Mechanism of calcium channel blockade by verapamil, D600, diltiazem and nitrendipine in single dialysed heart cells

Inactivation determinant in the I-II loop of the Ca2+ channel alpha1-subunit and beta-subunit interaction affect sensitivity for the phenylalkylamine (-)gallopamil

1. The role of calcium (Ca2+) channel inactivation in the molecular mechanism of channel block by phenylalkylamines (PAAs) was analysed in a PAA-sensitive rabbit brain class A Ca2+ channel mutant (alpha1A-PAA). Use-dependent barium current (IBa) inhibition of alpha1A-PAA by (-)gallopamil and Ca2+ channel recovery from inactivation and block were studied with two-microlectrode voltage clamp after expression of alpha1A-PAA and auxiliary alpha2-delta- and beta1a- or beta2a-subunits in Xenopus oocytes. 2. Mutation Arg387Glu (alpha1A numbering) in the intracellular loop connecting domains I and II of alpha1A-PAA slowed the inactivation kinetics and reduced use-dependent inhibition (100 ms test pulses at 0.2 Hz from -80 to 20 mV) of the resulting mutant alpha1A-PAA/R-E/beta1a channels by 100 microM (-)gallopamil (53 +/- 2 %, alpha1A-PAA/beta1a vs. 31 +/- 2 %, alpha1A-PAA/R-E/beta1a, n >= 4). This amino acid substitution simultaneously accelerated the recovery of channels from inactivation and from block by (-)gallopamil. 3. Coexpression of alpha1A-PAA with the beta2a-subunit reduced fast IBa inactivation and induced a substantial reduction in use-dependent IBa inhibition by (-)gallopamil (25 +/- 4 %, alpha1A-PAA/beta2a; 13 +/- 1 %, alpha1A-PAA/R-E/beta2a). The time constant of recovery from block at rest was not significantly affected. 4. These results demonstrate that changes in channel inactivation induced by Arg387Glu or beta2a-alpha1-subunit interaction affect the drug-channel interaction.

Effects of manidipine and nitrendipine enantiomers on the plateau phase of K+-induced intracellular Ca2+ increase in GH3 cells

The aim of the present study was to investigate whether the chirality and type of substitution at position 3 of the dihydropyridine ring influences the pattern of voltage-gated Ca2+ channel blockade. For this purpose, the effect of R- and S-enantiomers of manidipine and nitrendipine, separated by chiral High-Pressure-Liquid-Chromatography columns, were investigated by fura-2 microfluorimetry during the plateau phase of the intracellular Ca2+ ([Ca2+]i) increase induced by 55 mM K+ and by patch-clamp recording of Ca2+ channel activity in GH3 cells. R- and S-enantiomers of both nitrendipine and manidipine produced a [Ca2+]i decay of the K+-induced plateau phase that followed a biexponential pattern with a 'fast' and a 'slow' phase. The S-configuration of both nitrendipine and manidipine produced a larger [Ca2+]i decrease during the 'fast phase', and a faster and smaller [Ca2+]i decrease in the 'slow phase' than did the R-enantiomers. The S- and R-enantiomers of manidipine, which possess a longer and more lipophilic side chain at position 3 of the dihydropyridine ring, induced a slower [Ca2+]i decrease than that observed with the respective nitrendipine enantiomers. Accordingly, patch-clamp experiments revealed that the S-enantiomers of both dihydropyridines displayed a faster onset of action and produced a greater blockade than the R-enantiomers. These results suggest that the enantiomeric configuration and a small side chain at position 3 of the dihydropyridine ring are factors in the chemical structure which influence the pattern of blockade of voltage-sensitive Ca2+ channels.

Calcium antagonistic properties of the cyclooxygenase-2 inhibitor nimesulide in human myometrial myocytes

The non-steroidal anti-inflammatory drug nimesulide is a selective inhibitor of cyclooxygenase-2 which relaxes spontaneously contracting human myometrium in vivo and is potentially a useful tocolytic drug. Part of the relaxant action of nimesulide may be via block of myometrial Ca2+ channels. Here, we describe the Ca2+ channel blocking properties of nimesulide in freshly dispersed human term-pregnant myometrial smooth muscle cells (HMSMCs). Both L- and T-components of the whole cell Ca2+ channel current were inhibited by 100 microM nimesulide (38+/-3 and 35+/-1% block, respectively). At physiological pH inside and outside the cell (pHo/pHi = 7.4/7.2), this block did not depend on the holding or test potential, although a degree of use-dependence was observed during high frequency stimulation at a higher concentration of drug (300 microM). At pHo/pHi = 6.8, under which condition the concentration of the non-ionized form of the drug is increased 3 fold compared to pH 7.4, nimesulide blocked the L-type current more potently (58+/-3% inhibition at 100 microM, P<0.01) compared to physiological pH. Nimesulide caused a 7 mV leftward shift in the availability curve of the current at pH 6.8, suggesting that the affinity of the drug for the inactivated channel is approximately 4 fold higher than its affinity for the closed channel. We speculate that acidification and depolarization of the myometrium during the intense and prolonged contractions of labour might increase the potency of nimesulide as a Ca2+ channel antagonist, promoting its action as a tocolytic agent.

Troglitazone inhibits voltage-dependent calcium currents in guinea pig cardiac myocytes

BACKGROUND

It has been suggested that intracellular Ca2+ overload in cardiac myocytes leads to the development of diabetic cardiomyopathy. Troglitazone, an insulin-sensitizing agent, is a promising therapeutic agent for diabetes and has been shown to prevent diabetes-induced myocardial changes. To elucidate the underlying mechanism of troglitazone action on cardiac myocytes, the effects of troglitazone on voltage-dependent Ca2+ currents were examined and compared with classic Ca2+ antagonists (verapamil and nifedipine).

METHODS AND RESULTS

Whole-cell voltage-clamp techniques were applied in single guinea pig atrial myocytes. Under control conditions with CsCl internal solution, the voltage-dependent Ca2+ currents consisted of both T-type (ICa,T) and L-type (ICa,L) Ca2+ currents. Troglitazone effectively reduced the amplitude of ICa,L in a concentration-dependent manner. Troglitazone also suppressed ICa,T, but the effect of troglitazone on ICa,T was less potent than that on ICa,L. The current-voltage relationships for ICa,L and the reversal potential for ICa,L were not altered by troglitazone. The half-maximal inhibitory concentration of troglitazone on ICa,L measured at a holding potential of -40 mV was 6.3 micromol/L, and 30 micromol/L troglitazone almost completely inhibited ICa,L. Troglitazone 10 micromol/L did not affect the time courses for inactivation of ICa,L and inhibited ICa,L mainly in a use-independent fashion, without shifting the voltage-dependency of inactivation. This effect was different from those of verapamil and nifedipine. Troglitazone also reduced isoproterenol- or cAMP-enhanced ICa,L.

CONCLUSIONS

These results demonstrate that troglitazone inhibits voltage-dependent Ca2+ currents (T-type and L-type) and then antagonizes the effects of isoproterenol in cardiac myocytes, thus possibly playing a role in preventing diabetes-induced intracellular Ca2+ overload and subsequent myocardial changes.

The pharmacological basis and pathophysiological significance of the heart rate-lowering property of diltiazem

The calcium channel blocker diltiazem lowers heart rate in man and this property probably contributes to its clinical effectiveness in ischaemic heart disease and hypertension. This review examines the pharmacological basis of diltiazem's heart rate-lowering activity and considers its pathophysiological significance. The points discussed include the potent direct inhibitory effect of diltiazem on the sinus node and the frequency-dependence of this action. In addition, the well-balanced tissue selectivity profile of diltiazem and its ability to modulate cardiac reflex responsiveness contribute by counteracting the potential for reflex tachycardia.

Presynaptic calcium-channel currents in normal and csp mutant Drosophila peptidergic terminals

The study of regulated vesicle exocytosis, which underlies neurotransmitter and neuropeptide release, has benefited from a convergence of several independent approaches. These include the use of genetically tractable organisms and model preparations that allow a direct characterization of presynaptic ionic currents. Aiming for a comprehensive analysis of release, we had already developed a Drosophila preparation in which electrophysiological recordings from peptidergic terminals are feasible. Here, we report on the characterization of the Ca2+-channel currents present in these terminals. With Ba2+ as the charge carrier, the presynaptic membrane expresses a current type with high-activation threshold and little inactivation. This current is blocked by verapamil and diltiazem at micromolar concentrations, it is relatively insensitive to nifedipine and completely resistant to non-L-type Ca2+-channel antagonists. As a comparison, we also analysed the pharmacology of high-threshold Ba+2 currents on muscle fibres. A high-activation threshold Ca2+-channel current is also present in muscle fibres, albeit with a distinct pharmacological profile. Thus, peptidergic terminals and muscle fibres exhibit different subtypes of voltage-gated Ca2+ channels. The putative role of cysteine string protein (CSP) as a neuronal Ca2+-channel modulator was tested by examining the peptidergic presynaptic current in csp null mutants. We show that CSP is expressed in peptidergic boutons and abolished in the mutant. Direct recordings, under conditions that inhibit calcium influx into glutamatergic terminals, show that Ca2+-currents in peptidergic csp terminals are entirely normal. This result indicates that CSP is not a generic Ca2+-channel modulator and it might perform different functions in fast versus slow forms of release.

Farnesol blocks the L-type Ca2+ channel by targeting the alpha 1C subunit

We recently demonstrated that farnesol, a 15-carbon isoprenoid, blocks L-type Ca2+ channels in vascular smooth muscle cells. To elucidate farnesol's mechanism of action, we performed whole-cell and perforated-patch clamp experiments in rat aortic A7r5 cells and in Chinese hamster ovary (CHO) C9 cells expressing smooth muscle Ca2+ channel alpha 1C subunits. Farnesol dose-dependently and voltage-independently inhibited Ba2+ currents in both A7r5 and CHOC9 cells, with similar half-maximal inhibitions at 2.6 and 4.3 micromol/L, [corrected] respectively (P=NS). In both cell lines, current inhibition by farnesol was prominent over the whole voltage range without changes in the current-voltage relationship peaks. Neither intracellular infusion of the stable GDP analogue guanosine-5'-O-(2-thiodiphosphate) (100 micromol/L) [corrected] via the patch pipette nor strong conditioning membrane depolarization prevented the inhibitory effect of farnesol, which indicates G protein-independent inhibition of Ca2+ channels. In an analysis of the steady-state inactivation curve for voltage dependence, farnesol induced a significant, negative shift ( approximately 10 mV) of the potential causing 50% channel inactivation in both cell lines (P<0. 001). In contrast, the steepness factor characterizing the voltage sensitivity of the channels was unaffected. Unlike pharmacological Ca2+ channel blockers, farnesol blocked Ca2+ currents in the resting state: initial block was 63+/-8% in A7r5 cells and 50+/-9% in CHOC9 cells at a holding potential of -80 mV. We then gave 500 mg/kg body weight farnesol by gavage to Sabra hypertensive and normotensive rats and found that farnesol reduced blood pressure significantly in the hypertensive strain for at least 48 hours. We conclude that farnesol may represent an endogenous smooth muscle L-type Ca2+ channel antagonist. Because farnesol is active in cells expressing only the pore-forming alpha1 subunit, the data further suggest that this subunit represents the molecular target for farnesol binding and principal action. Finally, farnesol has a blood pressure-lowering action that may be relevant in vivo.

Effects of AH-1058, a new antiarrhythmic drug, on experimental arrhythmias and cardiac membrane currents

AH-1058 is a newly synthesized antiarrhythmic agent. We investigated the antiarrhythmic and electrophysiological effects of AH-1058 in experimental arrhythmia models and isolated cardiomyocytes. In the ouabain-induced arrhythmia model of the guinea pig, pretreatment with AH-1058 (0.1-0.3 mg/kg, i.v.) delayed the appearance of premature ventricular complex (PVC) and ventricular fibrillation (VF) induced by intravenous infusion of ouabain. However, disopyramide (10 mg/kg, i.v.) delayed only that of PVC, and verapamil (1 mg/kg, i.v.) failed to affect the ouabain-induced ventricular arrhythmias. In the reperfusion-induced arrhythmia model of the rat, in which 5-min coronary occlusion and 10-min reperfusion were produced, AH-1058 (0.1-0.3 mg/kg, i.v.) inhibited the incidence of both ventricular tachycardia (VT) and VF, whereas disopyramide (5 mg/kg, i.v.) inhibited only reperfusion-induced VF. On the other hand, a higher dose of AH-1058 (1 mg/kg, i.v.) did not affect the aconitine-induced arrhythmias in rats, which were inhibited by disopyramide (5 mg/kg, i.v.). We also confirmed oral activity of AH-1058 in the reperfusion-induced arrhythmia model of the rat. AH-1058, at doses of 2-4 mg/kg, dose-dependently inhibited VT and VF. Electrophysiological experiments with patch-clamp techniques revealed that AH-1058 potently suppressed the L-type Ca2+ currents in isolated cardiomyocytes of the guinea pig. These results suggest that AH-1058 is a potent antiarrhythmic drug having a Ca2+ channel-blocking action. The antiarrhythmic profile of AH-1058 is different from that of disopyramide and verapamil.

Cold acclimation of guinea pig depressed contraction of cardiac papillary muscle

Guinea pigs were exposed to 5 degrees C for 3 wk, and the contractions of myocardial papillary muscle were compared with preparations dissected from control animals kept at approximately 25 degrees C. Developed tension of the papillary muscle per cross-sectional area was significantly (t-test, P < 0.05) decreased after cold exposure (19,200 +/- 8,160 vs. 3,020 +/- 2,890 dyne/cm2; 1 Hz). Time to peak tension was significantly faster in cold-exposed guinea pigs (126.4 +/- 11.1 ms; 1 Hz) than in controls (162.7 +/- 8. 7 ms). The magnitude of the developed tension after application of ryanodine (2 mM) to muscles from cold-exposed animals was decreased to 37.5 +/- 8.3% of control at 1 Hz, whereas in muscles from control animals, tension was decreased to 82.4 +/- 7.7%. The ryanodine-sensitive component of contraction was not significantly changed in control guinea pigs at frequencies >0.5 Hz, whereas in muscles from cold-acclimated guinea pigs, there was a "positive staircase." These results suggested that reversal of the Na+/Ca2+ exchanger is predominantly involved in the positive staircase in control guinea pigs, whereas rate-dependent increases in the Ca2+ store in the sarcoplasmic reticulum may be involved in the staircase after cold acclimation.

Sequence differences between alpha1C and alpha1S Ca2+ channel subunits reveal structural determinants of a guarded and modulated benzothiazepine receptor

The molecular basis of the Ca2+ channel block by (+)-cis-diltiazem was studied in class A/L-type chimeras and mutant alpha1C-a Ca2+ channels. Chimeras consisted of either rabbit heart (alpha1C-a) or carp skeletal muscle (alpha1S) sequence in transmembrane segments IIIS6, IVS6, and adjacent S5-S6 linkers. Only chimeras containing sequences from alpha1C-a were efficiently blocked by (+)-cis-diltiazem, whereas the phenylalkylamine (-)-gallopamil efficiently blocked both constructs. Carp skeletal muscle and rabbit heart Ca2+ channel alpha1 subunits differ with respect to two nonconserved amino acids in segments IVS6. Transfer of a single leucine (Leu1383, located at the extracellular mouth of the pore) from IVS6 alpha1C-a to IVS6 of alpha1S significantly increased the (+)-cis-diltiazem sensitivity of the corresponding mutant L1383I. An analysis of the role of the two heterologous amino acids in a L-type alpha1 subunit revealed that corresponding amino acids in position 1487 (outer channel mouth) determine recovery of resting Ca2+ channels from block by (+)-cis-diltiazem. The second heterologous amino acid in position 1504 of segment IVS6 (inner channel mouth) was identified as crucial inactivation determinant of L-type Ca2+ channels. This residue simultaneously modulates drug binding during membrane depolarization. Our study provides the first evidence for a guarded and modulated benzothiazepine receptor on L-type channels.

Involvement of calcium in ACC-oxidase activity from Cicer arietinum seed embryonic axes

Both in vivo and in vitro ACC-oxidase activities as well as ethylene production from embryonic axes of chickpea seeds were strongly inhibited by EGTA, a selective extracellular Ca2+ ion chelator, indicating that the influx of Ca2+ is important for enzymatic activity. EGTA inhibition was restored by exogenous Ca2+. Treatments of embryonic axes with either Verapamil and LaCl3 (both Ca2+ channel blockers) or TMB-8 (an intracellular Ca2+ antagonist) provoked an inhibition of both ACC-oxidase activity and ethylene production. These results suggest an involvement of calcium fluxes and intracellular calcium levels in the activity of the last step of the ethylene biosynthetic pathway, which is, in turn, intimately correlated with germination of Cicer arietinum seeds.

pH-dependent block of the L-type Ca2+ channel current by diltiazem in human mesenteric arterial myocytes

Inhibition of the L-type Ca2+ channel current (IBa) by diltiazem was characterised in human mesenteric arterial myocytes. External (pHo) and internal (pHi) pH was varied to alter the proportion of drug in charged and neutral forms. Diltiazem (20 microM) reduced IBa amplitude by approximately half at pHo 7.2 and 9.2 at holding potential -60 mV. The IBa decay was increased by diltiazem at pHo = 9.2 (97% uncharged), but not at 7.2. The IC50 for inhibition of IBa by diltiazem at holding potential -60 mV was decreased from 51 to 20 microM at pHo 7.2 and 9.2, respectively. At holding potential of -90 mV, but not -60 mV, tonic block increased and use-dependent block decreased as pHo was raised from 6.2 to 9.2. Diltiazem also caused a hyperpolarizing shift in IBa availability at alkaline pHo. The results suggest that raising pH promotes Ca2+ channel blockade by increasing the proportion of uncharged diltiazem.

Antiarrhythmic drugs and cardiac ion channels: mechanisms of action

In this review a description and an analysis are given of the interaction of antiarrhythmic drugs with their molecular target, i.e. ion channels and receptors. Our approach is based on the concept of vulnerable parameter, i.e. the electrophysiological property which plays a crucial role in the genesis of arrhythmias. To prevent or stop the arrhythmia a drug should modify the vulnerable parameter by its action on channel or receptor targets. In the first part, general aspects of the interaction between drugs channel molecules are considered. Drug binding depends on the state of the channel: rested, activated pre-open, activated open, or inactivated state. The change in channel behaviour with state is presented in the framework of the modulated-receptor hypothesis. Not only inhibition but also stimulation can be the result of drug binding. In the second part a detailed and systematic description and an analysis are given of the interaction of drugs with specific channels (Na+, Ca2+, K+, "pacemaker") and non-channel receptors. Emphasis is given to the type of state-dependent block involved (rested, activated and inactivated state block) and the change in channel kinetics. These properties vary and determine the voltage- and frequency-dependence of the change in ionic current. Finally, the question is asked as to whether the available drugs by their action on channels and receptors modify the vulnerable parameter in the desired way to stop or prevent arrhythmias.

Functional interaction between benzothiazepine- and dihydropyridine binding sites of cardiac L-type Ca2+ channels

We have previously shown, in a radioligand binding study with single ventricular myocytes, that benzothiazepine and dihydropyridine binding sites interact with each other. To further examine whether this interaction between the two binding sites is reflected in the function of L-type Ca2+ channels, the blocking action of diltiazem, nitrendipine, and the combination of these two drugs on L-type Ca2+ channel currents was investigated using baby hamster kidney cells expressing the alpha 1C, alpha 2/delta, beta and gamma subunits of the Ca2+ channel. The effects of diltiazem and nitrendipine were additive at room temperature but synergistic at 33 degrees C. The use-dependent block by 3 microM of diltiazem was significantly enhanced from 28% to 68% by addition of 30 nM of nitrendipine, which by itself did not have a blocking effect. Thus, we conclude that benzothiazepine- and dihydropyridine binding sites interact and potentiate their blocking action on L-type Ca2+ channels in a temperature-dependent manner.

Mechanosensitive cation channels mediate afferent arteriolar myogenic constriction in the isolated rat kidney

1. In order to assess ionic mechanisms mediating renal afferent arteriolar myogenic constriction, experiments were performed using isolated perfused hydronephrotic rat kidneys. 2. Increasing pressure progressively constricted the afferent arteriole (-0.26 +/- 0.02% mmHg-1, n = 21, r = 0.97). Gadolinium (10 microM), a mechanosensitive cation channel blocker, abolished this myogenic constriction. However, high potassium media (30 mM) constricted the afferent arteriole in the presence of gadolinium. 3. Lowering extracellular sodium concentration gradually attenuated afferent arteriolar myogenic constriction. In the perfusate containing 50 mM sodium, the myogenic response was arrested. 4. Afferent arteriolar myogenic constriction was prevented in calcium-free perfusate or by the L-type calcium channel blocker diltiazem (10 microM). 5. Our present findings provide evidence that increasing pressure gates mechanosensitive cation channels on the afferent arteriole, thereby eliciting membrane depolarization and activating voltage-dependent calcium channels.

Ca2+ signaling modulates cytolytic T lymphocyte effector functions

Cytolytic T cells use two mechanisms to kill virally infected cells, tumor cells, or other potentially autoreactive T cells in short-term in vitro assays. The perforin/granule exocytosis mechanism uses preformed cytolytic granules that are delivered to the target cell to induce apoptosis and eventual lysis. FasL/Fas (CD95 ligand/CD95)-mediated cytolysis requires de novo protein synthesis of FasL by the CTL and the presence of the death receptor Fas on the target cell to induce apoptosis. Using a CD8(+) CTL clone that kills via both the perforin/granule exocytosis and FasL/Fas mechanisms, and a clone that kills via the FasL/Fas mechanism only, we have examined the requirement of intra- and extracellular Ca2+ in TCR-triggered cytolytic effector function. These two clones, a panel of Ca2+ antagonists, and agonists were used to determine that a large biphasic increase in intracellular calcium concentration, characterized by release of Ca2+ from intracellular stores followed by a sustained influx of extracellular Ca2+, is required for perforin/granule exocytosis. Only the sustained influx of extracellular Ca2+ is required for FasL induction and killing. Thapsigargin, at low concentrations, induces this small but sustained increase in [Ca2+]i and selectively induces FasL/Fas-mediated cytolysis but not granule exocytosis. These results further define the role of Ca2+ in perforin and FasL/Fas killing and demonstrate that differential Ca2+ signaling can modulate T cell effector functions.

Tonic block of the sodium and calcium currents by ketamine in isolated guinea pig ventricular myocytes

Effects of ketamine on the sodium (INa) and L-type calcium currents (ICa) were examined by using whole-cell patch clamp techniques in guinea pig single ventricular myocytes. The mode of action of ketamine was compared with those of quinidine, a sodium channel blocker, and verapamil, a calcium channel blocker. Ketamine (30-300 microM) inhibited both INa and ICa in a concentration-dependent manner. Quinidine (30 microM) and verapamil (0.1 microM) produced use-dependent depression of INa and ICa, respectively. The amplitude of INa elicited by the first depolarizing pulse after a long quiescent period was slightly decreased by quinidine. During a train of depolarizing pulse the current amplitude decreased gradually, and reached a steady state level in the quinidine-treated cell (use-dependent block, UDB). Verapamil produced a similar mode of inhibition of ICa, i.e., UDB. In contrast, ketamine produced significant decrease in INa and ICa elicited by the first depolarizing pulses and the decreases of both currents were not augmented during a train of depolarizing pulses. From these results, it can be concluded that ketamine produces tonic block of the cardiac sodium and calcium channels and the mode of inhibition is clearly different from UDB by quinidine and verapamil.

Ligand-insensitive state of cardiac ATP-sensitive K+ channels. Basis for channel opening

The mechanism by which ATP-sensitive K+ (KATP) channels open in the presence of inhibitory concentrations of ATP remains unknown. Herein, using a four-state kinetic model, we found that the nucleotide diphosphate UDP directed cardiac KATP channels to operate within intraburst transitions. These transitions are not targeted by ATP, nor the structurally unrelated sulfonylurea glyburide, which inhibit channel opening by acting on interburst transitions. Therefore, the channel remained insensitive to ATP and glyburide in the presence of UDP. "Rundown" of channel activity decreased the efficacy with which UDP could direct and maintain the channel to operate within intraburst transitions. Under this condition, the channel was sensitive to inhibition by ATP and glyburide despite the presence of UDP. This behavior of the KATP channel could be accounted for by an allosteric model of ligand-channel interaction. Thus, the response of cardiac KATP channels towards inhibitory ligands is determined by the relative lifetime the channel spends in a ligand-sensitive versus -insensitive state. Interconversion between these two conformational states represents a novel basis for KATP channel opening in the presence of inhibitory concentrations of ATP in a cardiac cell.

Inhibitory action of insulin-sensitizing agents on calcium channels in smooth muscle cells from resistance arteries of guinea-pig

1. The actions of troglitazone, pioglitazone, metformin and bezafibrate, agents that improve insulin-resistance, on voltage-dependent Ca2+ channels in arterial smooth muscle cells were examined by use of the conventional and nystatin-perforated whole-cell clamp methods. Single cells were freshly isolated from resistance mesenteric arteries of guinea-pigs. The actions of these agents on 77 mM K+-induced contraction of the isolated arteries were also examined with the use of isometric tension recording. 2. The thiazolidinedione derivatives, troglitazone and pioglitazone, inhibited whole-cell Ca2+ currents in a dose-dependent manner with dissociation constants of 3.0 microM and 44.9 microM and Hill coefficients of 0.61 and 0.68, respectively. These two agents inhibited the 77 mM K+-induced contraction with similar potencies as those inhibiting the Ca2+ currents. Metformin and bezafibrate had no apparent effects on the Ca2+ current or high K+-induced contraction. 3. The inhibitory action of troglitazone on Ca2+ currents was not affected by the command potential, the holding potential, or the stimulation frequency, suggesting that its mode of the action differs from that of known organic Ca2+ channel antagonists. 4. The inhibitory action of troglitazone on Ca2+ currents was not affected by the addition of insulin to, or the removal of glucose from, the solutions. 5. In conclusion, the thiazolidinedione derivatives directly inhibited the voltage-dependent Ca2+ channels in a different manner from that of organic Ca2+ channel antagonists. This inhibitory action on Ca2+ channels was not a common feature of insulin-sensitizing agents.

Pharmacological properties of T-type Ca2+ current in adult rat sensory neurons: effects of anticonvulsant and anesthetic agents

We have used the whole cell patch-clamp method to study pharmacological properties of low-voltage-activated (LVA) Ca2+ current in freshly dissociated neurons from dorsal root ganglia of adult rats. Inward barium current [in the presence of internal fluoride to reduce L-type high-voltage-activated (HVA) and external 1 microM omega-conotoxin GVIA to block N-type HVA current- was evoked from negative holding potentials of -90 mV to test potentials of -25 mV and showed complete inactivation during 200-ms test pulses. Amiloride blocked approximately 90% of current with half-maximal block (EC50) of 75 microM and a Hill coefficient (n) of 0.99. LVA current was blocked completely by inorganic Ca2+ channel blockers: lanthanum (EC50 = 0. 53 microM) > zinc (EC50 = 11.3 microM) > cadmium (EC50 = 20 microM)> nickel (EC50 = 51 microM). The antiepileptics, ethosuximide (EC50 = 23.7 mM, n = 1.4), phenytoin (EC50 = 7.3 microM, n = 1.3), alpha-methyl-alpha-phenylsuccinimide (EC50 = 170 microM, n = 2.1), and valproic acid (EC50 = 330 microM, n = 1.9) maximally blocked approximately 100, 60, 26, and 17% of T current, respectively. Another antiepileptic, carbamazepine (</=100 microM), and convulsants such as pentylenetetrazole (1 mM) and tert-butyl-bicyclo [2.2.2] phosphorothionate (50 microM) had no effect on T current. Barbiturates completely blocked T current: thiopental (EC50 = 153 microM, n =1.2) > pentobarbital (EC50 = 334 microM, n = 1.2) > methohexital (EC50 = 502 microM, n = 1.3) > phenobarbital (EC50 = 1. 7 mM, n = 1.2). Blockade by thiopental and pentobarbital did not show voltage or use dependence. General anesthetics blocked T current completely and reversibly: propofol (EC50 = 12.9 microM, n = 1.3) > octanol(EC50 = 122 microM, n = 1.2) > etomidate (EC50 = 205 microM, n =1.3) > isoflurane (EC50 = 303 microM, n = 2.3) > halothane (EC50 = 655 microM, n = 2.0) > ketamine (EC50 = 2.5 mM, n = 1.1). Mibefradil, a novel Ca2+ channel blocker, blocked dorsal root ganglion T current in a voltage- and use-dependent fashion with an EC50 of approximately 3 microM (n = 1.3). When compared with results on other T currents, these data indicate that significant differences exist among different T currents in terms of pharmacological sensitivities. Furthermore, differences in pharmacological sensitivity of T currents among peripheral neurons, CNS, and neuroendocrine cells may contribute to the spectrum of effects of particular analgesic, anticonvulsant, and anesthetic drugs.

Molecular mechanism of use-dependent calcium channel block by phenylalkylamines: role of inactivation

The role of channel inactivation in the molecular mechanism of calcium (Ca2+) channel block by phenylalkylamines (PAA) was analyzed by designing mutant Ca2+ channels that carry the high affinity determinants of the PAA receptor site [Hockerman, G. H., Johnson, B. D., Scheuer, T., and Catterall, W. A. (1995) J. Biol. Chem. 270, 22119-22122] but inactivate at different rates. Use-dependent block by PAAs was studied after expressing the mutant Ca2+ channels in Xenopus oocytes. Substitution of single putative pore-orientated amino acids in segment IIIS6 by alanine (F-1499-A, F-1500-A, F-1510-A, I-1514-A, and F-1515-A) gradually slowed channel inactivation and simultaneously reduced inhibition of barium currents (I(Ba)) by (-)D600 upon depolarization by 100 ms steps at 0.1 Hz. This apparent reduction in drug sensitivity was only evident if test pulses were applied at a low frequency of 0.1 Hz and almost disappeared at the frequency of 1 Hz. (-)D600 slowed I(Ba) recovery after maintained membrane depolarization (1-3 sec) to a comparable extent in all channel constructs. A drug-induced delay in the onset of I(Ba) recovery from inactivation suggests that PAAs promote the transition to a deep inactivated channel conformation. These findings indicate that apparent PAA sensitivity of Ca2+ channels is not only defined by drug interaction with its receptor site but also crucially dependent on intrinsic gating properties of the channel molecule. A molecular model for PAA-Ca2+ channel interaction that accounts for the relationship between drug induced inactivation and channel block by PAA is proposed.

Hypoxia-induced inhibition of calcium channels in guinea-pig taenia caeci smooth muscle cells

1. The effects of hypoxia on whole-cell current in single smooth muscle cells and on a high K(+)-induced contraction of strips of the guinea-pig taenia caeci were studied. 2. In physiological salt solution (PSS) and K(+)-based pipette solution, hypoxia (PO2 = 20 mmHg) reversibly inhibited both the inward Ca2+ current (ICa) and outward Ca(2+)-activated K+ current (IK(Ca)) components of the whole-cell current. 3. In PSS and Cs(+)-based pipette solution, hypoxia reversibly suppressed ICa by 30 +/- 5% at 0 mV. 4. When Ba2+ was used as a charge carrier, the IBa was suppressed by hypoxia in a potential-dependent manner, with the maximum of 40 +/- 7% at +10 mV. Alterations of concentrations of EGTA, GDB beta S or ATP in the pipette solution did not change the inhibitory effects of hypoxia on ICa and IBa. 5. In PSS with 2 mM CaCl2 replaced by CoCl2, hypoxia did not affect the Ca2+ influx-independent potassium current. 6. In cells voltage clamped at -20 mV hypoxia reversibly inhibited the spontaneous transient outward currents. 7. The response of high K(+)-contracted taenia caeci to hypoxia was composed of an initial rapid relaxation followed by a small transient contraction and slow relaxation. The transient contraction was blocked by atropine (1-10 microM), while relaxations were unaffected by atropine and guanethidine (10 microM). 8. The results show that hypoxia reversibly inhibits ICa and secondarily suppresses IK(Ca) due to decreased Ca2+ influx through Ca2+ channels. 9. It is suggested that inhibition of ICa was responsible for the rapid relaxation, whereas transient contraction may have been due to release of acetylcholine from nerve terminals upon hypoxia.

Multiple modulations of action potential duration by different calcium channel blocking agents in guinea pig ventricular myocytes

Effects of extracellular applications of different types of Ca2+ channel blocking agents (Mn2+, verapamil, and nisoldipine) on action-potential duration and membrane currents were studied by the whole-cell patch-clamp technique in guinea pig ventricular myocytes. Low concentrations of Mn2+ (1 mM) and verapamil (1 microM) prolonged action-potential duration at 90% repolarization (APD90) with a suppressed plateau phase. Increases in Mn2+ (5 mM) and verapamil (5 microM) shortened APD90 with a further depression of the plateau. Nisoldipine (0.2-1 microM) shortened APD90 without lengthening it. Applications of Mn2+ and verapamil suppressed amplitudes of the L-type Ca2+ current (ICa), the delayed outward K+ current (IK), and the inward rectifier K+ current (IK1). Furthermore, the ratios of ICa:IK inhibition were similar by low and high concentrations of Mn2+ and verapamil. Nisoldipine selectively suppressed ICa without effect on IK and IK1. A low concentration (1 mM) of Mn2+ not only decreased the peak amplitude of ICa but also delayed its decay time course, which caused an increase in late ICa amplitude at the end of a 200-ms depolarizing pulse. Both verapamil and nisoldipine suppressed peak ICa without affecting its decay. Whereas Mn2+ suppressed IBa without changing its decay time course, verapamil and nisoldipine speeded up the IBa decay with suppressed amplitude of IBa. We conclude that different types of Ca2+ channel blocking agents (Mn2+, verapamil, and nisoldipine) diversely modulate APD because of their multiple modes of actions on ICa and IK.

Inhibition of L-type Ca2+ channel current in rat ventricular myocytes by terfenadine

To elucidate possible mechanisms underlying the cardiotoxicity of terfenadine, the effect of this antihistamine on L-type Ca2+ channel current (ICa,L) was studied in adult rat ventricular myocytes using the whole-cell patch-clamp technique. Myocytes were held at -70 mV and internally dialyzed and externally perfused with Na(+)- and K(+)-free solutions; exposure to terfenadine (10(-9) to 5 x 10(-6) mol/L) resulted in a concentration-dependent inhibition of peak ICa,L with a half-maximum inhibition concentration (IC50) of 142 nmol/L. The terfenadine-induced inhibition of ICa,L was not mediated via effects on histamine H1 receptors, because 1 mumol/L triprolidine, a more selective and potent H1 antagonist, had no effect on ICa,L. In this study, we found that terfenadine (1) increased both the fast and slow time constants of ICa,L inactivation, (2) shifted the steady state inactivation of ICa,L to more negative potentials, and (3) elicited a tonic block and a use-dependent block of ICa,L. The terfenadine-induced tonic and use-dependent block and the steady state inhibition of ICa,L were voltage dependent. Both tonic and use-dependent blocks of ICa,L by terfenadine at -40 mV were greater than that at -70 mV, and blocks were partially released by applying a long hyperpolarizing prepulse to -90 mV. These results suggest that terfenadine binds to L-type Ca2+ channels in inactivated and rested states and inhibits ICa,L predominantly by interacting with the inactivated state with an apparent dissociation constant of 60 nmol/L. Open-state block could be observed only at high concentrations of terfenadine. The high-affinity interaction of terfenadine with the inactivated state of L-type Ca2+ channels may play an important role in its cardiotoxicity under pathophysiological conditions, such as ischemia.

Effects of CP-060S on membrane channels in vascular smooth muscle cells from guinea pig

The newly developed cardioprotective drug, CP-060S, (-)-(S)-2-[3,5-bis(1,1-dimethylethyl)-4-hydroxyphenyl]-3-[3-[N-methyl-N- [2-(3,4-methylenedioxyphenoxy) ethyl] amino] propyl]-1,3-thiazolidin-4-one hydrogen fumarate, is reported to possess a vasodilating action. Our objective was to examine the effects of CP-060S on the membrane channels in mesenteric arterial cells from guinea pigs, using whole-cell patch-clamp techniques. CP-060S inhibited the Ca2+ channel current in a concentration-dependent manner (ED50 = 1.7 microM at a holding potential of -80 mV and a stimulation frequency of 0.1 Hz). The inhibition was potentiated by a more depolarized holding potential and a higher stimulation frequency. These effects of CP-060S resembled those of diltiazem and gallopamil more than to those of nifedipine; the inhibition was more frequency dependent and less holding-potential dependent than with nifedipine. Higher concentrations of CP-060S also inhibited the delayed K+ channel currents (ED50 = 18 microM). The present observations suggest that CP-060S exhibits the profile of a Ca2+ channel antagonist, similar to that of diltiazem and gallopamil.

Calcium channel block by (-)devapamil is affected by the sequence environment and composition of the phenylalkylamine receptor site

The pore-forming alpha 1 subunit of L-type calcium (Ca2+) channels is the molecular target of Ca2+ channel blockers such as phenylalkylamines (PAAs). Association and dissociation rates of (-)devapamil were compared for a highly PAA-sensitive L-type Ca2+ channel chimera (Lh) and various class A Ca2+ channel mutants. These mutants carry the high-affinity determinants of the PAA receptor site in a class A sequence environment. Apparent drug association and dissociation rate constants were significantly affected by the sequence environment (class A or L-type) of the PAA receptor site. Single point mutations affecting the high-affinity determinants in segments IVS6 of the PAA receptor site, introduced into a class A environment, reduced the apparent drug association rates. Mutation I1811M in transmembrane segment IVS6 (mutant AL25/-I) had the highest impact and decreased the apparent association rate for (-)devapamil by approximately 30-fold, suggesting that this pore-lining isoleucine in transmembrane segment IVS6 plays a key role in the formation of the PAA receptor site. In contrast, apparent drug dissociation rates of Ca2+ channels in the resting state were almost unaffected by point mutations of the PAA receptor site.

Actin assembly by cadmium ions

Cadmium is a highly toxic metal entering cells by a variety of mechanisms. Its toxic action is far from being completely understood, although specific interaction with the cellular calcium metabolism has been indicated. Metal ions that influence intracellular Ca2+ concentrations or compete with Ca2+ for protein binding sites may exert an effect on actin filaments, whose assembly and disassembly are both regulated by a number of calcium-dependent factors. Cadmium is such a metal. Much evidence demonstrates that cadmium interferes with the dynamics of actin filaments in various types of cells. Here we show that, at high (0.8-1.0 mM) concentrations, CdCl2 causes actin denaturation. At such Cd2+ concentrations, actin precipitates (really actin, as shown by SDS-PAGE, see Fig. 1B) in the form of irregular, disordered clots, clearly appreciable by electron microscopy. Denaturation seems to be reversible since, after Cd2+ removal by dialysis, the polymerizability of sedimented actin is restored almost completely. On the other hand, at concentrations ranging from 0.25 to 0.6 mM, CdCl2 is more effective as an actin polymerizing agent than both MgCl2 and CaCl2. The Cd-related increase in the actin assembly rate is ascribable to an enhanced nucleation rather than to an increased monomer addition to filament growing ends. The latter, in contrast, appears quite slow. Critical concentration measurements revealed that the extent of polymerization of both Mg- and Cd-assembled actin are very close (C(c) ranges from 0.25 to 0.5 microM), while Ca-polymerized actin shows a polymerization extent markedly lower (C(c) = 4.0 microM). By both the fluorescent Ca2+ chelator Quin-2 assay and limited proteolysis of actin by trypsin and alpha-chymotrypsin, the real substitution of G-actin-bound Ca2+ by Cd2+ has been appreciated. The increase in Quin-2 fluorescence after addition of excess CdCl2 indicates that, in our experimental conditions, Ca2+ tightly-bound to actin is partially (60-70%) replaced by Cd2+, forming Cd-actin. Electrophoretic patterns after limited proteolysis reveal that the trypsin cleavage sites in the segment 61-69 of the actin polypeptide chain are less accessible in Cd-actin than in Ca-actin, although the cation-dependent effect is less pronounced in Cd-actin than in Mg-actin. Our results are consistent with some of the consequences on microfilament organization observed in Cd2(+)-treated cells; however, considering the positive effect of Cd2+ on actin polymerization in solution we have noticed that this was never observed in vivo. A different indirect effect of Cd2+ on some cellular event(s) influencing cytoplasmic actin polymerization appears to be reasonable.

Preferential interaction of omega-conotoxins with inactivated N-type Ca2+ channels

The selective block of N-type Ca2+ channels by omega-conotoxins has been a hallmark of these channels, critical in delineating their biological roles and molecular characteristics. Here we report that the omega-conotoxin-channel interaction depends strongly on channel gating. N-type channels (alpha1B, alpha2, and beta1) expressed in Xenopus oocytes were blocked with a variety of omega-conotoxins, including omega-CTx-GVIA, omega-CTx-MVIIA, and SNX-331, a derivative of omega-CTx-MVIIC. Changes in holding potential (HP) markedly altered the severity of toxin block and the kinetics of its onset and removal. Notably, strong hyperpolarization renders omega-conotoxin block completely reversible. These effects could be accounted for by a modulated receptor model, in which toxin dissociation from the inactivated state is approximately 60-fold slower than from the resting state. Because omega-conotoxins act exclusively outside cells, our results suggest that voltage-dependent inactivation of Ca2+ channels must be associated with an externally detectable conformational change.

Inhibition of voltage-dependent Ca2+ channels of porcine tracheal smooth muscle by the novel Ca2+ channel antagonist RWJ-22108

1. We compared electrophysiological effects of the bronchoselective Ca2+ channel antagonist RWJ-22108 on voltage-dependent Ca2+ channels (VDCs) of porcine tracheal smooth muscle cells to the effects of nicardipine and verapamil. 2. Each of the three Ca2+ channel antagonists tested inhibited inward Ca2+ currents (ICa) measured by whole-cell patch clamp techniques. Inhibition was dose-dependent with approximately 50% inhibition of peak ICa at +20 mV obtained with 3 x 10(-6) M RWJ-22108, 3 x 10(-7) M nicardipine, or 10(-5) M verapamil. 3. Both RWJ-22108 (3 x 10(-6) M) and nicardipine (3 x 10(-7) M) shifted the voltage dependence of steady-state inactivation to more negative potentials; however, the change in the potential of half-maximal inactivation induced by RWJ-22108 (-18 mV) was significantly greater than that induced by nicardipine (-12 mV). Verapamil did not alter the voltage dependence of inactivation. 4. We conclude that inhibition of VDCs by RWJ-22108 is qualitatively similar to that by nicardipine but with a greater stabilizing effect on the inactivated channel state.

Calcium is required for swimming by the nonflagellated cyanobacterium Synechococcus strain WH8113

The marine cyanobacterium Synechococcus strain WH8113 swims in the absence of any recognizable organelles of locomotion. We have found that calcium is required for this motility. Cells deprived of calcium stopped swimming, while addition of calcium completely restored motility. No other divalent ions tested could replace calcium. Terbium, a lanthanide ion, blocked motility even when calcium was present at 10(5)-fold-higher concentrations, presumably by occupying calcium binding sites. Calcium chelators, EGTA or EDTA, blocked motility, even when calcium was present at 25-fold-higher concentrations, presumably by acting as calcium ionophores. Finally, motility was blocked by verapamil and nitrendipine, molecules known to block voltage-gated calcium channels of eukaryotic cells by an allosteric mechanism. These results suggest that a calcium potential is involved in the mechanism of motility.

Volume regulation of spermatozoa by quinine-sensitive channels

Bovine spermatozoa were shown to exhibit rapid regulatory volume decrease (RVD) when exposed to hypotonic saline media. This quinine- and quinidine-sensitive regulatory volume decrease was coincident with K+ release due to stretch-activation of inhibitor-specific presumptive K+ channels. The regulatory volume decrease response was much faster than a similar phenomenon observed in human peripheral blood lymphocytes. Studies on volume changes in different electrolyte and nonelectrolyte media suggested that: (1) this inhibitor-specific channel could also be a nonspecific pore in the spermatozoal membrane for nonelectrolytes below 150 daltons; (2) subpopulations (of nearly equal size) of the spermatozoa differ in the expression of the pore; (3) capacitation abolishes this distinction between subpopulations of spermatozoa; and (4) the general case of RVD for other mammalian spermatozoa was also established.

A novel benzothiazine Ca2+ channel antagonist, semotiadil, inhibits cardiac L-type Ca2+ currents

The influence of semotiadil fumarate, a novel vasoselective Ca2+ channel antagonist with a benzothiazine skeleton, was measured on the high-threshold Ca2+ current ICa,L in guinea-pig ventricular myocytes prepared by coronary perfusion with collagenase solution. Patch- and voltage-clamp methods were used to measure ICa,L. Diltiazem, nifedipine and amlodipine were studied for comparison. Samotiadil could be shown to inhibit ICa,L in a dose-dependent manner in concentrations similar to those of diltiazem but was less effective than amlodipine and nifedipine. The IC50 for nifedipine and amlodipine was in the range between 0.1 and 1 microM and that of semotiadil and diltiazem was between 10 and 100 microM. Recovery from inactivation of ICa,L in the control and under the influence of nifedipine 0.01 microM) and amlodipine (0.1 microM) was complete alter I. Semotiadil (0.1 microM) and diltiazem (1 microM) prolonged the time to full recovery to 20 s. This significant delay in the recovery of ICa,L produced by semotiadil indicates a mode of action similar to that of the verapamil type of Ca2+ channel antagonists and masses a clear distinction between it and the dihydropyridines, which have no effect on the recovery process. The rate dependence of the effect in combination with a distinct influence of the holding potential underlines the use dependence of the mechanism underlying the effect of semotiadil. The well-known high vasoselectivity of semotiadil in combination with a relatively low Ca2+ channel antagonistic influence on the heart makes semotiadil an interesting candidate for the treatment of coronary heart diseases.

Characteristics of L-type calcium channel blockade by lacidipine in guinea-pig ventricular myocytes

1. The Ca(2+)-antagonistic properties of lacidipine were investigated in patch-clamp guinea-pig ventricular myocytes. 2. In basal conditions, 0.1 microM lacidipine reduced the action potential duration, associated with a decrease in the L-type calcium current (ICa,L) to 66 +/- 4% of the control value, without a change in the current-voltage relationship. Sodium current and background potassium currents were not affected. All the effects reached a steady state within 2 min. 3. The Ca(2+)-antagonistic effect of lacidipine was voltage-dependent: a marked negative shift (about 20 mV) of the steady-state inactivation curve was observed with long (10 s) conditioning prepulses, but not with short (350 ms) prepulses. 4. The onset of and recovery from the voltage-dependent effect caused by 0.1 microM lacidipine were significantly slower when compared to those of equiactive concentrations of nimodipine (0.5 microM) and nisoldipine (0.1 microM). ICa,L measured after prepulses at -40 mV lasting 500 ms or less was unchanged (95 +/- 5% of maximum current value) while it was reduced to 49 +/- 10% by nimodipine and 43 +/- 9% by nisoldipine (P < 0.05 vs lacidipine for both). 5. Similarly, the recovery from block in the presence of lacidipine was slower than with nimodipine and nisoldipine. After a prepulse of 1 s at -80 mV, ICa,L recovered up to 54 +/- 2% of the maximum current value in the presence of lacidipine, and up to 91 +/- 3% and 93 +/- 5% in the presence of nimodipine and nisoldipine, respectively (P < 0.05 vs lacidipine). 6. Blockade of ICa,L by lacidipine was use-dependent. After ten 200 ms long pulses (1 Hz) from -80 mV, ICa,L was reduced to 55 +/- 7% of the current measured at the first pulse. In the presence of nimodipine and nisoldipine, ICa,L elicited by the tenth pulse amounted to 93 +/- 3% and 80 +/- 6% of the first pulse value, respectively (P < 0.05 vs lacidipine). Lacidipine did not cause use-dependent blockade of ICa,L in cells stimulated with 10 ms long pulses. 7. These results demonstrate that lacidipine selectively inhibits ICa,L in isolated cardiomyocytes and suggest that this effect occurs mainly through binding to the inactivated Ca2+ channels.

Effects of aranidipine, a novel calcium channel blocker, on mechanical responses of the isolated rat portal vein: comparison with typical calcium channel blockers and potassium channel openers

We investigated the effects of aranidipine, a dihydropyridine-type Ca2+ channel blocker, on contractile responses to KCl and spontaneous contractions in isolated rat portal veins in comparison with those of the Ca2+ channel blockers, nifedipine, nicardipine, nitrendipine, diltiazem, and verapamil, and of the K+ channel openers, cromakalim and nicorandil. All the Ca2+ channel blockers concentration-dependently inhibited contractions induced by KCl. Interestingly, aranidipine was more potent against the low K+ (20 mM)-induced contraction than the high K+ (80 mM)-induced contraction, whereas the other Ca2+ channel blockers were equally potent against contractions induced by either concentration of KCl. Cromakalim and nicorandil were effective only on the low K(+)-induced contraction. In addition, all the Ca2+ channel blockers and the K+ channel openers tested inhibited the amplitude of spontaneous contractions of isolated rat portal vein. Tetraethylammonium (TEA), a classic K+ channel blocker, significantly attenuated the effect of aranidipine but not of other Ca2+ channel blockers on the spontaneous contractions. The cromakalim-induced inhibition of spontaneous contractions was antagonized by TEA. Thus aranidipine was found to be different from the typical Ca2+ channel blockers and in part similar to the K+ channel openers in inhibiting mechanical responses of isolated rat portal vein, suggesting that activation of K+ channels may in part in part be involved in the aranidipine-induced vasodilation.

Inhibition of [3H]-U69593 binding and the cardiac effects of U50, 488H by calcium channel blockers in the rat heart

1. The calcium channel blockers (CCBs), nifedipine, nicardipine, diltiazem and verapamil, were used to displace the binding of [3H]-U69593 ((5a, 7a,8b)-(+)-N-methyl-N-(7-[1-pyrrolidinyl]-1-oxaspiro[4,5] dec-8-yl)-benzeneacetamide), a specific kappa-opioid agonist, in the rat cardiac sarcolemma. The CCBs competed with the binding of [3H]-U69593 (4 nM) in a dose-dependent manner. The displacing potency of verapamil was 55 times greater than that of nifedipine. 2. The effects of two CCBs, verapamil and nifedipine, on the arrhythmogenic action of kappa-receptor stimulation by a specific kappa-receptor agonist, U50,488H (trans-(+/-(-3),4-dichloro-N-methyl-N-(2-[1-pyrrolidinyl] cyclohexyl) benzeacetamide methanesulphonate), were also studied in the rat isolated perfused heart. U50,488H 80-800 nmol dose-dependently induced arrhythmias, which were completely abolished by a selective kappa-receptor antagonist, nor-BNI (nor-binaltorphimine, 17,17'-(dicyclopropylmethyl)-6,6',7,7'-6,6'-imino-7,7'-binorphinan -3,4',14, 14'-tetrol), at 100 nmol. The arrhythmogenic effect was also attenuated by both verapamil and nifedipine in a dose-dependent manner. The ED50 values for verapamil and nifedipine were 2.75 and 63.7 nmol, respectively. The antiarrhythmic potencies of these two CCBs were correlated to their displacing potencies and inversely related to their well known potencies in inhibiting transmembrane Ca2+ influx in the cardiac muscle. 3. Measurement of [Ca2+]i in the absence of free extracellular Ca2+ by a spectrofluorometric method, with fura-2 as Ca2+ indicator, showed that U50,488H 5 x 10(-5) M slowly increased [Ca2+]i in single ventricular myocytes and this effect was abolished by pretreatment with nor-BNI (5 microM), or ryanodine (5 microM). Verapamil 1 and 10 microM abolished the effect of U50,488H in 37.5% (3 out of 8) and 100% (12 out of 12) of the cells studied, respectively. On the other hand, nifedipine 10 and 100 microM had no effect at all. Neither verapamil nor nifedipine exerted any significant effect on the caffeine-induced Ca2+ transient. 4. The observations suggest that CCBs may inhibit the actions of kappa-receptor stimulation at the level of the kappa-receptor.

Molecular determinants of drug binding and action on L-type calcium channels

The crucial role of L-type Ca2+ channels in the initiation of cardiac and smooth muscle contraction has made them major therapeutic targets for the treatment of cardiovascular disease. L-type channels share a common pharmacological profile, including high-affinity voltage- and frequency-dependent block by the phenylalkylamines, the benz(othi)azepines, and the dihydropyridines. These drugs are thought to bind to three separate receptor sites on L-type Ca2+ channels that are allosterically linked. Results from different experimental approaches implicate the IIIS5, IIIS6, and IVS6 transmembrane segments of the alpha 1 subunits of L-type Ca2+ channels in binding of all three classes of drugs. Site-directed mutagenesis has identified single amino acid residues within the IIIS5, IIIS6, and IVS6 transmembrane segments that are required for high-affinity binding of phenylalkylamines and/or dihydropyridines, providing further support for identification of these transmembrane segments as critical elements of the receptor sites for these two classes of drugs. The close proximity of the receptor sites for phenylalkylamines, benz(othi)azepines, and dihydropyridines raises the possibility that individual amino acid residues may be required for high-affinity binding of more than one of these ligands. Therefore, we suggest that phenylalkylamines and dihydropyridines bind to different faces of the IIIS6 and IVS6 transmembrane segments and, in some cases, bind to opposite sides of the side chains of the same amino acid residues. The results support the domain interface model for binding and channel modulation by these three classes of drugs.

Effect of the organic Ca2+ channel blocker D-600 on sarcoplasmic reticulum Ca2+ uptake in skeletal muscle

Experiments were undertaken to study the possibility that the calcium channel blocker D-600 (gallopamil), which penetrates into muscle cells (20), facilitates excitation-contraction coupling in skeletal muscle (7) by a direct effect on the sarcoplasmic reticulum (SR). The effects of D-600 were studied on single phasic muscle fibers, either intact or split open. D-600 potentiated twitches in intact fibers at concentrations lower than those reported in whole muscles. In split fibers, the force produced by caffeine-induced Ca2+ release from the SR was reversibly inhibited by 5 microM D-600, when added to the Ca2+ loading solution. This inhibitory effect was inversely related to temperature, and it was dose dependent. When D-600 was added after Ca2+ loading and before caffeine exposure, or during the caffeine exposure itself, it did not inhibit Ca2+ release, but rather increased the development of force. We conclude that, apart from the blocking effect that D-600 may have on the voltage sensor, the drug penetrates into the myoplasm and affects excitation-contraction coupling by inhibiting the SR Ca2+ pump. This may be the consequence of a conformational change in the transmembrane Ca2+ binding domain of the ATPase.

Effects of KT-362, a sarcolemmal and intracellular calcium antagonist, on calcium transients of cultured neonatal rat ventricular cells: a comparison with gallopamil and ryanodine

We evaluated the effects of KT-362 (5-[3-([2-(3,4-dimethoxyphenyl)-ethyl]amino)-1-oxopropyl]-2,3,4,5, -tetrahydro-1,5-benzothiazepine fumarate), a putative intracellular calcium antagonist, on the intracellular free calcium concentration ([Ca2+]i) of cultured neonatal rat ventricular cells using microfluorometry of fura-2. The effects were compared with those of gallopamil (D-600), a sarcolemmal calcium channel antagonist, and ryanodine, a modulator of sarcoplasmic reticulum (SR) function. KT-362 decreased both systolic [Ca2+]i (sCa) and diastolic [Ca2+]i (dCa) in cell aggregates, in a concentration (1, 3, 10, and 30 microM) and stimulation frequency (0.2, 0.5, and 1.0 Hz) dependent manner. The time to peak of the Ca2+ transient was significantly prolonged by KT-362 at a concentration of 30 microM, while the half-life of the Ca2+ transient was prolonged at concentrations of > or = 10 microM. Gallopamil (1 microM) decreased both sCa and dCa in a frequency (0.2, 0.5, and 1.0 Hz) dependent fashion, as was the case for KT-362, but did not change the time course of Ca2+ transients. Ryanodine (10 microM) prolonged the time to peak and half-life of the Ca2+ transient, as was also the case for KT-362, while the effect of ryanodine on dCa differed from that of KT-362. Finally, the effect of KT-362 on Ca2+ transients could be mimicked by simultaneous application of gallopamil and ryanodine. These results suggest that KT-362 is a novel compound that exerts depressant effects on both sarcolemmal Ca2+ channels, and perhaps Ca2+ release channels of the sarcoplasmic reticulum, in cultured neonatal rat ventricular cells.

Calcium-antagonist effects of norbormide on isolated perfused heart and cardiac myocytes of guinea-pig: a comparison with verapamil

1. Cardiac effects on norbormide and verapamil were compared in single ventricular myocytes, right atria, and Langendorff perfused hearts isolated from guinea-pigs. 2. In ventricular myocytes, norbormide 50 microM inhibited the peak calcium current (ICa) by 49.6 +/- 3.9% without altering the shape of the current-voltage relationship; verapamil 1 microM inhibited ICa by 83.2 +/- 3.3%. Neither norbormide nor verapamil affected ICa at the first beat after a 3 min quiescence period; during repeated depolarizations, both drugs cumulatively blocked ICa (use-dependence), with time constants of 23.0 +/- 7.0 s for norbormide and 91.3 +/- 8.4 s for verapamil. 3. In constant-flow perfused hearts electrically driven at 2.5 Hz or 3.3 Hz, both norbormide and verapamil concentration-dependently decreased ventricular contractility (dP/dtmax), atrio-ventricular (AV) conduction velocity and coronary pressure. Intraventricular conduction velocity was slightly decreased by norbormide but not by verapamil. At an equivalent change in AV conduction, norbormide depressed heart contractility less than verapamil. The effects of norbormide on AV conduction, intraventricular conduction, and contractility were frequency-dependent. Furthermore, the curves correlating the mechanical and electrical effects of norbormide at the two frequencies used were apparently coincident, while those of verapamil were clearly separated. 4. In spontaneously beating right atria, norbormide and verapamil decreased the frequency of sinus node (SA) in a concentration-dependent way. At an equivalent effect on the AV conduction, norbormide exerted a greater effect on sinus frequency than verapamil. 5. These results indicate that in guinea-pig heart norbormide has the pharmacological profile of a Ca-antagonist with strong electrophysiological properties. In comparison with verapamil, norbormide is more selective on SA and AV node tissues and exerts a weaker negative inotropic effect on ventricles. In principle, this pattern of effects may be an advantage in treating supraventricular tachyarrhythmias in patients with heart failure. The effect of norbormide on intraventricular conduction may represent an additional antiarrhythmic mechanism.

Quantification of rate-dependent effects of verapamil, diltiazem, and digoxin on atrioventricular conduction

The calcium channel blocking agents, verapamil and diltiazem, and the digitalis compound, digoxin, caused drug specific rate-dependent changes of the atrioventricular conduction time (AVCT). The purpose of this study was to investigate this rate adaptation of the AVCT in isolated guinea pig hearts perfused by the method of Langendorff to get an insight in drug-specific binding kinetic to the respective channel. In the presence of 10 nM verapamil, 30 nM diltiazem, or 0.6 nM digoxin, the atrioventricular conduction time was prolonged to a comparable degree during sinus rhythm. The drug-specific time constant, characterizing the rate-dependent adaptation of the AVCT, in the presence of a substance was comparable if evaluated after abruptly changing the heart rate from the pacing cycle length of 240 ms to 180 ms (tau-on) or from 180 to 240 ms (tau-off). The adaptation of the AVCT in the presence of verapamil (tau-on = 178 +/- 45 beats, tau-off = 125 +/- 33 beats, mean +/- SEM) was more pronounced than in the presence of digoxin (tau-on = 144 +/- 24 beats, tau-off = 98 +/- 15 beats) or diltiazem (tau-on = 70 +/- 11 beats, tau-off = 98 +/- 15 beats). In conclusion, the differences in the rate adaptation of the AVCT may be explained by the drug-specific association and dissociation kinetic to the calcium channel, slow in the case of verapamil, and fast in the case of dilitiazem, whereas this phenomenon in the presence of digoxin may be explained by its direct effects on passive membrane properties.

Extra- and intracellular action of quaternary devapamil on muscle L-type Ca(2+)-channels

1. The quaternary derivative of the potent verapamil-analogue, (-)-D888, (qD888, 4-cyano-4-(3,4-dimethoxyphenyl)-N-[2-(3-methoxy phenyl)ethyl]-N,N,5-trimethyl-1-hexanaminium) was synthesized as a novel membrane-impermeable probe to study the localization of phenylalkylamine (PAA) effector domains on L-type Ca2+ channels. Channel block by qD888 was investigated in smooth muscle-like (A7r5) cells after extra- and intracellular application by use of the whole-cell configuration of the patch clamp technique. 2. Extracellularly applied qD888 inhibited Sr2+ (Isr) (IC50 = 90 microM) and Na+ (IC50 = 27 microM) inward currents through L-type Ca(2+)-channels mainly in a resting-state-dependent manner. Structurally closely related quaternary PAAs (e.g. D890) were ineffective after extracellular application. 3. QD888 also blocked Isr from the cytoplasmic side, as did other quaternary PAAs (D890, D575). Intracellular block was clearly dependent on channel opening, which resulted in pronounced use-dependence. 4. We conclude that qD888 blocks L-type Ca2+ channels not only from the intracellular side, via interaction with the classical PAA binding domain, but also from the extracellular channel surface. The properties of Ca2+ channel block together with previous biochemical and structural data suggest that extracellular block may be mediated by a site that also confers tonic block by quaternary benzothiazepines.

Transfer of high sensitivity for benzothiazepines from L-type to class A (BI) calcium channels

To investigate the molecular basis of the calcium channel block by diltiazem, we transferred amino acids of the highly sensitive and stereoselective L-type (alpha1S or alpha1C) to a weakly sensitive, nonstereoselective class A (alpha1A) calcium channel. Transfer of three amino acids of transmembrane segment IVS6 of L-type alpha1 into the alpha1A subunit (I1804Y, S1808A, and M1811I) was sufficient to support a use-dependent block by diltiazem and by the phenylalkylamine (-)-gallopamil after expression in Xenopus oocytes. An additional mutation F1805M increased the sensitivity for (-)-gallopamil but not for diltiazem. Our data suggest that the receptor domains for diltiazem and gallopamil have common but not identical molecular determinants in transmembrane segment IVS6. These mutations also identified single amino acid residues in segment IVS6 that are important for class A channel inactivation.