Ba and quinidine. Blockade by Ba was strongly voltage dependent, while that by quinidine was not. In the presence of high external Cl, a component of outward current that was inhibited by the anion channel blocker diphenylamine-2-carboxylate (DPC) appeared in 70% of the cells. This component was strongly outwardly rectifying and reversed at a potential expected for a Cl current. At the single channel level the event most frequently observed in the cell-attached configuration was a K channel with the following characteristics: inward-rectifying I-V relation with a conductance (with 112.5 mM K in the pipette) of 44 pS at the reversal potential, one open and at least two closed states, and open probability that increased with depolarization. Quinidine blocked by binding in the open state and decreasing mean open time. Several observations suggest that this channel is responsible for most of the whole-cell current observed in high external K, and for the K conductance of the basolateral membrane of the intact epithelium. On a few occasions a Cl channel was observed that activated upon excision and brief strong depolarization. The I-V relation exhibited strong outward rectification with a single channel conductance of 48 pS at 0 mV in symmetrical 112 mM Cl solutions. Kinetic analysis showed the presence of two open and at least two closed states. Open time constants and open probability increased markedly with depolarization.(ABSTRACT TRUNCATED AT 400 WORDS)

Quinidine-induced inhibition of the fast transient outward K+ current in rat melanotrophs

1. The effect of quinidine on the fast-activating, fast-inactivating potassium current (IK(f] in acutely dissociated melanotrophs of the adult rat pituitary was examined. Macroscopic currents were measured by use of the whole-cell configuration of the patch clamp technique. 2. Bath application of quinidine caused a dose-dependent reduction of the peak amplitude of IK(f). The Kd for blockade of IK(f) at 0 mV was estimated to be 41 +/- 5.6 microM. 3. Quinidine elicited a dose-dependent increase of the rate of the decay of IK(f) and this effect was enhanced by membrane depolarization. The possibility that this phenomenon reflects an open channel blocking reaction is discussed. 4. Quinidine also caused a 5 mV hyperpolarizing shift of the steady-state inactivation curve and increased the half-time for recovery from inactivation. Quinidine did not affect the onset of inactivation measured at -30 mV. 5. Internal quinidine did not appear substantially to affect either the peak amplitude or kinetics of IK(f). 6. A study of some structural analogues showed that hydroquinidine and quinacrine had effects similar to those of quinidine. The effect of quinacrine on the amplitude and kinetics of IK(f) was also pH-dependent. Cinchonine, which bears a close structural resemblance to quinidine, was much less effective as a blocker of IK(f).

Specificity of tetraethylammonium and quinine for three K channels in insulin-secreting cells

The effects of tetraethylammonium (TEA) and quinine on Ca-activated [K(Ca)], ATP-sensitive [K(ATP)]K channels and delayed-rectifier K current [K(dr)] have been studied in cultured insulin-secreting HIT cells using the patch-clamp technique. K(Ca) and K(ATP) channels were identified in excised, outside/out patches using physiological solutions and had unitary conductances of 60.8 +/- 1.3 pS (n = 31) and 15.4 +/- 0.3 pS (n = 40), respectively. Macroscopic K(dr) current (peak current = 607 +/- 100 pA at +50 mV, n = 14) were recorded in the presence of 100 microM cadmium and 0.5 microM tetrodotoxin. Tetraethylammonium (TEA) blocked all three channel types but was more effective on K(Ca) channels (EC50 = 0.15 mM) than on K(ATP) channels (EC50 = 15 mM) or K(dr) currents (EC50 = 3 mM). Quinine also blocked all three currents but was less effective on K(Ca) channels (EC50 = 0.3 mM) while equally effective against K(ATP) channels and K(dr) currents (EC50 = 0.025 mM). TEA blocked K(Ca) and K(ATP) channels by reducing their single-channel conductances and decreasing the probability of K(ATP) channel opening. Quinine blocked K(Ca) channels by reducing the single-channel conductance, but blocked K(ATP) channels by reducing the probability of channel opening. Reinterpretation of previous microelectrode studies in light of these findings suggest that, (i) only K(ATP) channels are active in low glucose, (ii) both K(Ca) and K(dr) channels may assist Ca-spike repolarization, and (iii) K(Ca) channels play no role in forming the burst pattern of Ca spiking in the B cell.

The effects of quinidine on sodium-dependent calcium efflux in isolated rod photoreceptors of the salamander retina

The effect of quinidine on the membrane current generated by the Na:Ca, K exchange has been investigated in the outer segment of isolated rod photoreceptors from the retina of the larval tiger salamander. The inward exchange current associated with the efflux of Ca2+ was selectively recorded by introducing a Ca2+ load through the light-sensitive channels, and then shutting these channels with a bright light. Quinidine (20-1000 microM) reduced the magnitude of the exchange current and slowed its decay during the removal of a Ca2+ load. Quinidine did not alter the form of the relation between the exchange current and the total concentration of exchangeable calcium remaining within the outer segment. [Ca]T, showing that it does not change the affinity of the exchange mechanism for internal Ca2+. The relation between exchange current inhibition and the quinidine concentration could be described by a simple Michaelis relation with a Ki of 287 microM and a maximum inhibition of 50%. The incomplete block of the Na:Ca, K exchange current by quinidine shows that it does not act by simple competition with external Na+, and suggests that the inhibition of the exchange by quinidine may be non-specific.

Quinine inhibits chloride and nonselective cation channels in isolated rat distal colon cells

Isolated cells from rat distal colon were investigated with the patch-clamp technique. In cell-attached and cell-excised patches (inside-out) single chloride channels with outward-rectifying properties were observed. In excised patches the single-channel conductance g was 47 +/- 5 pS at positive and 22 +/- 2 pS at negative clamp potentials (n = 6). The Cl- channel blocker 5-nitro-2-(3-phenylpropylamino)benzoic acid (NPPB, 10 microM) induced fast closing events, whereas 10 microM of 3',5-dichlorodiphenylamine-2-carboxylic acid (DCDPC) had no effect when applied to the cytosolic side. Quinine in the bath inhibited the Cl- channel by reducing its single-channel amplitude and increased open channel noise. With 0.1 mM the current amplitude decreased by 54% and with 1 mM quinine by 67%. Ca2(+)-dependent nonselective cation channels where observed after excision of the membrane patch. This channel was completely and reversibly inhibited by 100 microM DCDPC. Application of 1 mM quinine to the bath induced flickering and reduced the open-state probability from 0.94 to 0.44. In summary, besides its well established effects on K+ channels, quinine also inhibits nonselective cation channels and chloride channels by inducing fast closing events.

A delayed rectifier potassium current in Xenopus oocytes

A delayed voltage-dependent K+ current endogenous to Xenopus oocytes has been investigated by the voltage-clamp technique. Both activation and inactivation of the K+ current are voltage-dependent processes. The K+ currents were activated when membrane potential was depolarized from a holding potential of -90 to -50 mV. The peak current was reached within 150 ms at membrane potential of +30 mV. Voltage-dependent inactivation of the current was observed by depolarizing the membrane potential from -50 to 0 mV at 10-mV increments. Voltage-dependent inactivation was a slow process with a time constant of 16.5 s at -10 mV. Removal of Ca2+ from the bath has no effect on current amplitudes, which indicates that the current is Ca2+)-insensitive. Tail current analysis showed that reversal potentials were shifted by changing external K+ concentration, as would be expected for a K(+)-selective channel. The current was sensitive to quinine, a K+ channel blocker, with a Ki of 35 microM. The blockade of quinine is voltage-independent in the range of -20 to +60 mV. Whereas oocytes from the same animal have a relatively homogeneous current distribution, average amplitude of the K+ current varied among oocytes from different animals from 30 to 400 nA at membrane potential of +30 mV. Our results indicate the presence of the endogenous K+ current in Xenopus oocytes with characteristics of the delayed rectifier found in some nerve and muscle cells.

Effect of quinine on the release of catecholamines from bovine cultured chromaffin cells

1. The effects of quinine on catecholamine release from cultured bovine chromaffin cells were studied. 2. Quinine (25-400 microM) produced a dose-related inhibition of catecholamine release in response to depolarizing concentrations (12.5-50 mM) of K+. 3. The inhibition of the secretory response to high K+ produced by quinine decreased with the increase in the extracellular concentration of Ca2+. 4. Stimulation of cultured chromaffin cells with 50 mM K+ produced a significant increase in Ca2+ influx. In the presence of 100 microM quinine a 54% inhibition of the K(+)-induced Ca2+ influx was observed. 5. Quinine treatment of chromaffin cell cultures produced a small but significant decrease in membrane resting potential and a less pronounced depolarization in response to 50 mM K+. 6. The results suggest that the inhibition of the K(+)-evoked release of catecholamines produced by quinine is at least partly due to a decrease in Ca2+ influx. Ca2+ influx is lower because quinine reduces the sensitivity of the membrane potential to changes in extracellular K+ but direct effects of quinine on Ca2+ channels cannot be excluded.

Use-dependent action of antiarrhythmic drugs in frog skeletal muscle and canine cardiac Purkinje fiber

1. Conventional microelectrode techniques were used to study the effect of quinidine (10 microM), lidocaine (20 microM), and verapamil (3-10 microM) on action potential upstroke (V+ max) in frog skeletal muscle and dog Purkinje fiber. 2. The frequency-dependent nature of V+ max depression induced by these drugs was similar in both preparations, however, quinidine was more potent in skeletal muscle while lidocaine was in Purkinje fibers. 3. In skeletal muscle tetrodotoxin (3 and 15 nM) and low concentrations of antiarrhythmic drugs proportionally reduced the maximum velocity of depolarization and repolarization (V+ max and V- max, respectively), whereas V- max was more depressed than V+ max by high concentrations (50-200 microM) of antiarrhythmics. Decreases in the overshoot potential were proportional to the V+ max block in the case of each drug. 4. These results indicate that therapeutically relevant concentrations of quinidine and lidocaine inhibit skeletal muscle Na+ channels in a use-dependent manner similar to heart, while at higher concentrations the K+ channels may also be blocked. Therapeutic implications of the results are discussed.

Effect of antiarrhythmic drugs, TTX, and 4-aminopyridine on repetitive electrical activity in frog skeletal muscle

1. Conventional microelectrode techniques were used to study the effects of antiarrhythmic drugs (quinidine, 2-20 microM; lidocaine, 5-50 microM; verapamil, 2-20 microM), 4-aminopyridine (4-AP, 50-100 microM), and tetrodotoxin (TTX, 1.5-6 nM) on repetitive electrical discharges induced in the muscle membrane in the presence of 1 microM cevadine. 2. Antiarrhythmic drugs and 4-AP produced progressive reduction of the maximum upstroke velocity (V+ max) of the discharges, while the cycle length was prolonged by each drug except 4-AP. 3. The efficacy in depression of V+ max and prolongation of cycle length was not proportional in the case of individual drugs. 4. A simple model of the repetitive activity incorporating drug-effects was presented. The cevadine-modified Na+ channels could be blocked by antiarrhythmic agents, however, the efficacy of these drugs on the normal and cevadine-modified Na+ channels were found to be different.

Quinine potently blocks single K+ channels activated by dopamine D-2 receptors in rat corpus striatum neurons

In single channel recordings from acutely dissociated neurons of the rat corpus striatum, a membrane K+ channel which is activated by dopamine D-2 receptors was blocked by nanomolar concentrations of quinine. An intermittent partial blockade was observed at 4-10 nM quinine, with a voltage dependence consistent with quinine binding to the channel near the extracellular surface of the membrane. A nearly complete blockade of channel current was observed at 100 nM quinine and above. Such concentrations are known to be too low to block various other ion channels, and may be attained in human brain at antimalarial dosages of quinine. Blockade of this channel by quinine may provide a useful experimental probe of dopaminergic function, as an alternative to D-2 receptor binding site blockade by neuroleptics.

Complete separation of four potassium currents in Drosophila

A number of voltage-activated and Ca2+ activated K+ currents are known to coexist and play a major role in a wide variety of cellular processes including neuromuscular phenomena. Separation of these currents is important for analyzing their individual functional roles and for understanding whether or not they are mediated by entirely different channels. In Drosophila, we have now been able to manipulate four different K+ currents, individually and in combination with one another, by a combined use of mutations and pharmacological agents. This allows analysis of the physiological and molecular properties of different K+ channels and of the role of individual currents in membrane excitability.

Protein kinase C activators reduce the inositol trisphosphate-induced outward current and the Ca2+-activated outward current in identified neurons of Aplysia

Effects of intracellularly injected activators of protein kinase C on the InsP3-induced K+ current and the Ca2+-activated K+ current recorded from identified neurons (R9-R12) of Aplysia kurodai were investigated with conventional voltage-clamp and pressure-injection techniques. Intracellular injection of InsP3 into identified neurons produced a 4-aminopiridine (4-AP)-resistant, tetraethylammonium (TEA)-sensitive, and quinidine-sensitive K+ current similar to the Ca2+ activated K+ current elicited by direct injection of Ca2+ ions into the same neurons. The diacylglycerol analogue 1,2-oleoylacetylglycerol (OAG) at an intracellular concentration of 65 nM produced irreversible decreases in both the InsP3-induced K+ current and the Ca2+-activated K+ current. The phorbol 12,13-dibutyrate (PDBu) at an intracellular concentration of 150 nM also decreased irreversibly both the InsP3-induced K+ current and the Ca2+-activated K+ current. These results suggest that protein kinase C activators reduce both the InsP3-induced K+ current and the Ca2+-activated K+ current recorded from certain identified neurons of Aplysia and that protein kinase C reduces the ability of Ca2+ to open K+ channels rather than affecting the ability of InsP3 to release Ca2+ from intracellular stores.

Differential effects of pentylenetetrazole on ion currents of Aplysia neurones

The effect of the convulsant drug pentylenetetrazole (PTZ) on separated membrane current components has been studied in identified voltage-clamped Aplysia neurones. External PTZ blocks the voltage-dependent Na+, Ca2+ currents and the delayed rectifier current (INa, ICa and IK,V, respectively). The amplitude of the Ca2+-activated K+ current (IK,Ca) is increased. The amplitude of the fast inactivating K+ current (IA) is transiently increased at low concentrations of PTZ but is depressed at higher concentrations or after long-lasting application of the drug. The effect of PTZ on leakage current (IL) seems to depend on the cell type. In some cells (R-15, L-7, LP-1) IL is decreased while it is increased in other cells (L-11, BL-1, BR-1). PTZ accelerates the inactivation of IK,V and IA and shifts the current-voltage relation of ICa to negative voltages by 5-8 mV. Pressure injection of PTZ into the neurone did not affect IK,V or IK,Ca. Thus PTZ seems to act on the outside of the plasma membrane. The effect of external PTZ on INa, ICa, IK,V and IL is also observed if the internal Ca2+ activity is buffered with EGTA suggesting that an increase in the internal Ca2+ activity is not involved. At -40 mV PTZ induces a tetrodotoxin-insensitive inward current carried by Na+ ions. PTZ transforms the beating pacemaker cell L-11 into a bursting pacemaker and the bursting pacemaker cell R-15 exhibits 'square-wave'-like oscillations of the membrane potential.

Ba2+-inhibitable 86Rb+ fluxes across membranes of vesicles from toad urinary bladder

86Rb+ fluxes have been measured in suspensions of vesicles prepared from the epithelium of toad urinary bladder. A readily measurable barium-sensitive, ouabain-insensitive component has been identified; the concentration of external Ba2+ required for half-maximal inhibition was 0.6 mM. The effects of externally added cations on 86Rb+ influx and efflux have established that this pathway is conductive, with a selectivity for K+, Rb+ and Cs+ over Na+ and Li+. The Rb+ uptake is inversely dependent on external pH, but not significantly affected by internal Ca2+ or external amiloride, quinine, quinidine or lidocaine. It is likely, albeit not yet certain, that the conductive Rb+ pathway is incorporated in basolateral vesicles oriented right-side-out. It is also not yet clear whether this pathway comprises the principle basolateral K+ channel in vivo, and that its properties have been unchanged during the preparative procedures. Subject to these caveats, the data suggest that the inhibition by quinidine of Na+ transport across toad bladder does not arise primarily from membrane depolarization produced by a direct blockage of the basolateral channels. It now seems more likely that the quinidine-induced elevation of intracellular Ca2+ activity directly blocks apical Na+ entry.

Ionic current of an identifiable giant neurone, d-RPLN, of an African giant snail (Achatina fulica Férussac), measured under voltage clamping--II. Outward currents

1. The outward currents of d-RPLN (dorsal-right parietal large neurone), one of the largest identifiable neurones of an African giant snail, were studied. 2. At the holding potential (-90 mV) and at the command voltage (Vc20 mV), the current values were 3.05 +/- 0.13 microA (M +/- SE) for the peak (n = 38), and 1.96 +/- 0.10 microA for the plateau (n = 37). 3. The peak time constant (Vc = 0 mV) was 2.05 +/- 0.08 msec. 4. Tetraethylammonium at 50 mM reduced the plateau value up to 50-55% of the normal, but had little effect on the peak. 5. 5-Aminopyridine at 5.0 mM diminished the peak value to about 50-55%, and delayed the peak time. 6. Quinine at 0.25 mM decreased both the peak and the plateau approximately to 55-65% of their controls, but shortened the peak time when Vc was beyond 0 mV, in contrast to the case of 4-AP. 7. The calcium-free state (replaced with cobalt) reduced these currents to about 75% of the normal, and evidently delayed the peak time.

Actions of quinidine and apamin on after-hyperpolarization of the spike in circular smooth muscle cells of the guinea-pig ileum

The effects of quinine and quinidine on membrane potential and action potential were investigated in circular smooth muscle of the guinea-pig ileum and the findings compared with the actions of apamin. In addition to results obtained from microelectrode experiments, the actions of quinidine and apamin on membrane currents were assessed using the single cell voltage clamp method. Quinine (above 0.2 mmol/l) and quinidine (above 0.08 mmol/l) depolarized the membrane, increased the membrane resistance and blocked generation of the after-hyperpolarization of the spike. Higher concentrations of both agents reduced the amplitude of the action potential and further depolarized the membrane. Quinidine and quinine possessed much the same action, with the former being more potent than the latter. Apamin, an inhibitor of the Ca-dependent K current, did not inhibit the after-hyperpolarization of the spike and had no effect on the membrane potential. In voltage clamp experiments, a depolarizing pulse (above -30 mV from -60 mV; 200 ms duration) elicited an inward current, followed by an outward current. With application of 2.5 mmol/l Mn instead of Ca, the outward current was subclassified into the Mn sensitive (Ca-dependent) and Mn resistant (voltage-dependent) K currents. Apamin (0.1 mumol/l) did not modify membrane currents evoked in the circular muscle cell, while, 0.1 mmol/l quinidine inhibited both the Ca- and voltage-dependent K outward currents, and Ca inward current. Our observation suggest that apamin-insensitive Ca-dependent K channels are present in the smooth muscle membrane and that they probably participate in the falling phase and after-hyperpolarization of the action potential.

Differentiation of two distinct K conductances in the basolateral membrane of turtle colon

The K conductance of the basolateral membrane of turtle colon was measured in amphotericin-treated cell layers under a variety of ionic conditions. Changing the composition of the bathing solutions changed not only the magnitude but also the physical properties of the basolateral K conductance. The results are consistent with the notion that altered ionic environments can lead to changes in the relative abundance of two different populations of K channels in the basolateral membrane, which can be differentiated on the basis of pharmacological specificity, ion selectivity, and tracer kinetics. In the following article (Germann, W. J., S. A. Ernst, and D. C. Dawson, 1986, Journal of General Physiology, 88:253-274), we present evidence consistent with the hypothesis that one of these conductances was due to the same channels that give rise to the normal resting basolateral K conductance of the transporting cells, while the other was associated with experimental maneuvers that led to extreme swelling of the epithelial cells.

Effects of quinidine and quinine on the excitability of pyramidal neurons in guinea-pig hippocampal slices

Effects of quinidine (25 microM-1mM) and its stereoisomer, quinine (1-5 mM), on the excitability of CA3 pyramidal neurons were investigated in guinea-pig hippocampal slices using intracellular recording techniques. At concentrations of quinidine higher than 100 microM (and higher than 1 mM for quinine), 1) the resting potential shifted to the depolarizing direction with an increase of the input resistance, 2) the spike duration was prolonged, 3) the spike amplitude was decreased, 4) the late component of the afterhyperpolarization (AHP) (caused by the activity of the Ca2+-mediated K conductance) were suppressed, and 5) finally, neurons became inexcitable. The results indicate that the blocking action of quinidine and quinine is not specific to the Ca2+-mediated K conductance in mammalian hippocampal neurons, and that this conductance is much less sensitive to the drugs in comparison with other preparations.

Inhibition of Ca2+-activated K+ channels in pig pancreatic acinar cells by Ba2+, Ca2+, quinine and quinidine

Patch-clamp whole-cell and single-channel current recordings were made from pig pancreatic acinar cells to test the effects of quinine, quinidine, Ba2+ and Ca2+. Voltage-clamp current recordings from single isolated cells showed that high external concentrations of Ba2+ or Ca2+ (88 mM) abolished the outward K+ currents normally associated with depolarizing voltage steps. Lower concentrations of Ca2+ only had small inhibitory effects whereas 11 mM Ba2+ almost blocked the K+ current. 5.5 mM Ba2+ reduced the outward K+ current to less than 30% of the control value. Both external quinine and quinidine (200-500 microM) markedly reduced whole-cell outward K+ currents. In single-channel current studies it was shown that external Ba2+ (1-5 mM) markedly reduced the probability of opening of high-conductance Ca2+ and voltage-activated K+ channels whereas internal Ba2+ (6 X 10(-6) to 3 X 10(-5) M) caused activation at negative membrane potentials and inhibition at positive potentials. Quinidine (200-400 microM) evoked rapid chopping of single K+ channel openings acting both from the outside and inside of the membrane and in this way markedly reduced the total current passing through the channels.

Potassium channels in cultured bovine adrenal chromaffin cells

K channels of bovine adrenal chromaffin cells were studied using patch-clamp techniques. Whole-cell K currents measured near +10 mV were much larger in 1 mM-external Ca than in Ca-free saline. Noise analysis suggested that this Ca-dependent current was carried by a large unitary conductance channel, called BK channel, which was previously described in inside-out patches (Marty, 1981). The Ca-dependent K current near +10 mV declined with time due to 'run-down' of Ca channels. At the same time, a fraction of the outward current observed above +50 mV was also eliminated. This outward current component probably represents K efflux through Ca channels. Whole-cell Ca-dependent K currents were studied using various Ca buffers. EGTA buffers were surprisingly inefficient: in order to block the current entirely, it was necessary to use an isotonic EGTA solution and to increase internal pH. 1,2-bis(o-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid (BAPTA) was at least five times more efficient than EGTA. In isolated patches three types of single-channel K currents were observed. Under normal ionic conditions (140 mM-K inside, 140 mM-Na outside), the unitary conductances measured between -20 and +40 mV were 96 pS, 18 pS and 8 pS. The 96 pS channels are the Ca-dependent BK channels. 18 pS and 8 pS channels were both activated and then inactivated by membrane depolarization. Both displayed complex kinetics; single-channel currents were grouped in bursts. Activation and inactivation kinetics were faster for the 18 pS channel (therefore termed FK channel, for fast K channel) than for the 8 pS channel (SK channel, for slow or small amplitude channel). The voltage dependence of opening probability was steeper for the FK channel as compared to the SK channel.

Ca2+-activated K+ permeability in human erythrocytes: modulation of single-channel events

Elevated levels of intracellular Ca2+ activate a K+-selective permeability in the membrane of human erythrocytes. Currents through single channels were analysed in excised inside-out membrane patches. The effects of several ions that are known to inhibit K+ fluxes are described with respect to the single-channel events. The results suggest that the blocking ions can partly move into the channels (but cannot penetrate) and interact with other ions inside the pore. The reduction of single-channel conductance by Cs+, tetraethylammonium and Ba2+ and of single-channel activity by quinine and Ba2+ is referred to different rates of access to the channel. The concentration- and voltage-dependent inhibition by ions with measurable permeability (Na+ and Rb+) can be explained by their lower permeability, with single-file movement and ionic interactions inside the pore.