Aliphatic alcohols increase the decay rate of glutamate-activated currents at the crayfish neuromuscular junction.

Excitatory junction currents produced by glutamate were recorded with an extracellular electrode at the excitatory neuromuscular junction of the crayfish. The currents decayed more quickly as the membrane was hyperpolarized. The direction of the voltage sensitivity of the decay phase is thus opposite to that found for acetylcholine-activated currents at the amphibian endplate. The aliphatic alcohols ethanol to octanol all increased the rate of decay of the currents. The effects of the short chain alcohols were opposite to their actions at the toad endplate, where ethanol to pentanol prolong the currents. This observation was explained in terms of the opposite direction of the voltage sensitivity in the two preparations. For each alcohol, the relationship between the half-decay time of the currents (t 1/2) and alcohol concentration was exponential. The potency of each alcohol in decreasing t 1/2 was exponentially related to carbon chain length, which would be predicted if the effects of the alcohols were directly related to their concentration in the lipid phase of the membrane. These findings are consistent with the ideas that the alcohols may alter membrane polarizability or change membrane fluidity in the vicinity of the channels.     

Selective block of late Na(+) current by local anaesthetics in rat large sensory neurones

The actions of lignocaine and benzocaine on transient and late Na(+) current generated by large diameter (> or =50 microm) adult rat dorsal root ganglion neurones, were studied using patch-clamp techniques. Both drugs blocked whole-cell late Na(+) current in a concentration-dependent manner. At 200 ms following the onset of a clamp step from -110 to -40 mV, the apparent K for block of late Na(+) current by lignocaine was 57.8+/-15 microM (mean+/-s.e.mean, n = 4). The value for benzocaine was 24.9+/-3.3 microM, (mean+/-s.e. mean, n = 3). The effect of lignocaine on transient current, in randomly selected neurones, appeared variable (n = 8, half-block from approximately 50 to 400 microM). Half-block by benzocaine was not attained, but both whole-cell (n = 11) and patch data suggested a high apparent K,>250 microM. Transient current always remained after late current was blocked. The voltage-dependence of residual late current steady-state inactivation was not shifted by 20 microM benzocaine (n = 3), whereas 200 microM benzocaine shifted the voltage-dependence of transient current steady-state inactivation by -18.7+/-5.9 mV (mean+/-s.e.mean, n = 4). In current-clamp, benzocaine (250 microM) could block subthreshold, voltage-dependent inward current, increasing the threshold for eliciting action potentials, without preventing their generation (n = 2). Block of late Na(+) current by systemic local anaesthetic may play a part in preventing ectopic impulse generation in sensory neurones.     

Inhibitory action of aliphatic alcohols on smooth muscle contraction.

The addition of 0.05-0.20 mM CaCl2 to the isolated guinea pig ileum immersed in a depolarizing (excess potassium), and calcium-free Tyrode solution produces a dose-related contraction, which is reversibly blocked by aliphatic alcohols of low molecular weight. The inhibitory potency of the alcohols increases with the length of their carbon chain, and may be due to an interference with the movement of calcium across the smooth muscle cell membrane.     

Effects of imipramine on the transient outward current in rabbit atrial single cells.

1. The effects of imipramine on action potential characteristics and transient outward potassium current (It) of rabbit isolated atrial myocytes were studied using the whole-cell configuration of the patch-clamp technique. 2. Imipramine, 3 microM, decreased action potential amplitude and lengthened the action potential duration measured at 50% of repolarization, whereas it did not modify the final phase of repolarization or the resting membrane potential. These results are similar to those reported in multicellular rabbit atrial preparations. 3. Imipramine, 0.1-100 microM, induced a concentration-dependent inhibition of the peak amplitude of It, a shortening of the time to peak current and an increase in the inactivation rate. The acceleration of the current inactivation is to a major extent responsible for the decrease in the integral of the outward current measured at 50 ms after the start of the pulse. 4. The drug-induced block of It was not associated with changes in the voltage-dependence of the steady-state inactivation curve or in the process of recovery from inactivation of the current. Extrapolation to zero block shows that imipramine did not block It before its activation at the onset of the depolarization. These results suggested that imipramine does not affect the inactivated or the resting state of It channels. 5. It is concluded that in rabbit isolated atrial cells, imipramine inhibits It and that this effect is responsible for the lengthening of the action potential duration produced by this drug.     

Effects of sodium metabisulfite on potassium currents in acutely isolated CA1 pyramidal neurons of rat hippocampus.

The effects of sodium metabisulfite (SMB), a food preservative mostly used in food and drug industries, on voltage-dependent potassium currents in acutely isolated hippocampal CA1 pyramidal neurons of rat were studied using the whole-cell patch-clamp techniques. SMB increased transient outward potassium current (IA) and delayed rectifier potassium current (IK) in a concentration-dependent manner. 10 microM SMB shifted the steady-state activation curve of IK to more negative potentials, and the steady-state inactivation curves of IA and IK to more positive potentials. Time to peak of IA was not affected, but the decay of IA was delayed by SMB. However, the activation and inactivation time constants of IK were both decreased by SMB. These results suggested that SMB differently affected IA and IK, and it would decrease the excitability of hippocampal neuron by increasing potassium currents.     

Blockade of HERG K+ channel by an antihistamine drug brompheniramine requires the channel binding within the S6 residue Y652 and F656

A number of clinically used drugs block delayed rectifier K+ channels and prolong the duration of cardiac action potentials associated with long QT syndrome. This study investigated the molecular mechanisms of voltage-dependent inhibition of human ether-a-go-go-related gene (HERG) delayed rectifier K+ channels expressed in HEK-293 cells by brompheniramine, an antihistamine. Brompheniramine inhibited HERG current in a concentration-dependent manner with the half-maximal inhibitory concentration (IC50) value of 1.7 microm at 0 mV. A block of HERG current by brompheniramine was enhanced by progressive membrane depolarization and showed significantly negative shift in voltage-dependence of channel activation. Inhibition of HERG current by brompheniramine showed time-dependence. The S6 residue HERG mutant Y652A and F656C largely reduced the blocking potency of HERG current. These results indicate that brompheniramine mainly inhibited the HERG potassium channel through the residue Y652 and F656 and these residues may be an obligatory determinant in inhibition of HERG current for brompheniramine.     

Block of NA+ and K+ currents in rat ventricular myocytes by quinacainol and quinidine

1. The electrophysiological actions of quinacainol were investigated on sodium (I(Na)), transient outward (i(to)) and sustained-outward plateau (iKsus) potassium currents in rat isolated cardiac myocytes using the whole-cell patch-clamp technique and compared with quinidine. 2. Quinacainol blocked sodium currents in a concentration-dependent manner and with a potency similar to that of quinidine (mean (+/-SEM) EC50 50+/-12 vs 95+/-25 micromol/L for quinidine and quinacainol, respectively). However, quinacainol had a considerably prolonged onset and recovery from block compared with quinidine. 3. Neither quinacainol nor quinidine significantly changed the steady state voltage dependence of activation of sodium currents. Quinidine produced a hyperpolarizing shift in the voltage dependence for sodium current inactivation, but no such shift was observed with quinacainol at doses that produced a substantial current block. 4. Although quinacainol did not effectively block voltage-dependent potassium currents, even at concentrations as high as 1.5 mmol/L, quinidine, at a half-maximal sodium channel-blocking concentration, reduced peak i(to) current amplitude, increased the rate of inactivation of i(to) and blocked iKsus. 5. These results indicate that quinacainol, a quinidine analogue, blocks sodium currents in cardiac myocytes with little effect on i(to) or iKsus potassium currents, which suggests that quinacainol may be exerting class 1c anti-arrhythmic actions.     

A Chloroform Extract of the Herb Feverfew Blocks Voltage-dependent Potassium Currents Recorded from Single Smooth Muscle Cells

Abstract— We have studied the effects of a chloroform extract of fresh leaves from the herb feverfew (Tanacetum parthenium) on potassium currents in smooth muscle. The currents were recorded from single cells dissociated from the rat anococcygeus and the rabbit ear artery using the whole-cell patch-clamp technique. When applied to cells isolated from the rat anococcygeus, the extract reduced the inactivating voltage-dependent potassium current in a concentration-related manner, with an IC50 value (the concentration that reduced the current by 50%) of 56 μg mL^?1. Complete block of the current occurred at 1 mg mL^?1. In addition to reducing the peak current, feverfew decreased the time to peak of the current and increased the rate of decay of the current. These effects can be explained by the feverfew extract blocking open potassium channels. In single cells isolated from rabbit ear artery the feverfew extract again reduced the voltage-dependent potassium current, whilst at the same time having no effect on the spontaneous transient outward currents which arise as a consequence of activation of calcium-dependent potassium channels. These results suggest that chloroform extracts of feverfew leaf contain an as yet unidentified substance capable of producing a selective, open-channel block of voltage-dependent potassium channels.     

Passive permeability of dihexadecylphosphate vesicles altered by aliphatic alcohols and omega-diols.

Alcohols act as anaesthetics only up to a certain chain length, beyond which their biological activity disappears. Although the molecular nature of general target sites remains unknown, presently available data support the hypothesis that this 'cut-off' in anaesthetic activity could be due to a corresponding cut-off in the absorption of long-chain alcohols into lipid-bilayer portions of nerve membranes. To test this hypothesis, we developed a method based on leakage of Ru(bpy)3(2+) ions across the membrane of dihexadecylphosphate (DHP) vesicles induced by aliphatic alcohols (C1 to C18) and some of their omega-diol. The permeant effects of aliphatic linear alcohols expressed as PD50 values rise to a maximum for n-dodecanol (PD50 = 2 x 10(-3) M 1(-1]. Dodecanol was found to be the alcohol which presents the greatest anaesthetic potency among the series of linear aliphatic alcohols (cut-off anaesthetic effect). The results are discussed in terms of the structural physicochemical and geometrical characteristics of the permeating alcohols.     

Voltage-dependent acceleration of Ca(v)1.2 channel current decay by (+)- and (-)-isradipine

Inhibition of Ca(v)1.2 by antagonist 1,4 dihydropyridines (DHPs) is associated with a drug-induced acceleration of the calcium (Ca(2+)) channel current decay. This feature is contradictorily interpreted as open channel block or as drug-induced inactivation. To elucidate the underlying molecular mechanism we investigated the effects of (+)- and (-)-isradipine on Ca(v)1.2 inactivation gating at different membrane potentials. alpha(1)1.2 Constructs were expressed together with alpha(2)-delta- and beta(1a)- subunits in Xenopus oocytes and drug-induced changes in barium current (I(Ba)) kinetics analysed with the two microelectrode voltage clamp technique. To study isradipine effects on I(Ba) decay without contamination by intrinsic inactivation we expressed a mutant (V1504A) lacking fast voltage-dependent inactivation. At a subthreshold potential of -30 mV a 200-times higher concentration of (-)-isradipine was required to induce a comparable amount of inactivation as by (+)-isradipine. At +20 mV the two enantiomers were equally efficient in accelerating the I(Ba) decay. Faster recovery from (-)- than from (+)-isradipine-induced inactivation at -80 mV in a Ca(v)1.2 construct (tau((-)-isr.(Cav1.2))=0.74 s相似文献   

Electrophysiological mechanisms for antiarrhythmic efficacy and positive inotropy of liriodenine, a natural aporphine alkaloid from Fissistigma glaucescens.

1. The antiarrhythmic potential and electromechanical effects of liriodenine, an aporphine alkaloid isolated from the plant, Fissistigma glaucescens, were examined. 2. In the Langendorff perfused (with constant pressure) rat heart, at a concentration of 0.3 to 3 microM, liriodenine was able to convert a polymorphic ventricular tachyrhythmia induced by the ischaemia-reperfusion (EC50 = 0.3 microM). 3. In isolated atrial and ventricular muscle, liriodenine increased the contractile force and slowed the spontaneous beating of the right atrium. 4. The liriodenine-induced positive inotropy was markedly attenuated by a transient outward K+ channel blocker, 4-aminopyridine (4-AP) but was not significantly affected by prazosin, propranolol, verapamil or carbachol. 5. In rat isolated ventricular myocytes, liriodenine prolonged action potential duration and decreased the maximal upstroke velocity of phase 0 depolarization (Vmax) and resting membrane potential in a concentration-dependent manner. The action potential amplitude was not significantly changed. 6. Whole-cell voltage clamp study revealed that liriodenine blocked the Na+ channel (INa) concentration-dependently (IC50 = 0.7 microM) and caused a leftward shift of its steady-state inactivation curve. However, its recovery rate from the inactivated state was not affected. The L-type Ca2+ currents (Ica) were also decreased, but to a lesser degree (IC50 = 2.5 microM, maximal inhibition = 35%). 7. Liriodenine inhibited the 4-AP-sensitive transient outward current (Ito) (IC50 = 2.8 microM) and moderately accelerated its rate of decay. The block of Ito was not associated with changes in the voltage-dependence of the steady-state inactivation curve or in the process of recovery from inactivation of the current. Liriodenine also reduced the amplitude of a slowly inactivating, steady-state outward current (Iss) (IC50 = 1.9 microM). These effects were consistent with its prolonging effect on action potential duration. The inwardly rectifying background K+ current (IK1), was also decreased but to a less degree. 8. Compared to quinidine, liriodenine exerted a stronger degree of block on INa, comparable degree of block on IK1, and lesser extent of block on ICa and Ito. 9. It is concluded that, through inhibition of Na+ and the Ito channel, liriodenine can suppress ventricular arrhythmias induced by myocardial ischaemia reperfusion. The positive inotropic effect can be explained by inhibition of the Ito channel and the subsequent prolongation of action potential duration. These results provide a satisfactory therapeutic potential for the treatment of cardiac arrhythmias.     

东亚钳蝎中新分离的毒素BmTx3B抑制大鼠海马神经元延迟整流性钾电流

目的：研究从东亚钳蝎毒素中新分离的短肽BmTx3B对电压门控性钾通道的作用．方法：在酶解打散的新生大鼠海马细胞,采用全细胞电压箝位方式记录,并根据动力学特性分离二种电压依赖性钾电流．结果：BraTx3B(10-100μmol／L)选择地抑制延迟整流性钾电流(IK),不影响瞬时性快钾电流(IA)．此抑制作用是可逆的,呈现浓度依赖性,但无电压依赖性．BmTx3B对延迟整流性钾电流的稳态激活和稳态失活的动力学特性无影响．结论：蝎毒短肽BmTx3B选择地抑制海马神经元延迟整流性钾通道。     

Effects of pinaverium on voltage-activated calcium channel currents of single smooth muscle cells isolated from the longitudinal muscle of the rabbit jejunum.

1. Smooth muscle cells of the longitudinal muscle of the rabbit jejunum were dispersed by enzyme treatment and recordings of membrane current were made in the whole-cell mode by patch clamp technique. The action of pinaverium bromide on the voltage-dependent inward current of single isolated smooth muscle cells was studied in solutions containing normal concentrations of calcium or high concentrations of barium at room temperature. 2. Pinaverium reduced the voltage-dependent inward current with an IC50 of 1.5 microM. This IC50 is similar to those of verapamil, diltiazem and flunarizine on these cells as described by others. Occasionally evidence of a potentiating action of pinaverium on the inward current was seen. 3. Repetitive stimulation of the cells did not increase blockade of inward current by pinaverium unlike the use-dependent blockade seen with verapamil, methoxyverapamil, and diltiazem in these and in other smooth muscle cells. 4. The inactivation of inward current was studied by holding at various potentials for 2 or 10 s before evoking inward current. The voltage at which current was 50% available was changed very little by pinaverium although other calcium entry blockers, for example the dihydropyridines, have been reported to produce appreciable negative shifts which indicate considerable voltage-dependence of their blockade. This may indicate that pinaverium has similar affinities for the closed available and inactivated calcium channel states so that blockade is not appreciably voltage-dependent.     

Characterization of Ca2+ current inhibition by cilnidipine using a beta-subunit antisense oligonucleotide

The dihydropyridine cilnidipine has been reported to induce a fast decay of the L-type Ca(2+) current, an effect distinct from the modulation of voltage-dependent inactivation. We performed a whole-cell patch-clamp study using A7r5 cells to analyse the changes in current decay induced by two structurally related dihydropyridines after the amount of the beta-subunit mRNA has been decreased by the antisense oligonucleotide. The Ba(2+) current underwent a single exponential decay indicating voltage-dependent inactivation. The tau value was greater in the antisense group than in the sense and nonsense groups. Equipotent doses of cilnidipine and nimodipine decreased the tau value, while only cilnidipine created an additional component with a smaller tau value (tau(cil): 35 ms) that showed voltage-independence. Treatment with antisense failed to alter this component (tau(cil): 38 ms). These results suggest that cilnidipine specifically exerts a second type of blocking action on L-type Ca(2+) channels that is not dependent on the beta-subunit.     

Effects of the antiarrhythmic agent EGIS-7229 (S 21407) on calcium and potassium currents in canine ventricular cardiomyocytes

Based on earlier pharmacological studies performed using conventional microelectrodes EGIS-7229 (S 21407), the novel antiarrhythmic candidate, was suggested to have a combined mode of action in cardiac tissues isolated from various mammalian species. In order to characterize the electrophysiological effects of the compound, its effects on calcium and potassium currents of isolated canine ventricular cardiomyocytes were studied in the present work using the whole cell configuration of the patch clamp technique. L-type Ca current (ICa) was significantly depressed by EGIS-7229 at concentrations of 3 microM or higher with no concomitant changes in the voltage-dependence of activation and time course of inactivation of ICa. The drug reversibly suppressed the rapid component of the delayed rectifier K current (IKr) in a concentration-dependent manner, having a K0.5 value of 1.1+/-0.1 microM and a slope factor of close to unity (1.23+/-0.16), indicating that probably one single binding site of high affinity may be involved in binding of EGIS-7229 to the IKr channel. In contrast, no changes in the slow component of the delayed rectifier K current (IKs) was observed with the compound up to the concentration of 100 microM, even if the current was fully activated by 8-bromo-cAMP. At a concentration of 10 microM or higher, EGIS-7229 caused also a moderate but significant reduction in the inward rectifier K current (IK1) and the transient outward K current (Ito) with no change in the voltage-dependence of activation and steady-state inactivation of Ito. Present results indicate that EGIS-7229 can be considered as a selective IKr blocker at low (1 microM) concentration; however, its combined (class III + IV) mechanism of action is evident at concentrations of 3 microM or higher. Suppression of ICa may explain the lack of development of early afterdepolarizations in the presence of EGIS-7229, predicting a relatively safe clinical application in contrast to pure class III compounds.     

Effects of aluminum chloride on sodium current, transient outward potassium current and delayed rectifier potassium current in acutely isolated rat hippocampal CA1 neurons.

The effects of aluminum chloride (AlCl3) on sodium current (INa), the transient outward potassium (IA) and delayed rectifier potassium currents (IK) in hippocampal CA1 neurons of rats were studied using the whole cell patch-clamp technique. AlCl3 decreased INa, IA, and IK in a partly reversible, dose and voltage-dependent manner. AlCl3 prolonged the time to peak of INa, and increased the inactivation time constants of INa and IA . In addition, 1000 microM AlCl3 shifted the voltage dependence of steady-state activation of INa, IA and IK toward positive potential, and the voltage dependence of steady-state inactivation of INa, IA toward negative potential. These results imply that AlCl3 could affect the activation and inactivation courses of sodium current and potassium current of rat hippocampal CA1 neurons, which may contribute to damage of the central nervous system by aluminum.     

Properties of the cromakalim-induced potassium conductance in smooth muscle cells isolated from the rabbit portal vein.

1. Single smooth muscle cells were isolated freshly from the rabbit portal vein and membrane currents were recorded by the whole-cell or excised patch configurations of the patch-clamp technique at room temperature. 2. Cromakalim (Ckm, 10 microM) induced a potassium current (ICkm) that showed no pronounced voltage-dependence and had low current noise. 3. This current, ICkm, was inhibited by (in order of potency): phencyclidine greater than quinidine greater than 4-aminopyridine greater than tetraethylammonium ions (TEA). These drugs inhibited the delayed rectifier current, IdK, which is activated by depolarization of the cell, with the same order of potency. 4. Large conductance calcium-activated potassium channels (LKCa) in isolated membrane patches were blocked by (in order of potency) quinidine greater than TEA approximately phencyclidine. 4-Aminopyridine was ineffective. A similar order of potency was found for block of spontaneous transient outward currents thought to represent bursts of openings of LKCa channels. 5. The low current noise of ICkm at positive potentials, and its susceptibility to inhibitors indicated that it was not carried by LKCa channels, and that it may be carried by channels which underlie IdK. It was observed that when ICkm was activated, IdK was reduced. However, in two experiments, ICkm was much more susceptible to glibenclamide than IdK; possible reasons for this are discussed.     

Enhancing effects of medium chain aliphatic alcohols and esters on the permeation of 6-carboxyfluorescein and indomethacin through rat skin

Medium chain aliphatic alcohols (C8-C12) and methyl or propyl esters of medium chain fatty acids (C8-C12) enhanced the permeation of 6-carboxyfluorescein (6-CF) and indomethacin (IND) through excised rat skin. The enhancing effects of the aliphatic alcohols for 6-CF and IND decreased with the increase in carbon chain length. The dependence on the carbon chain length was different from that exhibited by medium-chain fatty acids previously reported. In the case of fatty acid esters, the enhancing effects were lower than those of aliphatic alcohols and fatty acids. The relationship between the enhancing effects and the total number of carbon atoms in the esters was different for 6-CF and IND. The dependence on the total number of carbon atoms was similar to that in the aliphatic alcohols for 6-CF, and greater effects were observed in the shorter esters. On the other hand, no definite trends were observed for IND. Although the relationships between the structure and skin permeation-enhancing effect of the aliphatic alcohols and fatty acid esters used in this study are not yet fully understood, they are possible candidates as permeation enhancers for hydrophilic and lipophilic drugs. Further experiments, including examination of the location and environment of the lipophilic carbon chain and hydrophilic groups of such enhancers in the stratum corneum, are needed to optimize transdermal delivery systems containing them.     

The effect of selected organic solvents on intact human red cell membrane acetylcholinesterase in vitro

Human erythrocytes were exposed to different concentrations of aromatic hydrocarbons, chlorinated aliphatic hydrocarbons, and alcohols in vitro to study the effects of these agents on the activity of acetylcholinesterase (AchE), a membrane integral protein. Aromatic hydrocarbons were in general more potent AchE inhibitors than chlorinated aliphatic hydrocarbons and alcohols at +37 degrees C. The influence of decreasing the temperature to +15 degrees C and +5 degrees C was more prominent on the effect of aromatic hydrocarbons than on the effect of chlorinated aliphatic hydrocarbons and alcohols. In general, however, the decrease in the incubation temperature increased the AchE-inhibiting effect of organic solvents. The lipid solubility and molecular structure, among other factors, may determine the AchE inhibitory potency of organic solvents. Changes in membrane AchE may be one of the factors affecting membrane fluidity, which is considered to determine membrane stabilization. The primary site of action of the membrane-stabilizing agents may involve a membrane protein.     

Enhancing Effects of Medium Chain Aliphatic Alcohols and Esters on the Permeation of 6-Carboxyfluorescein and Indomethacin through Rat Skin

Medium chain aliphatic alcohols (C8-C12) and methyl or propyl esters of medium chain fatty acids (C8-C12) enhanced the permeation of 6-carboxyfluorescein (6-CF) and indomethacin (IND) through excised rat skin. The enhancing effects of the aliphatic alcohols for 6-CF and IND decreased with the increase in carbon chain length. The dependence on the carbon chain length was different from that exhibited by medium-chain fatty acids previously reported. In the case of fatty acid esters, the enhancing effects were lower than those of aliphatic alcohols and fatty acids. The relationship between the enhancing effects and the total number of carbon atoms in the esters was different for 6-CF and IND. The dependence on the total number of carbon atoms was similar to that in the aliphatic alcohols for 6-CF, and greater effects were observed in the shorter esters. On the other hand, no definite trends were observed for IND. Although the relationships between the structure and skin permeation-enhancing effect of the aliphatic alcohols and fatty acid esters used in this study are not yet fully understood, they are possible candidates as permeation enhancers for hydrophilic and lipophilic drugs. Further experiments, including examination of the location and environment of the lipophilic carbon chain and hydrophilic groups of such enhancers in the stratum corneum, are needed to optimize transdermal delivery systems containing them.