Studies on mechanism of inhibition of cardiac muscle contractile tension by ryanodine. Mechanical response

Expression of calsequestrin in atrial and ventricular muscle of thermally acclimated rainbow trout

Calsequestrin (CASQ) is the main Ca(2+) binding protein within the sarcoplasmic reticulum (SR) of the vertebrate heart. The contribution of SR Ca(2+) stores to contractile activation is larger in atrial than ventricular muscle, and in ectothermic fish hearts acclimation to low temperatures increases the use of SR Ca(2+) in excitation-contraction coupling. The hypotheses that chamber-specific and temperature-induced differences in SR function are due to the increased SR CASQ content were tested in rainbow trout (Oncorhynchus mykiss) acclimated at either 4 degrees C (cold acclimation, CA) or 18 degrees C (warm acclimation, WA). To this end, the trout cardiac CASQ (omCASQ2) was cloned and sequenced. The omCASQ2 consists of 1275 nucleotides encoding a predicted protein of 425 amino acids (54 kDa in molecular mass, MM) with a high (75-87%) sequence similarity to other vertebrate cardiac CASQs. The transcript levels of the omCASQ2 were 1.5-2 times higher in CA than WA fish and about 2.5 times higher in the atrium than ventricle (P<0.001). The omCASQ2 protein was measured from western blots using a polyclonal antibody against the amino acid sequence 174-315 of the omCASQ2. Unlike the omCASQ2 transcripts, no differences were found in the abundance of the omCASQ2 protein between CA and WA fish, nor between the atrium and ventricle (P>0.05). However, a prominent qualitative difference appeared between the acclimation groups: two CASQ isoforms with apparent MMs of 54 and 59 kDa, respectively, were present in atrial and ventricular muscle of the WA trout whereas only the 54 kDa protein was clearly expressed in the CA heart. The 59 kDA isoform was a minor CASQ component representing 22% and 13% of the total CASQ proteins in the atrium and ventricle of the WA fish, respectively. In CA hearts, the 59 kDa protein was present in trace amounts (1.5-2.4%). Collectively, these findings indicate that temperature-related and chamber-specific differences in trout cardiac SR function are not related to the abundance of luminal Ca(2+) buffering by cardiac CASQ.

Minor constituents of Spigelia anthelmia and their cardiac activities

A more detailed phytochemical analysis of extracts of the aerial parts of Spigelia anthelmia L. (Loganiaceae) yielded 20 structurally related new compounds besides spiganthine and ryanodine. Structure elucidation was achieved mainly by spectroscopic methods. The compounds were tested on their cardiac and on their insect antifeedant activities.

Tetracaine can inhibit contractions initiated by a voltage-sensitive release mechanism in guinea-pig ventricular myocytes

1. Effects of tetracaine on membrane currents and cell shortening were measured with high resistance electrodes, single-electrode voltage clamp (switch clamp) and a video edge detector at 37 C in cardiac ventricular myocytes. 2. Sequential voltage steps from -65 mV to -40 and 0 mV were used to activate two mechanisms of excitation-contraction (EC) coupling separately. The step to -40 mV activated the voltage-sensitive release mechanism (VSRM); the step to 0 mV1 activated Ca2+-induced Ca2+ release (CICR) coupled to inward Ca2+ current (IL). 3. Exposure to 100-300 microM tetracaine inhibited VSRM contractions but not CICR contractions. Inhibition of VSRM contractions was independent of INa blockade. In contrast, 100 microM Cd2+ blocked IL and CICR contractions, but not VSRM contractions. Simultaneous application of both agents blocked both mechanisms of EC coupling. 4. Contraction-voltage relationships were sigmoidal when the VSRM was available. However, when the VSRM was inhibited with 100-300 microM tetracaine, contraction-voltage relationships became bell-shaped. The tetracaine-insensitive contractions were abolished by 0.1 microM ryanodine, indicating that they were dependent on release of SR Ca2+. 5. At a higher concentration (1 mM) tetracaine also inhibited IL and contractions triggered by IL; however, the time course of effects on IL and associated contractions were different than for VSRM contractions. 6. With continuous application of tetracaine, the VSRM remained inhibited although SR Ca2+ stores increased 4-fold as assessed with caffeine. CICR contractions were not inhibited and maximum amplitude of contraction was not reduced. 7. Rapid application of tetracaine just before and during test steps also inhibited VSRM contractions, but without significantly affecting sarcoplasmic reticulum (SR) Ca2+ stores or CICR contractions. Maximum amplitude of contraction was reduced. 8. Rapid application of tetracaine (100-300 microM) allows preferential inhibition of the VSRM and provides a pharmacological method to assess the contribution of the VSRM to EC coupling.

Role of sarcoplasmic reticulum in myocardial contraction of neonatal and adult mice

Changes in action potential parameters by and inotropic responses to nicardipine, verapamil, ryanodine and cyclopiazonic acid were examined in isolated ventricular myocardial preparations from neonatal and adult mice. The action potential of both neonatal and adult mice had a unique configuration with little evidence of a plateau at depolarized membrane potential; the action potential duration was significantly larger in neonatal preparations. Nicardipine had no effect on action potential parameters in the adult while it significantly shortened the action potential duration at 50% repolarization in the neonate. Ryanodine significantly shortened the action potential duration at 80% repolarization at both ages: the shortening was significantly larger in the adult when compared with the neonate. The contraction of ventricular preparations from adult mice were relatively resistant to nicardipine and verapamil. Nicardipine or verapamil, even at 10(-5) M, only decreased the contractile force to 70% of control values; the decrease was much less than that reported in other experimental species such as chick, guinea pig or rabbit. In the neonate, 10(-5) M nicardipine or verapamil decreased the contractile force to 30% of control values. Ryanodine had a potent negative inotropic effect both in the neonate and adult; the effect was significantly larger in the adult. Cyclopiazonic acid produced a decrease in contractile force and prolongation of the time required for relaxation; both effects were significantly larger in the adult. These results suggest that the contraction of the adult mouse myocardium is highly dependent on SR function and less dependent on transsarcolemmal Ca2+ influx when compared with the myocardium of the neonatal mouse and that of other species.

The heart and development

The perspective from which the developing heart is viewed can lead to differing conclusions about the effects of development on cardiac function. The hearts of the embryo, fetus and adult, viewed from a global perspective, sustain the circulation through the same basic mechanisms of developing pressure and ejecting blood. The failure of the embryonic heart to perform these tasks results in growth failure, edema, and embryonic death, just as in the infant and adult such failure results in premature death. Furthermore, from the viewpoint of gross anatomy, following embryonic morphogenesis, the developing and adult hearts appear in general to be structurally similar, differing only in size and mass. However, a closer view shows, in the molecular and structural makeup of the myocardium, richly complex changes that can modulate the basic physiological properties of the cardiac myocyte. This article focuses on how these changes and the effects of birth and development alter ventricular function.

Myocardial action potential prolongation by calcium channel activation under calcium free-EGTA condition in rats: developmental and regional variations

1. Prolongation of action potentials upon the addition of isoproterenol, forskolin, isobutylmethyl-xanthine (IBMX) and dibutyril cAMP (dbcAMP) under Ca-free EGTA condition was examined in isolated myocardial preparations from neonatal and adult rats, whose action potential configuration greatly differ. 2. The prolongation of the action potential was previously suggested to be produced by persistent sodium influx through calcium channel due to the lack of calcium-mediated inactivation of calcium channels under such experimental condition. 3. Preparations used were papillary muscles and free walls of the right and left ventricles from neonatal and adult rats. 4. In adult preparations, the prolongation produced by isoproterenol, forskolin and IBMX in the right free wall was smaller than those in the other three regions, while no regional difference was observed with dbcAMP. 5. The degree of prolongation by all of the four drugs were smaller in the neonate than in the adult. No regional difference was observed with any of the drugs in the neonate. 6. Our present results suggest that contribution of calcium-mediated inactivation of calcium channels to the repolarization of rat myocardium may increase postnatally to produce the developmental shortening of its action potential. Also, regional difference in the cAMP related mechanisms may appear postnatally.

Inotropic effects of ryanodine and nicardipine on fetal, neonatal and adult guinea-pig myocardium

The effects of extracellular Ca2+ and inotropic agents on contractile force were examined in left atrial and right ventricular myocardia isolated from fetal (35-55 days after conception), neonatal (0-5 days after birth) and adult (30-90 days after birth) guinea-pigs. In both atrial and ventricular muscles, the contractile force increased with increasing extracellular calcium concentration ([Ca2+]o) and the sensitivity to [Ca2+]o was higher in the fetus than in the neonate and adult. Nicardipine almost abolished the contractile force in all groups examined. The sensitivity to nicardipine was similar among the three age groups and also between the two tissues. Ryanodine almost abolished the contractile force in atrial muscles from all age groups. In ventricular muscles it partially reduced the contractile force to the same extent in the neonate and adult while it slightly increased the contractile force in the fetus. In both atrial and ventricular muscles, isoproterenol shortened the relaxation time to the same extent in the neonate and adult, but little or not in the fetus. Taken together, our present results suggest that the sarcoplasmic reticulum function in regulating myocardial contraction is less developed in the fetal guinea-pig when compared with the neonate and adult, and that the atrial contraction is more dependent on Ca2+ release from the sarcoplasmic reticulum than the ventricular contraction is. Thus, it appears that the development of contractile function of the guinea-pig myocardium is mostly completed by birth.

Structural determinants of high-affinity binding of ryanoids to the vertebrate skeletal muscle ryanodine receptor: a comparative molecular field analysis

Ryanodine binds to specific membrane proteins, altering the calcium permeability of intracellular membranes. In this study 19 ryanoids were isolated or synthesized and the structures correlated to the strength of binding to vertebrate skeletal muscle ryanodine receptors. Global minima were determined by employment of molecular mechanics and dynamics augmented by systematic searching of conformational space. Overall, steric and electrostatic factors contribute about equally to the differences in the experimentally determined dissociation constants. The dominant electrostatic interaction is localized to a hydroxyl group in an apolar region of the molecule. The pyrrole and isopropyl groups located together at one pole of the molecule have the greatest effect on steric interactions between ligand and receptor. We suggest ryanodine binds to the receptor with the pyrrole and isopropyl groups buried deep inside a cleft in the protein. This arrangement places special importance on the conformation of the pyrrole and isopropyl groups. In contrast, the opposite pole appears to be positioned at the entrance of the binding pocket because bulky adducts placed in the 9 position of ryanodine alter binding minimally. For example, a fluorescent ryanodine adduct was synthesized which has a dissociation constant close to that of ryanodine. Detailed examination reveals subtle interactions between ryanoid and receptor. In many cases, the major factors altering the strength of binding were found to be conformational alterations in the molecule remote from the site of covalent modification.

Myocardial action potential prolongation by calcium channel activation under calcium-free EGTA condition in guinea pigs and rats

1. Prolongation of action potentials upon the addition of isoproterenol or dbcAMP under Ca-free EGTA condition were observed in isolated myocardial preparations from both the guinea pig and the rat, whose action potential configuration greatly differ. The degree of prolongation was greater in the rat than in the guinea pig. 2. The prolongation of the action potential was rapidly reversed upon the addition of calcium ion and was dose-dependently suppressed by the addition of calcium antagonists. The sensitivity to nicardipine of this action potential was tenfold higher than of the so-called slow response action potentials. The duration of the prolonged action potential was dependent on the external sodium concentration, but was not affected by tetrodotoxin. 3. Thus, it was demonstrated in intact myocardia that sodium ion may persistently pass through the calcium channel to prolong the action potential when it is activated under the condition where the calcium-mediated inactivation of calcium channels is removed. 4. Contribution of calcium-mediated inactivation of calcium channels to the repolarization of normal myocardium may be larger in the rat than in the guinea pig.

Modulation of sarcoplasmic reticulum Ca(2+)-release channels by caffeine, Ca2+, and Mg2+ in skinned myocardial fibers of fetal and adult rats

Ryanodine causes depression of the caffeine-induced tension transient (ryanodine depression) in skinned muscle fibers, because it blocks the sarcoplasmic reticulum (SR) Ca(2+)-release channels [Su, J. Y. (1988) Pflügers Arch 411:132-136, 371-377; (1992) Pflügers Arch 421:1-6]. This study was performed to examine the sensitivity of SR Ca(2+)-release channels to ryanodine in fetal compared to adult myocardium and to investigate the influence of Ca2+, caffeine, and Mg2+ on ryanodine depression in skinned fibers. Ryanodine (0.3 nM-1 microM) caused a dose-dependent depression in skinned myocardial fibers of the rat, and the fetal fibers (IC50 approximately 74 nM) were 26-fold less sensitive than those of the adult (IC50 approximately 2.9 nM). The depression induced by 0.1 microM or 1 microM ryanodine was a function of [caffeine], or [Ca2+] (pCa < 6.0), which was potentiated by caffeine, and an inverse function of [Mg2+]. At pCa > 8.0 plus 25 mM caffeine, a 20% ryanodine depression was observed in both the fetal and adult fibers, indicating independence from Ca2+. Ryanodine depression in skinned fibers of the fetus was less affected than that seen in the adult by pCai, [caffeine]i, or 25 mM caffeine plus pCai or plus pMgi (IC50 approximately pCa 4.5 versus 5.1; caffeine 12.7 mM versus 2 mM; pCa 6.7 versus 7.3; and pMg 3.9 versus 3.3 respectively). The results show that the SR Ca(2+)-release channel in both fetal and adult myocardium is modulated by Ca2+, caffeine, and Mg2+.(ABSTRACT TRUNCATED AT 250 WORDS)

Lack of effect on the sodium efflux of the microinjection of D-Ins(1,4,5)P3 into ouabain-poisoned barnacle muscle-fibers

A study has been carried out using relatively intact mature muscle fibers from the barnacle Balanus nubilus to see whether D-Ins(1,4,5)P3 stimulates the ouabain-insensitive Na efflux following its microinjection and whether this is accompanied by a contraction of the fiber. Part of the impetus for a study of this type came from the on-going debate between Vergara, Rojas and co-workers and Lea and co-workers, the former group holding the view that skinned barnacle fibers and skeletal fibers in general are responsive to this isomer. The evidence brought forward indicates that the injection of D-Ins(1,4,5)P3 in concentrations in the range of 10(-2) M to 10(-6) M into cannulated unskinned fibers pretreated with ouabain fails to increase the residual efflux, and additionally fails to elicit a contraction. A similar picture emerges with the use of non-hydrolyzable DL-Ins(1,4,5)P3[S]3, analog following its injection in a concentration of 0.5 microM. Higher concentrations of the analog were unavailable for use. This work also involved verification of the idea that an effect might be obtainable in depolarized fibers. However, doubling or tripling K0+ and injection of the isomer or the analog simultaneously failed to support this idea. Since nothing is known as to whether D-Ins(1,4,5)P3 influences the behavior of the Na(+)-Ca2+ exchanger when operating in the reverse mode, experiments were done to check this possibility. ATPNa2 which is though to activate Na(+)-Ca2+ exchange was injected prior to the isomer or the analog but no significant results were obtained. A similar line of reasoning was followed, that of activating the L-type Ca2+ channel by injecting GTPNa2 which in addition is known to activate adenylate cyclase. Again, neither the isomer nor the analog were effective. Thus, the only conclusion possible is that in relatively intact, mature barnacle fibers there is no coupling between the phosphoinositide signalling pathway and two other key systems, viz. the Na(+)-Ca2+ exchanger when operating in the reverse mode and the L-type Ca2+ channel. Equally clear is that for some unknown reason the ouabain-insensitive Na efflux and the contractile apparatus are insensitive to D-Ins(1,4,5)P3[S]3.

Developmental changes in cardiac myocyte calcium regulation

Developmental changes in the contributions of transsarcolemmal Ca2+ influx and Ca2+ release from intracellular storage sites to myocardial contraction were evaluated in isolated ventricular myocytes from neonatal (aged 1-7 days) and adult (aged 8-10 weeks) New Zealand White rabbits. Contractions ceased in one beat when extracellular Ca2+ was decreased from 1mM to micromolar levels using a rapid perfusion technique. On reperfusion with 1 mM Ca2+, recovery of control contraction amplitude occurred after significantly fewer beats in neonatal myocytes compared with adult myocytes, and after 1 minute compared with 5 minutes of reduced Ca2+. After 15 minutes of perfusion with either 1 or 10 microM ryanodine, contraction amplitude decreased in both age groups, but the decrease was significantly greater in adults than in neonates. These experiments indicate that isolated ventricular myocytes may be used in the study of developmental changes in intracellular Ca2+ regulation. Results suggest that cardiac contraction in neonates is relatively more dependent on transsarcolemmal Ca2+ influx. Furthermore, although Ca2+ release from intracellular storage sites is present in both neonates and adults, its role in cardiac contraction is more significant in adults.

Tension activation and relaxation in frog atrial fibres. Evidence for direct effects of divalent cations (Ca2+, Sr2+, Ba2+) on contractile proteins and Na-Ca exchange

The effect of alkali-earth cations (Ca2+, Sr2+, Ba2+) on the excitation-contraction coupling events of the frog atrial fibres were studied using a double mannitol gap voltage clamp technique coupled with a mechano-electric transducer. Photoremoval of the suppressive effect of nifedipine on the calcium channels allowed to obtain rapid transient Ca2+, Sr2+ or Ba2+ ions current jumps. The effect on the amplitude of the associated contraction was proportional to the current jumps. These results together with the correlation established between the estimated increase in the internal concentration of divalent cations and the amplitude of the phasic tension suggest that the essential source of divalent cations for activation of contraction is the extracellular space. Also Ba2+ ions reduced the tonic tension and strongly slowed the relaxation of the phasic component whereas Sr2+ exhibited smaller effects. Sr2+ ions could be more efficient than Ba2+ ions in substituting for Ca2+ ions in the Na+-Ca2+ exchange mechanism known to regulate these two mechanical events. The conclusions are that the order of effectiveness of these ions (Ca2+ greater than Sr2+ greater than Ba2+) is the same with regard to transarcolemmal exchange for Na+ ions, presumed uptake by a "second relaxing system", activation of contraction, and inactivation of the slow inward current.

Evidence for the presence of calsequestrin in both peripheral and interior regions of sheep Purkinje fibers

Localization of calsequestrin in sheep Purkinje fibers was determined by indirect immunofluorescence labeling of cryostat sections of sheep myocardium from the intraventricular wall. The results presented show that calsequestrin is present in discrete foci at the peripheral, as well as the interior regions of the cytoplasm. Since Purkinje fibers lack transverse tubules, the presence of calsequestrin at specific foci in the interior regions of the cytoplasm in these cells suggests that calsequestrin is localized in the lumen of peripheral junctional sarcoplasmic reticulum, as well as in the lumen of corbular sarcoplasmic reticulum present in the I band region of the myofibrils. Assuming that the function of calsequestrin is to sequester calcium into the lumen of the sarcoplasmic reticulum, these results imply that two structurally different regions of the sarcoplasmic reticulum function as calcium storage sites in mammalian Purkinje fibers and raises the possibility that calcium storage and/or release from these two sites might be regulated differently.

Mechanism of biphasic contractions in strontium-treated ventricular muscle

Biphasic contractions were produced in dog trabeculae by replacing 90-95% of the calcium in the bathing solution with strontium. These conditions produced prolonged action potentials accompanied by contractions with two distinct phasic components. The early component disappeared slowly when the remaining Ca++ was removed, whereas the late component was eliminated quickly when Sr++ was removed. Manganese ion (0.25 mM) preferentially decreased the late component without changing the action potential, whereas caffeine and ryanodine decreased or eliminated the early component. Ryanodine did not alter the action potential. Isoproterenol rapidly increased the early component and, more slowly and to a lesser degree, increased the late component. The results suggest that the early component is caused by intracellular release of activator cation, probably from the sarcoplasmic reticulum, whereas the late component is the result of Sr++ entry across the sarcolemma, possibly by way of the slow inward current.

The role of the sarcoplasmic reticulum in the pure frequency potentiation: the effect of ryanodine

The dependence of the contraction amplitude of the isolated papillary muscle of the guinea pig on the stimulation pattern is probably caused by a well working sarcoplasmic reticulum. This view is supported by the finding that the alkaloid ryanodine flattens the curve of the force-frequency relationship and abolishes the pure frequency potentiation. Ryanodine is said to destroy exclusively the connection between T-tubulus and sarcoplasmic reticulum.

Effect of ryanodine on myocardial calcium

The effects of ryanodine and ryanodine steady-state condition (RSSC) on contractile-related calcium were examined in isolated guinea pig left atrial muscle. 1. RSSC is a specific irreversible condition occurring after a brief exposure to 1 x 10(-7) M ryanodine, followed by washing. It is characterized by elimination of the contraction following a 10-sec rest interval (post-rest) and prolongation of the associated action potential duration (AP50%) from 78.9 to 160.8 msec with minimal alteration in steady-state tension development determined at 1 Hz. 2. Induction of RSSC with a ryanodine-bovine serum albumin conjugate produced similar alterations in post-rest contractile strength and action potential duration. 3. In the presence of 1 x 10(-7) M ryanodine, guinea pig left atria exhibit a significant increase in total 45Ca efflux from two rapidly exchangeable compartments (compartment 1, t1/2=1.58 min; compartment 2, t1/2=8.20 min). 4. In atria loaded after the induction of RSSC, total 45Ca release was significantly reduced by 7.2% of the total exchange. 5. The 45Ca exchange space for RSSC atria was reduced from 23.22 +/- 0.81 to 19.85 +/- 1.22 ml per 100 g muscle without a significant reduction in the total exchange space. 6. From these results, it is concluded that the effects of low concentrations of ryanodine and RSSC are to alter the contractile calcium levels of the tissue, primarily from sarcolemmal membrane sites which regulate post-rest contractile strength and action potential duration.