Cardiac sarcolemma as a possible site of action of caffeine in rat heart

Caffeine (0.1-10 mM) produced a biphasic effect on Na(+)-K+ ATPase activity in the rat heart sarcolemmal preparations. The Na(+)-K+ ATPase activity was stimulated by about 25% at low concentrations (0.1-1 mM), whereas the enzyme was inhibited by about 25% at higher concentrations (10 mM) of caffeine. The stimulatory effect of 1 mM caffeine was associated with about 30% increase in the Vmax value for Na(+)-K+ ATPase, whereas the depressant action of 10 mM caffeine was associated with an increase of the Km value from 1.4 to 2.1 mM ATP. The Na(+)-induced Ca++ release from the sarcolemmal vesicles was stimulated with caffeine in a concentration-dependent manner; about 80% increase in the activity was observed at 0.1 mM caffeine. The apparent Ka (millimolar Na+) values for the Na(+)-induced Ca++ release were about 17 and 6 in the absence and presence of 1 mM caffeine, respectively. However, the sarcolemmal Na(+)-dependent Ca++ uptake and ATP-independent Ca++ binding were not affected, whereas the ATP-dependent Ca++ accumulation and Ca+(+)-stimulated ATPase activities were depressed by 1 to 10 mM caffeine. This agent at concentrations of 0.1 to 10 mM produced a biphasic effect on the contractile activity of the isolated perfused rat heart. The initial transient positive inotropic (30-60%) effect was followed by a sustained negative inotropic (50-80%) response of the drug; the delayed decrease in contractile force was associated with a significant increase (35-50%) in the resting tension. The initial positive inotropic effect of caffeine was dependent on the concentration of Ca++ (0.2-3 mM) in the perfusion medium; however, this response was attenuated either by lowering the concentration of Na+ from 140 to 35 mM or by different concentrations (0.5-1 mM) of amiloride in the medium.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cardiotonic action of [8]-gingerol, an activator of the Ca++-pumping adenosine triphosphatase of sarcoplasmic reticulum, in guinea pig atrial muscle

[8]-Gingerol (gingerol), a component of ginger, produced a concentration-dependent positive inotropic effect on guinea pig isolated left atria at concentrations of 1 X 10(-6) to 3 X 10(-5) M. Gingerol also exhibited positive inotropic and chronotropic effects on guinea pig right atria. The gingerol-induced inotropic effect was abolished by ryanodine, but was little affected by propranolol, chlorpheniramine, cimetidine, tetrodotoxin, diltiazem or reserpine. The time to peak tension and relaxation time within a single contraction were shortened by gingerol (1 X 10(-5) M) as well as isoproterenol, whereas they were prolonged by BAY K 8644. In guinea pig isolated atrial cells, gingerol (3 X 10(-6) M) caused an increase in the degree and the rate of longitudinal contractions. In guinea pig left atria, gingerol (1 X 10(-6) to 3 X 10(-5) M) gave little influence on the action potential, although it increased the contractile force of the atria. The whole-cell patch-clamp experiments showed that the slow inward current was little affected by gingerol (1 X 10(-6) to 3 X 10(-5) M) in voltage-clamped guinea pig cardiac myocytes. The measurement of extravesicular Ca++ concentration using a Ca++ electrode indicated that gingerol (3 X 10(-6) to 3 X 10(-5) M) accelerated the Ca++ uptake of fragmented sarcoplasmic reticulum (SR) prepared from canine cardiac muscle in a concentration-dependent manner.(ABSTRACT TRUNCATED AT 250 WORDS)     

Vascular and cardiac effects of a new dihydropyridine derivative, YC-170: a comparison with Bay K 8644

The pharmacological effects of YC-170, a new dihydropyridine derivative, were studied in the rabbit aortic strips and guinea pig cardiac preparations and compared with those of Bay K 8644. In the rabbit aortic strips, YC-170 produced contraction in normal physiological saline solution ([K+]0 = 5.9 mM) in a concentration-dependent manner. Increasing the [K+]0 of the medium to 15 mM enhanced the contractile response. The maximum contraction produced by YC-170 at [K+]0 of 15 mM was comparable to that by Bay K 8644. However, YC-170 induced relaxation when the strip was contracted by 60 mM K+. In guinea pig left atrium, YC-170 produced a positive inotropic effect in a concentration-dependent manner, but its extent was far less than that of Bay K 8644. Like Bay K 8644, however, YC-170 increased the time to peak tension and relaxation time of the isometric tension, and prolonged the action potential duration. YC-170 failed to produce a positive inotropic action in the papillary muscle in which Bay K 8644 was a potent positive inotropic agent. In spontaneously beating right atria, YC-170 caused a negative chronotropic effect, whereas Bay K 8644 a positive one. The positive inotropic and vasoconstrictor effects of YC-170 were antagonized competitively by a Ca++ antagonist nicardipine. When the left atria were depolarized with high-K+ medium, the positive inotropic effect of YC-170 was attenuated progressively with increasing [K+]0 and at 13.2 mM K+ a negative inotropic effect was induced by YC-170.(ABSTRACT TRUNCATED AT 250 WORDS)     

Phospholipid N-methylation-dependent alterations of cardiac contractile function by L-methionine

Isolated rat, rabbit and guinea pig hearts exhibited an initial negative inotropic (20-30%) effect followed by a positive inotropic response (60-80%) upon perfusion with 300 microM L-methionine. In contrast, frog hearts did not show any delayed positive inotropic effect, whereas initial negative inotropic effect (25%) of L-methionine was seen. In subsequent studies using rat hearts, methionine was found to induce a dose-dependent increase in contractile force which correlated linearly (r = 0.93) with incorporation of methyl groups into tissue N-methylated phospholipids. The presence of adenosine, L-homocysteine thiolactone and erythro-9-(2-hydroxy-3-nonyl) adenine mixture in the perfusion medium inhibited the contractile effects of L-methionine as well as the incorporation of 3H-methyl groups by about 75%. Cycloleucine, an inhibitor of S-adenosylmethionine synthase, and methyl acetimidate, a blocker of the phosphatidylethanolamine polar groups, inhibited phospholipid N-methylation and prevented the contractile changes due to L-methionine. The initial negative inotropic effect of methionine was attenuated by lowering the concentration of Na+, whereas the delayed positive inotropic effect was dependent on the concentration of Ca++ in the perfusion medium. Ryanodine, a blocker of the sarcoplasmic reticular Ca++ release, prevented the positive inotropic effect of methionine whereas verapamil, a well known Ca++ antagonist, blocked the initial depressant effect and reduced the delayed positive inotropic response. Marked alterations in the sarcolemmal and sarcoplasmic reticular calcium transport activities were seen upon perfusing the hearts with methionine.(ABSTRACT TRUNCATED AT 250 WORDS)     

Digitalis-induced mechanical toxicity: protection by slow Ca++ channel blockers

In the in vitro perfusion of the isolated heart, toxic doses of cardiac glycosides produce an inotropic response which is followed by a decline in contractile force and an increase in the resting tension. Several reports in the literature indicate that the subsequent decline in contractile force may be related to cardiac cellular Ca++ overload. The purpose of the present study was to determine if the slow Ca++ channel blockers such as verapamil and nifedipine, which block Ca++ influx through voltage-dependent gated channels, can reduce or prevent the digitalis-induced decline in contractile force (mechanical toxicity). Langendorff preparations of isolated perfused guinea pig heart were used for the present study. The data obtained demonstrate that 1 to 2 microM ouabain in the perfusion medium produced mechanical toxicity in the hearts after an initial inotropic response. Verapamil or nifedipine, when combined with ouabain in the perfusion medium, increased the magnitude of the inotropic response and delayed or abolished the mechanical toxicity in a dose-dependent manner. No changes in the sarcolemmal Na+,K+-adenosine triphosphatase or ouabain binding were observed in the presence of verapamil or nifedipine. The data suggest that simultaneous use of verapamil or nifedipine may protect against digitalis-induced mechanical toxicity.     

The influence of ketamine on inotropic and chronotropic responsiveness of heart muscle.

The influence of ketamine on the inotropic and chronotropic responsiveness of heart muscle was examined in spontaneously beating right atrial preparations and in electrically driven left atrial preparations of guinea pigs. Ketamine (2.63 X 10(-5) to 4.2 X 10(-4) M) decreased heart rate of right atria and decreased contractile tension and its maximum rate of increase in both right and left atrial preparations (right atria greater than left atria). Ketamine did not prevent the heart rate increase produced by norepinephrine (NE; 1 X 10(-8) to 1 X 10(-4) M) in right atria; however, the maximum heart rate was consistently lower in ketamine-treated than in control muscles even after exposure to NE. Although contractile tension was decreased by ketamine, the maximum inotropic response to NE was consistently greater in ketamine-treated atria than in control atria. An inhibitor of the slow Ca++ current in heart muscle, D600, depressed the contractile effects of NE but did not prevent the positive inotropic interaction of ketamine and NE. Ketamine similarly enhanced the inotropic responses to norepinephrine (1 X 10(-6) M), epinephrine (1 X 10(-6) M), isoproterenol (1 X 10(-7) M) and dibutyryl cyclic adenosine 3':5'-monophosphate (AMP; 4 X 10(-3) M) in left atria electrically paced at a constant frequency of contraction of 1 Hz; however, ketamine inhibited the positive inotropic response to increased frequency of stimulation (0.1-3.0 Hz) and to ouabain (3 X 10(-7) M). These findings demonstrate that ketamine can exert a selective positive inotropic influence in heart muscle independent of heart rate or direct or reflexogenic autonomic nervous system changes, and suggest that this activity could in some way be associated with an alteration of the intracellular disposition of cyclic AMP.     

Reversal of caffeine-induced calcium overload in cardiac Purkinje fibers

In cardiac Purkinje fibers, caffeine initially increases and then decreases contractile force. The possible role of calcium overload in the negative inotropic effect of caffeine was studied in vitro under conditions that have been demonstrated to increase or decrease cellular calcium. The following results were obtained. Increasing [K]0 increased the initial positive and decreased the subsequent negative inotropic effect of 1 mM caffeine. At higher concentrations (2 and 4 mM), caffeine induced a larger negative inotropic effect which was reversed by high [K]0. Similarly, the positive inotropic effect was increased and the negative decreased by lowering [Ca]0. In high [Ca]0 or low [Na]0, caffeine had a predominantly negative inotropic effect which also was reversed by adding tetrodotoxin or by high [K]0. Reciprocally, in high [K]0, increasing [Ca]0 restored the negative inotropic effect of caffeine. During a brief exposure to zero [Ca]0, the force fell in the absence but less or not at all in the presence of caffeine. It is concluded that caffeine decreases contractile force in cardiac Purkinje fibers mostly by causing calcium overload.     

Negative chronotropic and positive inotropic actions of phencyclidine on isolated atrial muscle in guinea pigs and rats

Chronotropic and inotropic actions of phencyclidine were studied in spontaneously beating right atrial muscle and electrically paced left atrial muscle preparations isolated from guinea-pig or rat hearts. In right atrial muscle preparations, phencyclidine (10-100 microM) decreased the frequency of spontaneous beating. Guinea-pig and rat heart preparations had similar sensitivities to this action of phencyclidine. The negative chronotropic effect was not altered by atropine. A high concentration of naloxone failed to affect the chronotropic effect of phencyclidine in guinea-pig muscle, but significantly reduced the effect in rat heart muscle preparations. Phencyclidine (1-100 microM) caused positive inotropic effects in both guinea-pig and rat heart left atrial muscle electrically stimulated at 1.5 Hz; rat heart preparations had a higher sensitivity to the positive inotropic action of phencyclidine. The positive inotropic effect was reduced by verapamil, nifedipine and relatively high concentrations of diltiazem, but was not affected by propranolol, phentolamine, tripelennamine, atropine or ryanodine, indicating that the effect is not mediated by adrenergic, histaminergic or cholinergic systems or does not involve ryanodine-sensitive calcium pools. Inactivation of the fast sodium channels by partial membrane depolarization, and subsequent restoration of the contraction by raising the extracellular Ca++ concentration, did not abolish the positive inotropic action of phencyclidine. These results suggest that the negative chronotropic effect of phencyclidine is not mediated by a stimulation of the muscarinic receptor. The positive inotropic effects of phencyclidine seem to result from an increase in Ca++ influx through the slow channels of the cardiac cell membrane.     

Mechanism of inotropic action of xestoquinone, a novel cardiotonic agent isolated from a sea sponge.

Xestoquinone (XQN) isolated from the sea sponge Xestospongia sapra produced dose-dependent cardiotonic effects on guinea pig left and right atria. A direct action of XQN (1-30 microM) on the contractile machinery of cardiac myofilaments was demonstrated in chemically skinned fiber preparations from guinea pig papillary muscles. In atrial preparations, the XQN-induced inotropic effect was markedly inhibited by verapamil or nifedipine, but was not affected by practolol, chlorpheniramine, cimetidine, tetrodotoxin or reserpine. The Ca++ dependence curve for the contractile response of the atria was substantially shifted to the left by XQN (10 microM), and this XQN-induced shift was reversed by verapamil. The time-to-peak tension and relaxation times of the atrial contractions were shortened by XQN, and the action potential duration was markedly prolonged. Whole-cell patch clamp recordings in left atrial strips confirmed that XQN (30 microM) increased the slow inward current. However, there was a temporal dissociation between altered tension development and prolongation of the action potential duration. Cyclic AMP phosphodiesterase activity was inhibited and tissue cyclic AMP content of guinea pig left atria was increased by XQN (0.3-10 microM) in a concentration-dependent manner, but increases in cyclic AMP content did not occur in parallel with increases in contractile response. These observations suggest that an enhancement of intracellular cyclic AMP content and Ca++ influx across the cell membrane contribute to the late phase of XQN-caused cardiotonic responses, whereas the early phase may largely be elicited through direct activation of contractile elements. XQN may provide a novel leading compound for valuable cardiotonic agents.     

Effects of diacetyl monoxime on cardiac excitation-contraction coupling

Diacetyl monoxime (DAM) is a negative inotropic agent. To identify the mechanism of its actions, electrical and mechanical studies with various cardiac tissues were carried out. DAM (0.2-20 mM) inhibited the contractile force in both normal and 22 mM KCl-depolarized (in presence of 10(-6) M isoproterenol) guinea-pig papillary muscles in a concentration-dependent manner. In general, there was a lack of major effects of DAM on sarcolemmal electrical properties. The fast action potentials were somewhat depressed and the slow action potentials were slightly enhanced. In chemically skinned pig ventricular muscles, the myofibrillar contraction induced in 6.25 pCa was inhibited by DAM in a similar concentration range. DAM also produced an apparent decrease in sensitivity toward Ca++ in this preparation. Myofibrillar adenosine triphosphatase assay showed similar results as in the skinned muscles. All DAM effects were reversible upon washout and could be partially antagonized by raising [Ca++]. Taken together, the negative inotropic effect of DAM cannot be ascribed to an inhibitory effect on the slow inward current, as suggested previously. An inhibitory effect at the myofibril level is a distinct possibility. Additional effects of DAM on the sarcoplasmic reticulum cannot be ruled out.     

Pharmacological characterization of a new Ca(2+) sensitizer

The benzimidazole molecule was modified to synthesize a Ca(2+) sensitizer devoid of additional effects associated with Ca(2+) overload. Newly synthesized compounds, termed 1, 2, 3, 4, and 5, were evaluated in spontaneously beating and electrically driven atria from reserpine-treated guinea pigs. Compound 3 resulted as the most effective positive inotropic agent, and experiments were performed to study its mechanism of action. In spontaneously beating atria, the inotropic effect of 3 was concentration-dependent (3.0 microM-0.3 mM). Compound 3 was more potent and more active than the structurally related Ca(2+) sensitizers sulmazole and caffeine, but unlike them it did not increase the heart rate. In electrically driven atria, the inotropic activity of 3 was well preserved and it was not inhibited by propranolol, prazosin, ranitidine, pyrilamine, carbachol, adenosine deaminase, or ruthenium red. At high concentrations (0.1-1.0 mM) 3 inhibited phosphodiesterase-III, whereas it did not affect Na(+)/K(+)-ATPase, sarcolemmal Ca(2+)-ATPase, Na(+)/Ca(2+) exchange carrier, or sarcoplasmic reticulum Ca(2+) pump activities of guinea pig heart. In skinned fibers obtained from guinea pig papillary muscle and skeletal soleus muscle, compound 3 (0.1 mM, 1 mM) shifted the pCa/tension relation curve to the left, with no effect on maximal tension and no signs of toxicity. Compound 3 did not influence the basal or raised tone of guinea pig isolated aorta rings, whose cells do not contain the contractile protein troponin. The present results indicate that the inotropic effect of compound 3 seems to be primarily sustained by sensitization of the contractile proteins to Ca(2+).     

Negative inotropic effect of leukotrienes: leukotrienes C4 and D4 inhibit calcium-dependent contractile responses in potassium-depolarized guinea-pig myocardium

The effects of the sulfidopeptide leukotrienes (LTs) on the contractile response of electrically paced guinea-pig right ventricular papillary muscles in vitro were studied. LTs caused a concentration-dependent (1 nM-20 microM) negative inotropic effect; the order of relative potency was LTC4 greater than or equal to LTD4 greater than LTE4. A maximal 30% decrease in contractility occurred with 1 microM LTC4. The LT-induced decrease in contractile force was not mediated by cyclooxygenase products of the arachidonic acid cascade, as it was not influenced by indomethacin (14 microM). On the other hand, the slow-reacting substance-antagonist compound FPL 55712 (480 nM) caused a marked shift to the right of the LTC4 concentration-response curve. Because the negative inotropic effect of LTD4 was attenuated by increasing [Ca++]o, we next assessed the negative inotropic effect of LTs under conditions in which myocardial contractility depends solely on the slow inward Ca++ current. As a model, we used the isoproterenol- or histamine-induced restoration of contractile response in papillary muscles rendered inexcitable by 22 mMK+. LTC4 (16-480 nM) and LTD4 (20-600nM) inhibited isoproterenol- and histamine-induced restoration of contractility in a dose-dependent manner; a maximal 90% inhibition occurred with 0.48 microM LTC4. This effect of LTs was reversed by an elevation in [Ca++]o from 1.8 to 5.4 mM and prevented by FPL 55712 (480 nM). In muscles maintained at 5.4 mM [K+]o, LTC4 (160 and 480 nM) and LTD4 (1 microM) shifted the force-frequency curve (0.1-2 Hz) downwards in a parallel fashion; a similar alteration was obtained by lowering [Ca++]o to 1 mM.     

Stereoselective modulation of ryanodine-sensitive calcium channels by the delta isomer of hexachlorocyclohexane (delta-HCH).

delta-Hexachlorocyclohexane (delta-HCH) is shown to be 30-fold more potent as a positive inotropic agent with rat atrial strips compared with lindane (gamma-HCH). Threshold and ED50 values for enhanced contractile force at a pacing frequency of 0.5 Hz are less than 1 microM and 2.2 microM for delta-HCH and 40 microM and 63 microM for gamma-HCH, respectively. Contracture developed in atria exposed to greater than 4 microM delta-HCH (ED50 = 11 microM) but not in atria exposed to gamma-HCH. Uptake and release of Ca++ measured from actively loaded cardiac sarcoplasmic reticulum (SR) vesicles is measured with antipyrylazo III. Although delta-HCH (30 microM) decreases Ca(++)-dependent ATPase by 20%, it does not significantly alter Ca++ loading in the presence of ruthenium red. Addition of delta-HCH (5-50 microM) after loading is complete causes rapid, dose-dependent release of Ca++ from SR. Ca++ release induced by delta-HCH is markedly stereoselective. Compared with gamma-HCH (50 microM), delta-HCH (50 microM) induces a nearly 20-fold higher initial rate of Ca++ release (4.3 nmol of Ca++/mg/sec). Studies with [3H]ryanodine demonstrate that delta-HCH sharply inhibits Ca(++)- or daunorubicin-activated radioligand binding (IC50 = 37 and 25 microM, respectively, logit slope = 2). Inhibition of [3H]ryanodine-binding by delta-HCH is stereoselective inasmuch as IC50 values for alpha, beta and gamma isomers are greater than 100 microM. The delta-HCH modified Ca++ channel appears to proceed by a noncompetitive mechanism (reducing Bmax in equilibrium experiments) with respect to the conformationally sensitive binding site for [3H]ryanodine.(ABSTRACT TRUNCATED AT 250 WORDS)     

Increase in Ca++ sensitivity of the contractile system by MCI-154, a novel cardiotonic agent, in chemically skinned fibers from the guinea pig papillary muscles

The effects of MCI-154, a novel cardiotonic agent, on the contractile protein system and the sarcoplasmic reticulum (SR) were investigated by using thin bundles of chemically skinned fibers from the guinea pig papillary muscles. In the skinned muscle fibers treated with 50 micrograms/ml of saponin, MCI-154 shifted the -log[Ca++]M-tension relation curve to the left and upward in the concentration-dependent manner (10(-7) to 10(-4) M). This was confirmed also in the skinned muscle fibers treated with 250 micrograms/ml of saponin which destroyed not only the surface membrane but also the function of SR. Sulmazole (10(-4) M) shifted the -log[Ca++]M-tension relation curve to the left but the effect was about 100 times less potent than that of MCI-154. Unlike MCI-154, sulmazole had little effect on the maximum tension development induced by -log[Ca++]M 4.4. Milrinone did not affect the Ca++-induced tension development in the skinned cardiac fibers. Higher concentration of MCI-154 (10(-4) M) also increased amplitude of -log[Mg-ATP]M-tension-curve in the absence of free Ca++ ion (bell-shaped curve) to the upward. Initial rate and plateau phase of Ca++ uptake by the SR in the skinned fibers treated with 50 micrograms/ml of saponin was increased slightly by MCI-154 at the concentrations of 10(-6) and 10(-4) M. MCI-154 had no effect on the Ca++-induced Ca++ release mechanism in the SR. These results suggest that an increase in Ca++ sensitivity of the contractile protein system is responsible for, at least in part, the mechanism of the positive inotropic action of MCI-154.(ABSTRACT TRUNCATED AT 250 WORDS)     

Regional expression of sodium pump subunits isoforms and Na+-Ca++ exchanger in the human heart.

Cardiac glycosides exert a positive inotropic effect by inhibiting sodium pump (Na,K-ATPase) activity, decreasing the driving force for Na+-Ca++ exchange, and increasing cellular content and release of Ca++ during depolarization. Since the inotropic response will be a function of the level of expression of sodium pumps, which are alpha(beta) heterodimers, and of Na+-Ca++ exchangers, this study aimed to determine the regional pattern of expression of these transporters in the heart. Immunoblot assays of homogenate from atria, ventricles, and septa of 14 nonfailing human hearts established expression of Na,K-ATPase alpha1, alpha2, alpha3, beta1, and Na+-Ca++ exchangers in all regions. Na,K-ATPase beta2 expression is negligible, indicating that the human cardiac glycoside receptors are alpha1beta1, alpha2beta1, and alpha3beta1. alpha3, beta1, sodium pump activity, and Na+-Ca++ exchanger levels were 30-50% lower in atria compared to ventricles and/or septum; differences between ventricles and septum were insignificant. Functionally, the EC50 of the sodium channel activator BDF 9148 to increase force of contraction was lower in atria than ventricle muscle strips (0.36 vs. 1.54 microM). These results define the distribution of the cardiac glycoside receptor isoforms in the human heart and they demonstrate that atria have fewer sodium pumps, fewer Na+-Ca++ exchangers, and enhanced sensitivity to inotropic stimulation compared to ventricles.     

Negative inotropic effect of platelet-activating factor: association with a decrease in intracellular sodium activity

Platelet-activating factor (PAF) is an autacoid whose cardiovascular actions include a potent negative inotropic effect. The mechanism of this decrease in myocardial contractility is still at issue, as both a decrease and an increase in trans-sarcolemmal Ca++ influx have been reported. Because changes in intracellular sodium activity (aiNa) are known to influence myocardial contractility, we investigated whether PAF affects aiNa. Thus, we have measured contractile responses to PAF (1 nM-1 microM) in isolated guinea pig right ventricular papillary muscles paced at constant rate, and recorded transmembrane action potential and aiNa with conventional and sodium-selective microelectrodes, respectively. Our findings suggest that PAF does not affect slow inward Ca++ current, because PAF neither affected nor prevented histamine-induced restoration of contractile responses in K+-depolarized papillary muscles. On the other hand, we found the negative inotropic effect of PAF to be associated with a shortening of the action potential duration and with a decrease in aiNa. The specific PAF antagonist compound CV-3988 inhibited all three electro-mechanical responses. Our findings imply that the decrease in contractile force caused by PAF may depend on the reduction in aiNa; as aiNa falls, intracellular Ca++ may be lost via the Na+/Ca++ exchange and contractility decreases. The shortening of the action potential duration by PAF may reflect a decrease in Na+ influx and the consequent reduction in aiNa.     

Frequency modulation of the inotropic action of isoproterenol in mouse heart

In mouse right ventricular strips, field-stimulated to contract isometrically in an oxygenated bicarbonate-buffered physiological salt solution at 22--24 degrees C, the EC50 for the inotropic action of isoproterenol decreased from 37 nM in muscles stimulated at 0.2 Hz to 5 nM in muscles stimulated at 3.3 Hz. At higher rates of contraction, there was also an increased sensitivity to the inotropic actions of norepinephrine and epinephrine but not to those of Ca++ and N6,O2'-dibutyryl cyclic AMP. Increasing the Ca++ concentration further decreased the EC50 for isoproterenol at 3.3 Hz but had no effect on the EC50 at 0.2 Hz. The leftward shift of the contractile response curve at 3.3 Hz was inhibited by verapamil (0.6 microM) and Mn++ (0.25 mM). The stimulation of cyclic AMP accumulation was approximately 6-fold more sensitive to isoproterenol at 3.3 than at 0.2 Hz, but isoproterenol increased contractile force at concentrations two orders of magnitude lower than those that significantly increased cyclic AMP accumulation. Inhibition of cyclic AMP phosphodiesterase activity further increased the sensitivity to the inotropic actions of isoproterenol but did not attenuate the frequency difference. The results indicate that isoproterenol-stimulated Ca++ influx through the slow channel plays an important role in the mechanism of the increased sensitivity to the inotropic action of isoproterenol found at higher frequencies of contraction. Although cyclic AMP accumulation was also frequency dependent, its role in the inotropic action of isoproterenol in mouse heart is not clear.     

Differential effects of d- and l-pimobendan on cardiac myofilament calcium sensitivity

The effects is of the optical isomers of pimobendan (UD-CG 115 BS), an inotropic agent, were studied on the electrical and mechanical activity of intact and detergent-skinned preparations of cardiac muscle from guinea pig and dog. Racemic pimobendan has been shown to increase contractile force and to potentiate slow action potentials (AP) induced by stimulation of papillary muscle partially depolarized with 25 mM [K]o. These effects are shown in this study to be mainly due to the l-optical isomer of pimobendan. When slow APs were maximally stimulated by 1 microM isoproterenol, addition of either the d- or l-isomer of pimobendan did not affect the slow AP parameters. However, under these conditions, contractile force was significantly increased to 124% of control by the d-isomer and to 184% of control by the l-isomer. These results suggest that pimobendan may have direct effects on the myofilaments and that these effects are dependent on the optical isomer of the compound. To test this directly, the effects of d- and l-pimobendan were compared on Ca++-activated force developed by detergent-skinned heart muscle fibers. Submaximal force developed at constant Ca++ was increased by both optical isomers, but the l-isomer had a significantly greater Ca++-sensitizing effect. For example at pCa 6.75 force was 270% of control in the presence of the d-isomer and 400% of control in the presence of the l-isomer. At pCa 5, there was no effect of either isomer on force developed by the skinned fiber preparations.(ABSTRACT TRUNCATED AT 250 WORDS)     

Potent stimulation of myofilament force and adenosine triphosphatase activity of canine cardiac muscle through a direct enhancement of troponin C Ca++ binding by MCI-154, a novel cardiotonic agent

In the present study we have analyzed a likely biochemical mechanism underlying the Ca++-sensitizing action of MCI-154 (6-[4-(4'-pyridyl)aminophenyl)-4,5-dihydro-3(2H)-pyridazinone hydrochloride), a novel cardiotonic agent, on the contractile protein system. MCI-154 (10(-7) to 10(-4) M) enhanced the tension development induced by -log molar-free Ca++ concentration (pCa) 5.8 in chemically skinned fiber from the canine right ventricular muscle in a concentration-dependent manner. At pCa 7.0, MCI-154 (10(-7) to 10(-4) M) markedly increased adenosine triphosphatase (ATPase) activities of canine myofibrils and reconstituted actomyosin. In myofibrils and reconstituted actomyosin, MCI-154 (10(-7) to 10(-4) M) caused a parallel shift of the pCa-ATPase activity relation curve to the left without affecting the maximum activity, suggesting an increase in Ca++ sensitivity. MCI-154 (10(-8) to 10(-4) M) had little effect on actin-activated, Mg++, Ca++ and (K+, EDTA)-ATPase activities of myosin. Ca++ binding to cardiac myofibrils or purified cardiac troponin was increased by 10(-4) M MCI-154. These results suggest that MCI-154 enhances Ca++ binding to cardiac troponin C to elevate the Ca++ sensitivity of myofilaments and thus may cause a positive inotropic action in cardiac muscle. MCI-154 may provide a valuable tool for studying the molecular mechanism by which Ca++ regulates the contractile system.     

A polypeptide (AP-A) from sea anemone (Anthopleura xanthogrammica) with potent positive inotropic action.

Anthopleurin-A (AP-A), a polypeptide with MW ca. 5500 (53 amino acids), isolated from the sea anemone, Anthopleura xanthogrammica (Brandt), elicited a potent positive inotropic effect but without an accompanying chronotropic effect on the isolated cardiac muscles of rat, rabbit, guinea pig and cat. Similarly in dogs and cats in situ, i.p. injections of AP-A increased the contractile force without effect on heart rate or blood pressure. The cardiotonic potency for AP-A was equivalent to that of isoproterenol but much greater than that for ouabain or glucagon on the isolated cardiac muscle. AP-A increased the contractile force (cardiac output) and decreased atrial pressure in dog heart during pentobarbital-induced failure. This inotropic effect was not inhibited by propranolol pretreatment. The Ca++ requirement to restore the contractile force was less in AP-A-treated than in ouabain or isoproterenol-treated tissues. After AP-A treatment, the cardiac contractility was more resistant to hypoxia and to low or high temperature stress than ouabain-treated or control preparations. AP-A at 5 10(-9) M increased the duration of the action potential, its mean rate of rise and conduction in the guinea-pig atria and ventricles. At the maximum effective concentration, AP-A did not inhibit Na+, K+-activated adenosine triphosphatase, phosphodiesterase (high Km and low Km) and cyclic 3',5'-adenosine monophosphate content of guinea-pig heart. AP-A (5 X 10(-8) to 5 X 10(-7) M) neither contracted nor relaxed the isolated vascular smooth muscle. The results suggest that AP-A may be useful in the clinical management of cardiac failure and as an experimental tool to study the pharmacology and physiology of cardiac muscle.