ryanodine and diacetylmonoxime

The constitutive law of the material comprising any structure is essential for mechanical analysis since this law enables calculation of the stresses from the deformations and vice versa. To date, there is no constitutive law for actively contracting myocardial tissue. Using 2,3-butanedione monoxime to protect the myocardium from mechanical trauma, we subjected thin midwall slices of rabbit myocardium to multiaxial stretching first in the passive state and then during steady-state barium contracture or during tetani in ryanodine-loaded tissue. Assuming transverse isotropy in both the passive and active conditions, we used our previously described methods (Humphrey et al., 1990a) to obtain both passive and active constitutive laws. The major results of this study are: (1) This is the first multiaxial constitutive law for actively contracting mammalian myocardium. (2) The functional forms of the constitutive law for barium contracture and ryanodine-induced tetani are the same but differ from those in the passive state. Hence, one cannot simply substitute differing values for the coefficients of the passive law to describe the active tissue properties. (3) There are significant stresses developed in the cross-fiber direction (more than 40 percent of those in the fiber direction) that cannot be attributed to either deformation effects or nonparallel muscle fibers. These results provide the foundation for future mechanical analyses of the heart.

Topics: Animals; Anisotropy; Barium; Diacetyl; Female; Male; Models, Cardiovascular; Myocardial Contraction; Numerical Analysis, Computer-Assisted; Rabbits; Reproducibility of Results; Ryanodine; Signal Processing, Computer-Assisted; Stress, Mechanical; Tetany; Ventricular Function, Left

The heat produced by toad ventricle during manipulations of the inotropic state was measured using thermopiles, and some comparisons made to rat ventricle. The tension-independent heat, peak stress, and the tension-dependent heat increased when [Ca2+]o increased from 0.25 to 2 mM in Ringer. In 2 mM [Ca2+]o, tension-independent heat, peak stress, and tension-dependent heat were 3.1 +/- 0.4 mJ/g, 38.4 +/- 5.5 mN/mm2, and 0.49 +/- 0.06 units; about 25% of the tension-independent heat may relate to the Na(+)-K+ pump. At similar [Ca2+]o, rat ventricle produced a smaller tension-independent heat (1.6 +/- 0.2 mJ/g), and active heat per unit stress (0.22 +/- 0.01 units) than toad. Tension-independent heat, stress, and tension-dependent heat were increased by orciprenaline, and decreased by BDM. Ouabain increased the stress and tension-dependent heat but not the tension-independent heat. Five millimolar [Ca2+]o in HEPES buffer decreased the stress but increased the tension-dependent heat compared to 2 mM [Ca2+]o in Ringer. Ryanodine and CPA caused major reductions in force and tension-independent heat in rat, but had little effect on toad ventricle. In conclusion, our results suggest that in toad ventricle (a) the sarcoplasmic reticulum plays only a minor role in activation and relaxation, (b) the Na(+)-K+ pump contributes substantially to activation metabolism, (c) active metabolism is stimulated by increases in [Ca2+]o and (d) there is a larger tension-independent heat, a larger active metabolism per unit stress, and a lower basal metabolism than in rat papillary muscle. The energy cost of removing intracellular Ca2+ through the sarcolemma appears to be greater than uptake into sarcoplasmic reticulum.

Topics: Animals; Biological Transport; Buffers; Bufo marinus; Calcium; Diacetyl; Energy Metabolism; Hot Temperature; Magnesium; Male; Metaproterenol; Myocardial Contraction; Myocardium; Ouabain; Papillary Muscles; Rats; Rats, Sprague-Dawley; Ryanodine; Sarcoplasmic Reticulum; Sodium-Potassium-Exchanging ATPase; Species Specificity; Stress, Mechanical

1. We investigated the mechanism of force inhibition by 2,3-butanedione monoxime (BDM) on rat cardiac trabeculae. [Ca2+]i was measured by iontophoretic injection of fura-2 salt. Isometric force was recorded at an end-systolic sarcomere length of 2.1-2.2 microns. 2. With an external [Ca2+] of 1 mM, peak twitch force was monotonically reduced with increasing [BMD]; at 5 and 20 mM [BDM], force was 35 and 1% of the control force. In contrast, the mean peak [Ca2+]i during transients was only reduced at [BDM] > or = 10 mM. 3. The duration of the twitch was dramatically reduced by BDM in a dose-dependent fashion with no significant change in the time course of the underlying Ca2+ transients. The abbreviation of twitch force duration was much greater than expected for the observed reduction in peak force by this agent. 4. The mechanism of the inhibition of force by BDM was explored by examining the relationship between twitch force and Ca2+ transients at various values of external [Ca2+]. In the presence of BDM, the steepness of the relationship between peak force and peak [Ca2+]i was reduced compared to control conditions. As a result, significant elevation in the [Ca2+]i transient was unable to reverse the reduction in force observed in the presence of BDM. 5. The direct inhibitory effects of BDM on the contractile system were examined using ryanodine tetani in intact trabeculae to measure the steady-state force-[Ca2+]i relationship. In contrast to the effects on twitch force at 5 mM BDM, maximal force was only reduced to 71% of control. Furthermore, the [Ca2+]i required for half-maximal activation (Ca50) was increased while the Hill coefficient was reduced slightly by BDM. 6. BDM dramatically slowed the rate of rise of tetanic force. At maximal activation, the time required to reach 90% maximal force was prolonged by a factor of 3-8 in the presence of 5 mM BDM. This suggests that the observed reduction in twitch force and steady-state force may result from slowed kinetics of cross-bridge attachment, consistent with recent biochemical studies. 7. The contribution of altered cross-bridge kinetics to the effects of BDM was investigated using a co-operative cross-bridge model of the contractile system. Changing the rate constants for cross-bridge attachment in the model to mimic the reported biochemical effects of BDM reproduced the observed effects of BDM.(ABSTRACT TRUNCATED AT 400 WORDS)

Topics: Animals; Calcium; Depression, Chemical; Diacetyl; Female; Fluorescent Dyes; Fura-2; Heart; In Vitro Techniques; Isometric Contraction; Kinetics; Male; Models, Biological; Myocardial Contraction; Rats; Ryanodine; Sarcomeres

Cardiac contraction causes a decrease in coronary flow. Despite many studies, it is still not clear what mechanism or mechanisms are responsible for this flow decrease. The phasic nature of myocardial contraction and the complexities intrinsic to intact heart preparations make it difficult to elucidate the mechanisms. We therefore studied coronary pressure-flow relationships during steady-state (tetanic) contractions in the maximally vasodilated isolated canine interventricular septum to see whether waterfall-type behavior is present. Using ryanodine and electrical stimulation allowed the production of reproducible and reversible tetani. This preparation minimizes the difficulties associated with transmural variations and also the effects of intramyocardial capacitance. Two separate protocols were performed to delineate the pressure-flow relationships in the passive and tetanized states. The first compared diastolic and tetanized pressure-flow relationships. In the second protocol, 2,3-butanedione monoxime was added to obtain an intermediate contractile level, thus allowing the comparison of two contractile states. Both the diastolic and tetanized pressure-flow relationships were curvilinear in the low-pressure range. Linear and nonlinear fits to the data showed that the primary effect of contraction was a shift of the pressure-flow relationships to higher pressures at a given flow. This effect was graded by the level of contractility and was independent of developed stress. Although other mechanisms may also be operative, these results support the presence of waterfall behavior in the coronary vascular bed.

Topics: Animals; Blood Pressure; Coronary Circulation; Diacetyl; Diastole; Dogs; Electric Stimulation; Female; Heart Septum; Heart Ventricles; In Vitro Techniques; Male; Microscopy, Electron; Myocardial Contraction; Myocardial Stunning; Ryanodine

1. To study the effects of mechanical constraints on the calcium (Ca2+) affinity of cardiac troponin C, we analysed the tension and aequorin light (AL, intracellular Ca2+) transients in response to a step length change in aequorin-injected ferret right ventricular papillary muscles. The muscle preparations were continuously activated with ouabain (10(-4) M) (ouabain contracture) or with high frequency stimuli in the presence of ryanodine (5 microM) (tetanic contraction). 2. The tension transient in response to either the release or stretch was oscillatory: tension decreased rapidly during the release and then increased, after which it lapsed into a new steady level in a series of damped oscillations. The opposite was true for the stretch. The oscillatory responses were conspicuous and less damped in ouabain-activated preparations (oscillation frequency of 2.2-2.3 Hz at 22 degrees and 4.5-4.6 Hz at 30 degrees C) and much more damped in ryanodine-treated preparations. 3. The transient AL response was also oscillatory, the time course of which corresponded to that of the transient tension response. Regardless of the difference in the time course of the transients in two different preparations and at two different temperatures, the increase in AL corresponded to the decrease in tension, likewise the decrease in AL to the increase in tension. 4. The mean level of AL after release was lower than the control level present just prior to the release in ouabain-activated preparations, but the AL after release finally returned to the nearly control level in ryanodine-treated preparations. 5. When the ryanodine-treated muscle was further treated with 2,3-butanedione monoxime (BDM) (20 mM), the tetanic tension decreased remarkably without affecting the AL signal. The tension transient of this preparation was quite similar to that of the resting muscle, which changed in a nearly stepwise fashion; AL was hardly affected by step length changes, as in the resting muscle, in spite of the higher AL level. 6. These results suggest that the Ca2+ affinity of cardiac troponin C is increased with an increase in tension (i.e. the cross-bridge attachment) and decreased with a decrease in tension i.e. the cross-bridge detachment), and that the mean [Ca2+]i is lowered by release, at least in a Ca(2+)-overloaded condition, mainly through the sarcoplasmic reticulum.

Topics: Aequorin; Animals; Calcium; Cholinesterase Reactivators; Diacetyl; Electric Stimulation; Ferrets; Heart; In Vitro Techniques; Male; Myocardial Contraction; Myocardium; Ouabain; Papillary Muscles; Ryanodine; Troponin; Troponin C

We investigated the effects of 1 and 3 mM 2,3-butanedione monoxime (BDM, diacetyl monoxime) on excitation and contraction of cardiac muscle in several types of preparations at various levels of organization. We selected a concentration of BDM that was not expected to affect sarcolemmal calcium flux and action potential duration in cardiac tissue. Two indicators were used to record intracellular calcium. Aequorin, a bioluminescent calcium indicator, was used in studies with ferret papillary muscle preparations, and fura-2, a fluorescent calcium indicator, was used in studies with guinea pig cardiac myocytes. In both cases, addition of BDM resulted in a reduction of peak intracellular calcium released from the sarcoplasmic reticulum and a reduction of peak twitch force. The duration of the action potential of isolated myocytes was slightly abbreviated in the presence of BDM. In studies on the calcium current in the myocytes, addition of BDM was associated with reduced calcium current at any potential. Peak calcium current was reduced by 7.9 +/- 1% in the presence of BDM. In tetanized ferret papillary muscles, BDM reduced maximal calcium-activated force by 30 +/- 5% and increased the calcium ion concentration required for half-maximal force by 0.1 +/- 0.01 microM. The Hill coefficient was reduced from 5.00 +/- 0.11 to 3.40 +/- 0.20. Maximal shortening velocity of ferret papillary muscles was increased in the presence of BDM from 1.55 +/- 0.24 to 2.04 +/- 0.33 mm/sec. Ca2+ binding to troponin C in skinned fiber preparations from guinea pig, bovine, and canine hearts was unaffected by addition of up to 10 mM BDM. Our results indicate that BDM affects both calcium availability and responsiveness of the myofilaments to Ca2+. Uncoupling of contractile activation from excitation may also result from altered crossbridge kinetics.

Topics: Animals; Calcium; Diacetyl; Electrophysiology; Heart; Homeostasis; Intracellular Membranes; Myocardial Contraction; Myocardium; Ryanodine; Sarcolemma; Troponin; Troponin C

Isolated, perfused guinea pig hearts were used to determine the effects of diacetyl monoxime (DAM) on atrial rate, atrioventricular conduction time (AVCT), and left ventricular peak systolic pressure (LVSP). Contractile force and calcium transients were also monitored in isolated papillary muscles injected with aequorin in the absence and presence of ryanodine (RYA). In the isolated heart, 0.2-5 mM DAM caused significant dose-dependent decreases in LVSP (up to 51%) without change in atrial rate and AVCT. DAM (10 mM) produced a small slowing of atrial rate, no change in AVCT, and a 76% decrease in LVSP; 20 and 30 mM DAM further reduced LVSP, decreased atrial rate 38%, and produced AV dissociation. In isolated, paced papillary muscles, 2, 10, and 30 mM DAM decreased contractile force 27, 58, and 87%, respectively, while calcium transients increased by -9, 38, and 225%, respectively. All cardiac effects of DAM were readily reversible. RYA (1 microM) alone and with DAM (30 mM) decreased contractile force by 30 and 99%, respectively and decreased calcium transients by 59 and 74%, respectively. This study shows that low concentrations of DAM have little effect on electrical activity but greatly depress contractility and modify intracellular handling of calcium.

Topics: Animals; Atrial Function; Blood Pressure; Calcium; Diacetyl; Guinea Pigs; Heart Atria; Heart Conduction System; Heart Rate; Heart Ventricles; Myocardial Contraction; Myocardium; Papillary Muscles; Pressure; Ryanodine; Ventricular Function

The effect of 2,3-butanedione 2-monoxime (BDM), a substance possessing phosphatase-like activity, was studied on action potentials of isolated rat heart and on the slow inward calcium current and outward current (including the 4-aminopyridine (4-AP)-sensitive transient outward component), in rat ventricular myocytes. In contrast to what was observed by other authors in different species and cardiac tissues, BDM increased markedly the amplitude and duration of the rat ventricular action potential plateau. On the other hand, in the presence of 4-AP and ryanodine BDM shortened action potential duration. BDM decreased in a dose dependent manner the amplitude of both the slow inward calcium current and the transient outward current, accelerated their inactivation and shifted their steady-state inactivation-voltage relationships towards negative potentials. BDM also depressed other components of outward current. It is suggested that the lengthening effect of BDM on action potential duration results mainly from the simultaneous reduction of both the slow inward calcium current and the transient outward current, two antagonistic currents with unequal influences on action potential plateau development. The similarity of effect of BDM on these two currents also suggests that ionic channels generating them might require similar phosphorylation for their functioning.

Topics: 4-Aminopyridine; Action Potentials; Animals; Calcium; Cells, Cultured; Diacetyl; Heart; Heart Ventricles; Ion Channel Gating; Rats; Ryanodine