Effects of monomethyltin and dimethyltin compounds on heterologously expressed neuronal ion channels (Xenopus oocytes) and synaptic transmission (hippocampal slices).

The aim of this study was to investigate the effects of monomethyltin trichloride (MMT) and dimethyltin dichloride (DMT) on various neuronal ion channels heterologously expressed in Xenopus oocytes and on synaptic transmission in hippocampal slices of young (14-21 days old) and adult (2-4 months old) rats. The Xenopus oocyte expression system was chosen to allow direct assessment of the effects of MMT and DMT both on glutamate receptors sensitive to AMPA and NMDA and on various voltage-operated potassium and sodium channels. Hippocampal slices were used to analyze the effects of MMT and DMT on synaptic potentials generated by the important excitatory Schaffer collateral-CA1 synapse. In general, MMT and DMT were found to have no effect either on voltage-operated sodium and potassium channels or on the metabotropic glutamate receptor but they did differentially affect the functions of ionotropic glutamate receptors and glutamatergic synaptic transmission. MMT (100 microM) significantly reduced NMDA-mediated ion currents by up to 32%, but had no effect on ion currents through AMPA receptors. In slices of adult rats, MMT had no effect on the amplitudes of evoked fEPSPs and brought about a 35% reduction in the LTP amplitudes. In contrast, in slices of young rats MMT evoked a reversible 30% increase in the amplitudes of fEPSPs but had no effect on LTP induction. DMT (100 microM) reduced ion currents through NMDA-receptor ion channels by up to 29% and those through AMPA-receptor ion channels by up to 7%. In hippocampal slices 100 microM DMT reduced the amplitudes of fEPSPs (adults: 50%; young rats: 70%) and LTP (adults: 40%; young rats: 55%). Neither of the organotins affected the paired-pulse facilitation at this synapse, indicating that the organotins exert their effects at the postsynaptic site. The action of MMT and DMT may contribute to the organotin-induced impairment of behavior patterns in connection with learning and memory.

Lowering of the potassium concentration induces epileptiform activity in guinea-pig hippocampal slices.

Extra- and intracellular recording techniques were used to study the epileptiform activity generated by guinea-pig hippocampal slices perfused with low potassium containing artificial cerebrospinal fluid. Extracellular field potentials were recorded in CA1 and CA3 regions along with intracellular recordings in CA3 subfield. Reduction of the extracellular potassium concentration [K(+)](o) from 4 to 2 mM caused a transient neuronal hyperpolarisation which was followed by a repolarisation and subsequent depolarisation period. Paroxysmal depolarisation shifts occurred during the transient hyperpolarisation period while epileptic field potentials (EFP) appeared in the late repolarisation or early depolarisation phase. EFP elicited by reduction of [K(+)](o) were neither affected by blockade of N-methyl-D-aspartate (NMDA) glutamate-subreceptor or gamma aminobutyric acid receptor, nor by application of the organic calcium channel blocker nifedipine or the anticonvulsant drugs carbamazepine and valproic acid. Upon application of non-NMDA glutamate-subreceptor blocker the EFP were abolished in all trials, while application of the organic calcium channel blocker verapamil only suppressed the EFP in some cases. The results point to a novel mechanism of epileptogenesis and may provide an in vitro model for the development of new drugs against difficult-to-treat epilepsy.

Plasma membrane protein clusters appear in CFTR-expressing Xenopus laevis oocytes after cAMP stimulation.

Membrane trafficking of the cystic fibrosis transmembrane conductance regulator (CFTR) is supposed to be an important mechanism controlled by the intracellular messenger cAMP. This has been shown with fluorescence techniques, electron microscopy and membrane capacitance measurements. In order to visualize protein insertion we applied atomic force microscopy (AFM) to inside-out oriented plasma membrane patches of CFTR-expressing Xenopus laevis oocytes before and after cAMP-stimulation. In a first step, oocytes injected with CFTR-cRNA were voltage-clamped, verifying successful CFTR expression. Water-injected oocytes served as controls. Then, plasma membrane patches were excised, placed (inside out) on glass and scanned by AFM. Before cAMP-stimulation plasma membranes of both water-injected and CFTR-expressing oocytes contained about 200 proteins per micron 2. Molecular protein masses were estimated from molecular volumes measured by AFM. Before cAMP-stimulation, protein distribution showed a peak value of 11 nm protein height corresponding to 475 kDa. During cAMP-stimulation with 1 mM isobutylmethylxanthine (IBMX) plasma membrane protein density increased in water-injected oocytes to 700 proteins per micron 2 while the peak value shifted to 7 nm protein height corresponding to 95 kDa. In contrast, CFTR-expressing oocytes showed after cAMP-stimulation about 400 proteins per micron 2 while protein distribution exhibited two peak values, one peak at 10 nm protein height corresponding to 275 kDa and another one at 14 nm corresponding to 750 kDa. They could represent heteromeric protein clusters associated with CFTR. In conclusion, we visualized plasma membrane protein insertion upon cAMP-stimulation and quantified protein distribution with AFM at molecular level. We propose that CFTR causes clustering of plasma membrane proteins.

Blocking effects of the antiarrhythmic drug propafenone on the HERG potassium channel.

Propafenone has been shown to affect the delayed-rectifier potassium currents in cardiomyocytes of different animal models. In this study we investigated effects and mechanisms of action of propafenone on HERG potassium channels in oocytes of Xenopus laevis with the two-electrode voltage-clamp technique. Propafenone decreased the currents during voltage steps and the tail currents. The block was voltage-dependent and increased with positive going potentials (from 18% block of tail current amplitude at -40 mV to 69% at +40 mV with 100 micromol/l propafenone). The voltage dependence of block could be fitted with the sum of a monoexponential and a linear function. The fractional electrical distance was estimated to be delta=0.20. The block of current during the voltage step increased with time starting from a level of 83% of the control current. Propafenone accelerated the increase of current during the voltage step as well as the decay of tail currents (time constants of monoexponential fits decreased by 65% for the currents during the voltage step and by 37% for the tail currents with 100 micromol/l propafenone). The threshold concentration of propafenone effect was around 1 micromol/l and the concentration of half-maximal block (IC50) ranged between 13 micromol/l and 15 micromol/l for both current components. With high extracellular potassium concentrations, the IC50 value rose to 80 degrees mol/l. Acidification of the extracellular solution to pH 6.0 increased the IC50 value to 123 micromol/l, alkalization to pH 8.0 reduced it to 10 micromol/l and coexpression of the beta-subunit minK had no statistically significant effect on the concentration dependence. In conclusion, propafenone has been found to block HERG potassium channels. The data suggest that propafenone affects the channels in the open state and give some hints for an intracellular site of action.

Expression and functional characterization of the mt1 melatonin receptor from rat brain in Xenopus oocytes: evidence for coupling to the phosphoinositol pathway.

Melatonin-sensitive receptors were expressed in Xenopus laevis oocytes following an injection of mRNA from rat brain. The administration of 0.1-100 micromol/L melatonin to voltage-clamped oocytes activates calcium-dependent chloride currents via a pertussis toxin-sensitive G protein and the phosphoinositol pathway. To determine which melatonin receptor type (mt1, MT2, MT3) is functionally expressed in the Xenopus oocytes, we used (i) agonists and antagonists of different receptor types to characterize the pharmacological profile of the expressed receptors and (ii) a strategy of inhibiting melatonin receptor function by antisense oligonucleotides. During pharmacological screening administration of the agonists 2-iodomelatonin and 2-iodo-N-butanoyl-5-methoxytryptamine (IbMT) to the oocytes resulted in oscillatory membrane currents, whereas the administration of the MT3 agonist 5-methoxycarbonylamino-N-acetyltryptamine (GR135,531) exerted no detectable membrane currents. The melatonin response was abolished by a preceding administration of the antagonists 2-phenylmelatonin and luzindole but was unaffected by the MT3 antagonist prazosin and the MT2 antagonist 4-phenyl-2-propionamidotetralin (4-P-PDOT). In the antisense experiments, in the control group the melatonin response occurred in 45 of 54 mRNA-injected oocytes (83%). Co-injection of the antisense oligonucleotide, corresponding to the mt1 receptor mRNA, caused a marked and significant reduction in the expression level (13%; P < 0.001). In conclusion, the results demonstrate that injection of mRNA from rat brain in Xenopus oocytes induced the expression of the mt1 receptor which is coupled to the phosphoinositol pathway.

Reduction of voltage-operated sodium currents by the anticonvulsant drug sulthiame.

The effect of the sulfonamide derivative sulthiame (Ospolot) on voltage-operated sodium channels was investigated in acutely isolated neurons from the guinea pig hippocampus using the whole-cell patch-clamp technique. Sulthiame in a concentration of 10 microg/ml reduced the inactivating sodium currents without affecting potassium currents. The effect was not dependent on voltage. At therapeutic concentration of 1 to 10 microg/ml sodium currents were reduced by 13 to 25% of control. Reductions of this size (induced by the specific sodium channel blocker tetrodotoxin or by 10 microg/ml sulthiame itself) impaired repetitive generation of action potentials and reduced the maximum discharge frequency by 20 to 40%. In summary, the anticonvulsant drug sulthiame exerts blocking effects on sodium channels which can be assumed to be anticonvulsant and to be different from the effects induced by blockade of carbonic anhydrase.

Lowering the extracellular potassium concentration elicits epileptic activity in neocortical tissue of epileptic patients.

The increase in the extracellular potassium concentration ([K(+)](o)) is a well-established model of epilepsy (the so-called high potassium model). Therefore, it is generally accepted that for the prevention of abnormal excitability and seizure generation, increases of [K(+)](o) must be avoided. In this paper, however, we show that on the contrary, a reduction of [K(+)](o) also elicits epileptic activity in brain slices of man.

Effects of antiarrhythmic drugs on cloned cardiac voltage-gated potassium channels expressed in Xenopus oocytes.

The effects of 17 commonly used antiarrhythmic drugs on the rapidly activating cardiac voltage-gated potassium channels (Kv1.1, Kv1.2, Kv1.4, Kv1.5, Kv2.1 and Kv4.2) were studied in the expression system of the Xenopus oocyte. A systematic overview on basic properties was obtained using a simple and restricted experimental protocol (command potentials 10 mV and 50 mV positive to the threshold potential; concentration of 100 micromol/l each). The study revealed that 8 of 17 drugs yielded significant effects (changes >10% of control) on at least one type of potassium channel in the oocyte expression system. These drugs were ajmaline, diltiazem, flecainide, phenytoin, propafenone, propranolol, quinidine and verapamil, whereas the effects of adenosine, amiodarone, bretylium, disopyramide, lidocaine, mexiletine, procainamide, sotalol and tocainide were negligible. The drug effects were characterized by reductions of the potassium currents (except for quinidine and ajmaline). A voltage-dependence of drug effect was found for quinidine, verapamil and diltiazem. The different effect of the drugs was not related to the fast or slow current inactivation of the potassium channels (except for verapamil). Profiles of the individual drug effects at the different potassium channel types were identical for propafenone and flecainide and differed for all other substances. The study demonstrates marked differences in sensitivity to antiarrhythmic drugs within the group of voltage-operated cardiac potassium channel types. Taking the restrictions of the oocyte system into consideration, the findings suggest that several antiarrhythmic drugs exert significant effects at rapidly activating cardiac potassium channels.

Sensitivity of native and cloned hippocampal delayed-rectifier potassium channels to verapamil.

The effects of the phenylalkylamine verapamil on native and cloned hippocampal voltage-operated potassium channels were investigated. Native channels were studied in acutely isolated CA1 neurons from the guinea pig with the whole-cell patch-clamp technique. Cloned channels were expressed in oocytes of Xenopus laevis and studied with the two-electrode voltage-clamp technique. Native potassium channels: Verapamil suppressed the potassium currents in micro- and submicromolar concentrations. The current suppression increased during the voltage step. The IC50 value of verapamil was 3 micromol/l and the Hill coefficient was 0.5 indicating a mixed population of potassium channels with distinct verapamil sensitivity. Cloned potassium channels: The hippocampal potassium channels Kv1.1, Kv1.2, Kv1.3, Kv2.1, Kv3.1 and Kv3.2 were affected by verapamil in micromolar concentrations. The effect increased with depolarization time, was voltage-dependent, reached 90% of the maximum within around 40 s after start of verapamil application, recovered slowly after wash-out and did not reach control values even after wash-out times of six minutes. The IC50 values differed markedly and were 35 micromol/l for the Kv1.1 channel, 98 micromol/l for the Kv1.2 channel, 12 micromol/l for the Kv1.3 channel, 226 micromol/l for the Kv2.1 channel, 6 micromol/l for the Kv3.1 channel and 11 micromol/l for the Kv3.2 channel.

Do neurons have a reserve of sodium channels for the generation of action potentials? A study on acutely isolated CA1 neurons from the guinea-pig hippocampus.

The density of voltage-gated sodium channels is high in several regions of the neuronal membrane. It is unclear if this density of channels represents a reserve for the neuron, or if it fulfils a special role in action potential firing. This problem was addressed by studying sodium currents and action potentials in acutely isolated hippocampal CA1 neurons whose number of active sodium channels was acutely changed by applying the sodium channel blocker tetrodotoxin (TTX) at different concentrations. The results show that more than a third of the sodium channels can fail without affecting the single action potential. Thus, the neurons have a remarkable surplus of sodium channels. The surplus, however, is necessary for repetitive action potential firing, as every decrease in the fraction of sodium channels reduces the maximal frequency of action potentials that can be generated by the neuron.

[New knowledge in arrhythmogenesis--role of ion channels and genetic aspects]. / Neue Erkenntnisse in der Arrhythmiegenese--Die Rolle der Ionenkanäle und genetische Aspekte.

Recent advances in molecular biology have had a major impact on our understanding of the mechanisms of human diseases. Electrophysiology is one of the areas which, besides others, has substantially benefited from this development. Our understanding of the structure, function and mechanisms of the regulation of ion channels as well as their contribution to the pathogenesis of cardiac arrhythmias has substantially increased. The results of these studies are not only of special interest from the scientific point of view. It is likely to assume that, in the future, they will increasingly influence the diagnosis and treatment of arrhythmias.

Ceasing of movement-disorder attacks immediately after the onset of pregnancy: possible effect of human chorionic gonadotropin.

In a woman with paroxysmal kinesiogenic choreoathetosis, attacks ceased within a few days after conception. An effect of human chorionic gonadotrophin is assumed, since this hormone decreased sodium currents and excessive action potential generation in an experimental approach.

Effects of 2-phenoxyethanol on N-methyl-D-aspartate (NMDA) receptor-mediated ion currents.

The actions were examined of 17 frequently used glycol ether compounds on the glutamate receptor-mediated ion currents. The receptors were expressed in Xenopus oocytes by injection of rat brain mRNA. Most of the 17 glycol ethers exerted no effects on the glutamate subreceptors activated by kainate and N-methyl-D-aspartate (NMDA), whereas 2-phenoxyethanol (ethylene glycol monophenyl ether) caused a considerable reduction of NMDA-induced membrane currents in a reversible and concentration-dependent manner. The threshold concentration of the ethylene glycol monophenyl ether effect was < 10 mumol/l. The concentration for a 50% inhibition (IC50) was approximately 360 mumol/l. The results indicate a neurotoxic potential for 2-phenoxyethanol.

Bacillus stearothermophilus lctB gene gives rise to functional K+ channels in Escherichia coli and in Xenopus oocytes.

We have cloned a small K+ channel subunit (LctB) of the gram-positive bacterium Bacillus stearothermophilus (B. stearo.). The B. stearo. LctB protein is only 134 amino acids long. The sequence contains a typical K+ channel P-domain with a K+ channel GYGD signature sequence and two hydrophobic, possibly membrane-spanning segments M1 and M2. Unexpectedly, LctB K+ channels exhibited properties which differed markedly from the ones reported for KcsA channels of the gram-positive bacterium Streptomyces lividans. LctB channels, when expressed in E. coli, were targeted to the outer membrane and not like KcsA channels to the inner membrane. After reconstitution in black lipid membrane, LctB channels mediated K+ currents at neutral pH. They were apparently not gated by pH like KcsA channels. Also, LctB cRNA produced functional LctB channels in the Xenopus oocyte expression system in marked contrast to KcsA. The results demonstrated that heterologous expression produced functional LctB channels both in E. coli and in Xenopus oocytes. It is proposed that bacterial LctB subunits can be properly handled by the Xenopus oocyte leading to the occurrence of functional LctB K+ channels in the oocyte plasma membrane.

Characterization of ion currents elicited by a stream of fluid during spontaneous and ligand-induced chloride current oscillation in Xenopus laevis oocytes.

During Ca2+-activated C- current oscillations a mechanical deformation of the Xenopus laevis oocyte by a fluid stream evokes transient inward currents of high amplitude (stream evoked inward current, Ii,st). This current can be observed either in native or RNA-injected oocytes expressing ligand-controlled ion channels from rat brain. Ii,st reversed at the equilibrium potential of chloride and was blocked by 9-anthracene carboxylic acid (2 mM). Power spectral analysis of the oscillations did not reveal a correlation between the features of the oscillations and the amplitude of Ii,st. Antagonists of stretch-activated cation channels [gadolinium (100 microM) and lanthanum (1mM)] did not block Ii,st. Calcium channel blockers [cobalt and manganese (10 mM)] did not inhibited Ii,st and Ii,st could also be elicited in calcium-free medium. Preloading oocytes with pertussis toxin (PTX) for 17 h prevented current oscillations and Ii,st caffeine (10 mM), an antagonist of the liberation of calcium from intracellular stores, inhibited Ii,st. Our results proride evidence for modulation of the mechanosensitivity of chloride currents by activation of intracellular second messenger cascades.

Divergent effect of acute ventricular dilatation on the electrophysiologic characteristics of d,l-sotalol and flecainide in the isolated rabbit heart.

INTRODUCTION: The interaction between acute ventricular dilatation (AVD) as one aspect of ventricular dysfunction and Class I and III antiarrhythmic drugs is uncertain. We therefore investigated the effects of AVD on the electrophysiologic properties of d,l-sotalol and flecainide. METHODS AND RESULTS: The isolated rabbit heart was used as a model of AVD. The ventricular size and, therefore, the diastolic pressure were modified by sudden volume changes of a fluid-filled balloon placed in the left ventricle. Pacing was performed alternately using epi- and endocardial monophasic action potential (MAP)-pacing catheters at cycle lengths from 1,000 to 300 msec. d,l-Sotalol (10 microM) resulted in a significant (P < 0.05) lengthening of refractoriness (+13.5% +/- 3.1%), MAP duration (+14.9% +/- 3.2%), and QT interval (+15.5% +/- 4.1%) (mean +/- SEM at 1,000 msec). These effects had a reverse rate-dependence. AVD to a diastolic pressure of 30 mmHg reduced refractoriness and left ventricular MAP duration. In comparison with the control group with the same extent of AVD, d,l-sotalol still led to a significant prolongation of repolarization for all cycle lengths except 300 msec, so that its effects were not absolutely but relatively preserved. In contrast, flecainide (2 microM) had no significant effects on refractoriness or MAP duration. It led to a significant, rate-dependent increase of pacing thresholds (+47.6% +/- 8.2%), prolongation of QRS (+48.8% +/- 5.6%), and conduction time (+78.6% +/- 8.6%) (mean +/- SEM at 300 msec). In the flecainide group, AVD significantly increased the normal rate-dependent prolongation of QRS (+16.7% +/- 5.5%) and conduction time (+17.1% +/- 4.3%). CONCLUSION: Our data demonstrate that, during AVD, the Class III effect of d,l-sotalol is preserved, whereas flecainide's effect of slowing conduction is exaggerated. This may contribute to flecainide-related proarrhythmia in certain clinical situations.

Effects of Pb2+ on delayed-rectifier potassium channels in acutely isolated hippocampal neurons.

Effects of Pb2+ on delayed-rectifier potassium channels in acutely isolated hippocampal neurons. J. Neurophysiol. 78: 2649-2654, 1997. The effects of Pb2+ on delayed-rectifier potassium currents were studied in acutely isolated hippocampal neurons (CA1 neurons, CA3 neurons, granule cells) from the guinea pig using the patch-clamp technique in the whole cell configuration. Pb2+ in micromolar concentrations decreased the potassium currents in a voltage-dependent manner, which appeared as a shift of the current-voltage relation to positive potentials. The effect was reversible after washing. The concentration-responsiveness measured in CA1 neurons revealed an IC50 value of 30 mu mol/l at a potential of -30 mV. The half-maximal shift of the current-voltage relation was reached at 33 mu mol/l and the maximal obtainable shift was 13.4 mV. For the different types of hippocampal neurons, the shift of the current-voltage relation was distinct and was 7.9 mV in CA1 neurons, 13.7 mV in CA3 neurons, and 14.2 mV in granule cells with 50 micro mol/l Pb2+. The effects described here of Pb2+ on the potassium currents in hippocampal neurons and the differences between the types of hippocampal neurons correspond with the known properties and distributions of cloned potassium channels found in the hippocampus. As a whole, our results demonstrate that Pb2+ in micromolar concentration is a voltage-dependent, reversible blocker of delayed-rectifier potassium currents of hippocampal neurons. This effect has to be taken into consideration as a possible contributing mechanism for the neurological symptoms of enhanced brain activity seen during Pb2+ intoxication.

Follicular tissues reduce drug effects on ion channels in oocytes of Xenopus laevis.

The influence of follicular tissues on drug effects on ion channels in Xenopus oocytes was tested by investigating the pharmacological properties of a cloned potassium channel in oocytes with and without follicular tissues. The data show that the efficacy of blocking agents (ranging from metal ions to peptides) is drastically reduced by the follicular tissues (reductions by as much as 90% and increases of the IC50 values up to 30-fold). Furthermore, the time course of the blocking effect was slowed down by the tissues (increases of the t50 values up to 40-fold). The described impairment could be mitigated, but not abolished by partial removal of the follicular tissues (so-called defolliculation, leaving only the vitelline envelope and part of the follicle cells on the oocyte surface). The results indicate that the follicular tissues can induce significant errors in pharmacological measurements on membrane proteins in Xenopus oocytes.

Diversity of potassium channels contributing to differences in brain area-specific seizure susceptibility: sensitivity of different potassium channels to the epileptogenic agent pentylenetetrazol.

The effect of the epileptogenic agent pentylenetetrazol on eight cloned voltage-operated mammalian potassium channels (expressed in oocytes of Xenopus laevis) was investigated in order to contribute to an explanation for the brain area-specific differences in seizure susceptibility. Pentylenetetrazol increased the potassium currents at more negative and decreased them at more positive potentials for the channels of the Kv1 gene family, whereas for the other channels the currents were decreased over the whole potential range. The sensitivities of the different potassium channels to the epileptogenic agent were different. At a potential of 0 mV, for example, there were strong reductions for the Kv1.1, Kv1.4 and Kv2.1 currents, whereas the decrease was smaller for the Kv1.3 and Kv1.6 currents and was negligible for the Kv1.2, Kv1.5 and Kv3.4 currents. Correlating these data with the distribution patterns of the potassium channels in the hippocampus, the neocortex and the cerebellum (representing examples of brain areas of distinct seizure susceptibility) revealed that in brain areas with higher seizure susceptibility the overall sensitivity of the potassium channels to the epileptogenic agent is augmented. As a whole, the findings give the first evidence that the differences in distributions and properties of potassium channels contribute to differences in the seizure susceptibility of brain areas.

Membrane currents elicited by the organic calcium channel blocker verapamil in native and rat brain RNA-injected oocytes of Xenopus laevis.

For further analysis of the action of the diphenylalkylamine verapamil (CAS 152-11-4), the ability of verapamil to elicit membrane currents by itself was investigated in native and rat brain. RNA-injected oocytes of Xenopus laevis. Administration of verapamil elicited inward currents which remained constant or increased slightly during ongoing application. In native and RNA-injected oocytes the current responses were similar in shape, but larger in size in RNA-injected oocytes. The currents increased up to the maximal tested concentration of 1 mmol/l verapamil; the threshold concentration was below 80 mumol/l. After removal of follicular tissues the verapamil response was nearly doubled. During verapamil administration the input resistance was increased up to 1.7 of the initial value. The current response to verapamil can be subdivided into an early and late component. The equilibrium potential of the early component ranged between -80 and -110 mV; the late component which increased slightly during verapamil application, had an equilibrium potential between 0 and -20 mV. Under the influence of potassium channel blockers (tetraethylammonium and cesium chloride) or chloride channel blockers (anthracene-9-carbonic acid and the indanyloxy-acetic acid derivative IAA-94) the verapamil induced currents were reduced. Thus, the results indicate that beside the calcium channel-blocking effect, verapamil can induce currents by itself, presumably by acting on the potassium and chloride leakage.