Excitation-contraction Coupling In Ventricular Myocytes Research Articles

Effects of Varying Transverse and Axial Tubules in a Three-Dimensional Model of Calcium Signaling in the Human Atrial Myocyte

T-tubules are invaginations of the sarcolemma that play a key role in excitation-contraction coupling in ventricular myocytes. Atrial myocytes are generally thought to possess sparse irregular transverse-tubular (TT) components, as opposed to the highly dense and regular ventricular TT system. Axial tubules (ATs) with extensive junctions to the sarcoplasmic reticulum that include ryanodine receptor (RyR) clusters, characterized by rapid activation of Ca2+-induced Ca2+ release, have also been identified in atrial myocytes. AT and TT remodeling and changes in distribution, composition, and phosphorylation status of Ca2+ release units are thought to underlie Ca2+ abnormalities in atrial fibrillation (AF), the most common cardiac arrhythmia. Here, we performed a computational analysis to investigate how changes in the tubular network affect human atrial electrophysiology. We modified our well-established three-dimensional model of Ca2+ signaling in the rabbit ventricular myocyte to develop an analogous model in the human atrium. We also coupled the Ca2+ signaling model to our well-established model of membrane electrophysiology in the human atrial myocyte. We systematically varied TT and AT density and RyR distribution and assessed the effect on Ca2+ spark and wave properties. When TT density is low, as shown in isolated atrial myocytes, the model recapitulates the typical U-shaped Ca2+ wave seen experimentally in transverse confocal line-scan images. Introduction of ATs resulted in W-shaped Ca2+ waves, reflecting more synchronous Ca2+ release. The frequency and amplitude of Ca2+ release events were affected by both density of TT and AT, as well as RyR distribution. Our newly developed three-dimensional model of the human atrial myocyte will be employed to investigate whether and how AF-induced cellular electrical and structural remodeling effects collectively contribute to the membrane potential and Ca2+ abnormalities seen in AF.

Cholesterol Protects Against Acute Stress-Induced T-Tubule Remodeling in Mouse Ventricular Myocytes.

Efficient excitation-contraction coupling in ventricular myocytes depends critically on the presence of the t-tubular network. It has been recently demonstrated that cholesterol, a major component of the lipid bilayer, plays an important role in long-term maintenance of the integrity of t-tubular system although mechanistic understanding of underlying processes is essentially lacking. Accordingly, in this study we investigated the contribution of membrane cholesterol to t-tubule remodeling in response to acute hyposmotic stress. Experiments were performed using isolated left ventricular cardiomyocytes from adult mice. Depletion and restoration of membrane cholesterol was achieved by applying methyl-β-cyclodextrin (MβCD) and water soluble cholesterol (WSC), respectively, and t-tubule remodeling in response to acute hyposmotic stress was assessed using fluorescent dextran trapping assay and by measuring t-tubule dependent IK1 tail current (IK1,tail). The amount of dextran trapped in t-tubules sealed in response to stress was significantly increased when compared to control cells, and reintroduction of cholesterol to cells treated with MβCD restored the amount of trapped dextran to control values. Alternatively, application of WSC to normal cells significantly reduced the amount of trapped dextran further suggesting the protective effect of cholesterol. Importantly, modulation of membrane cholesterol (without osmotic stress) led to significant changes in various parameters of IK1, tail strongly suggesting significant but essentially hidden remodeling of t-tubules prior to osmotic stress. Results of this study demonstrate that modulation of the level of membrane cholesterol has significant effects on the susceptibility of cardiac t-tubules to acute hyposmotic stress.

Contractile responses to endothelin-1 are regulated by PKC phosphorylation of cardiac myosin binding protein-C in rat ventricular myocytes

The shortening of sarcomeres that co-ordinates the pump function of the heart is stimulated by electrically-mediated increases in [Ca2+]. This process of excitation-contraction coupling (ECC) is subject to modulation by neurohormonal mediators that tune the output of the heart to meet the needs of the organism. Endothelin-1 (ET-1) is a potent modulator of cardiac function with effects on contraction amplitude, chronotropy and automaticity. The actions of ET-1 are evident during normal adaptive physiological responses and increased under pathophysiological conditions, such as following myocardial infarction and during heart failure, where ET-1 levels are elevated. In myocytes, ET-1 acts through ETA- or ETB-G protein-coupled receptors (GPCRs). Although well studied in atrial myocytes, the influence and mechanisms of action of ET-1 upon ECC in ventricular myocytes are not fully resolved. We show in rat ventricular myocytes that ET-1 elicits a biphasic effect on fractional shortening (initial transient negative and sustained positive inotropy) and increases the peak amplitude of systolic Ca2+ transients in adult rat ventricular myocytes. The negative inotropic phase was ETB receptor-dependent, whereas the positive inotropic response and increase in peak amplitude of systolic Ca2+ transients required ETA receptor engagement. Both effects of ET-1 required phospholipase C (PLC)-activity, although distinct signalling pathways downstream of PLC elicited the effects of each ET receptor. The negative inotropic response involved inositol 1,4,5-trisphosphate (InsP3) signalling and protein kinase C epsilon (PKCε). The positive inotropic action and the enhancement in Ca2+ transient amplitude induced by ET-1 were independent of InsP3 signalling, but suppressed by PKCε. Serine 302 in cardiac myosin binding protein-C was identified as a PKCε substrate that when phosphorylated contributed to the suppression of contraction and Ca2+ transients by PKCε following ET-1 stimulation. Thus, our data provide a new role and mechanism of action for InsP3 and PKCε in mediating the negative inotropic response and in restraining the positive inotropy and enhancement in Ca2+ transients following ET-1 stimulation.

Cholesterol Protects Against Acute Stress-Induced T-Tubule Remodeling in Mouse Ventricular Myocytes

Efficient excitation-contraction coupling in ventricular myocytes depends critically on the presence of the t-tubular network. It has been recently demonstrated that cholesterol, a major component of the lipid bilayer, plays an important role in maintaining the integrity of t-tubular system although mechanistic understanding of underlying processes is essentially lacking. In this study we tested the hypothesis that membrane cholesterol protects against various acute stresses, including osmotic challenge. Experiments were performed using isolated left ventricular cardiomyocytes from adult mice. Depletion and restoration of membrane cholesterol was achieved by applying methyl-β-cyclodextrin (MβCD) and water soluble cholesterol (WSC), respectively. T-tubule remodeling in response to acute hyposmotic stress (211± 2 mOsm; 0.7 Na) was assessed using fluorescent dextran trapping assay and by measuring t-tubule dependent IK1 tail current. Myocytes were first treated with 3 mM MβCD for 1h at RT and 0.7 Na osmotic stress applied in the presence of extracellular fluorescent dextran. The amount of dextran trapped in t-tubules sealed in response to stress was increased by ≈25% when compared to control cells. Reintroduction of cholesterol by application of 5 mg/ml WSC to cells treated with MβCD restored the amount of trapped dextran to control values. Alternatively, application of 5 mg/ml WSC to normal cells reduced the amount of trapped dextran by ≈50%, confirming significant protective effect of cholesterol. Unexpectedly, depletion and enrichment of membrane cholesterol (without osmotic stress) accelerated and decelerated, respectively, the kinetics of IK1 tail current suggesting significant t-tubule remodeling prior to osmotic stress. Results of this study demonstrate that modulation of the level of membrane cholesterol has significant effects on the properties of cardiac t-tubules and on t-tubule response to acute hyposmotic stress.

The Effects of Aging on the Regulation of T-Tubular ICa by Caveolin in Mouse Ventricular Myocytes.

Aging is associated with diminished cardiac function in males. Cardiac excitation-contraction coupling in ventricular myocytes involves Ca influx via the Ca current (ICa) and Ca release from the sarcoplasmic reticulum, which occur predominantly at t-tubules. Caveolin-3 regulates t-tubular ICa, partly through protein kinase A (PKA), and both ICa and caveolin-3 decrease with age. We therefore investigated ICa and t-tubule structure and function in cardiomyocytes from male wild-type (WT) and caveolin-3-overexpressing (Cav-3OE) mice at 3 and 24 months of age. In WT cardiomyocytes, t-tubular ICa-density was reduced by ~50% with age while surface ICa density was unchanged. Although regulation by PKA was unaffected by age, inhibition of caveolin-3-binding reduced t-tubular ICa at 3 months, but not at 24 months. While Cav-3OE increased cardiac caveolin-3 protein expression ~2.5-fold at both ages, the age-dependent reduction in caveolin-3 (WT ~35%) was preserved in transgenic mice. Overexpression of caveolin-3 reduced t-tubular ICa density at 3 months but prevented further ICa loss with age. Measurement of Ca release at the t-tubules revealed that the triggering of local Ca release by t-tubular ICa was unaffected by age. In conclusion, the data suggest that the reduction in ICa density with age is associated with the loss of a caveolin-3-dependent mechanism that augments t-tubular ICa density.

Dynamic Changes in Sarcoplasmic Reticulum Structure in Ventricular Myocytes

The fidelity of excitation-contraction (EC) coupling in ventricular myocytes is remarkable, with each action potential evoking a [Ca2+]i transient. The prevalent model is that the consistency in EC coupling in ventricular myocytes is due to the formation of fixed, tight junctions between the sarcoplasmic reticulum (SR) and the sarcolemma where Ca2+ release is activated. Here, we tested the hypothesis that the SR is a structurally inert organelle in ventricular myocytes. Our data suggest that rather than being static, the SR undergoes frequent dynamic structural changes. SR boutons expressing functional ryanodine receptors moved throughout the cell, approaching or moving away from the sarcolemma of ventricular myocytes. These changes in SR structure occurred in the absence of changes in [Ca2+]i during EC coupling. Microtubules and the molecular motors dynein and kinesin 1(Kif5b) were important regulators of SR motility. These findings support a model in which the SR is a motile organelle capable of molecular motor protein-driven structural changes.

Ablation of Protein Kinase A or Calmodulin Kinase II Phosphorylation Sites on Phospholamban Confer Arrhythmia Resistance in Sinoatrial Nodal Pacemaker Cells

Phospholamban (PLN) is a negative regulator of the sarcoplasmic reticulum Ca2+ ATPase (SERCa). PLN is phosphorylated by Protein Kinase A (Ser16) or Calmodulin Kinase II (Thr17). These phosphorylations reduce the inhibitory effects of PLN on SERCa. Phosphorylation at PLN Ser16 and Thr17 are important for catecholamine effects on excitation-contraction coupling in ventricular myocytes, but their role in sinoatrial nodal (SAN) cells is unknown. We isolated SAN cells from wild type (WT) controls and from transgenic mice where Ser16Ala or Thr17Ala PLN mutants are expressed in lieu of WT PLN. We recorded spontaneous action potentials by perforated patch clamp at 35±1°C. SAN cell automaticity rates (‘beats’/min) were not significantly different between Ser16Ala, Thr17Ala or WT at baseline: WT (n=18) 269±12; T17A (n=9) 264±23; S16A (n=16) 256±17. No early (EAD) or delayed (DAD) afterdepolarizations were observed at baseline. EADs and DADs were induced by isoproterenol (1-5 μM) in WT SAN cells (cells with afterdepolarizations/total cells tested: 10/13) but not in Ser16Ala (0/6) and Thr17Ala (0/5) SAN cells (p<0.01 in both cases compared to WT). These results suggest that catecholamine induced EADs and DADs require phosphorylation of PLN Ser16 or Thr17 and highlight the importance of the intracellular Ca2+ cycling machinery for determining SAN cell vulnerability to adverse effects of catecholamine stimulation.

Hypertension-induced remodeling of cardiac excitation-contraction coupling in ventricular myocytes occurs prior to hypertrophy development

Hypertension is a major risk factor for developing cardiac hypertrophy and heart failure. Previous studies show that hypertrophied and failing hearts display alterations in excitation-contraction (E-C) coupling. However, it is unclear whether remodeling of the E-C coupling system occurs before or after heart disease development. We hypothesized that hypertension might cause changes in the E-C coupling system that, in turn, induce hypertrophy. Here we tested this hypothesis by utilizing the progressive development of hypertensive heart disease in the spontaneously hypertensive rat (SHR) to identify a window period when SHR had just developed hypertension but had not yet developed hypertrophy. We found the following major changes in cardiac E-C coupling during this window period. 1) Using echocardiography and hemodynamics measurements, we found a decrease of left ventricular ejection fraction and cardiac output after the onset of hypertension. 2) Studies in isolated ventricular myocytes showed that myocardial contraction was also enhanced at the same time. 3) The action potential became prolonged. 4) The E-C coupling gain was increased. 5) The systolic Ca(2+) transient was augmented. These data show that profound changes in E-C coupling already occur at the onset of hypertension and precede hypertrophy development. Prolonged action potential and increased E-C coupling gain synergistically increase the Ca(2+) transient. Functionally, augmented Ca(2+) transient causes enhancement of myocardial contraction that can partially compensate for the greater workload to maintain cardiac output. The increased Ca(2+) signaling cascade as a molecular mechanism linking hypertension to cardiac hypertrophy development is also discussed.

No Apparent Requirement for Neuronal Sodium Channels in Excitation-Contraction Coupling in Rat Ventricular Myocytes

The majority of Na channels in the heart are composed of the tetrodotoxin (TTX)-resistant (KD, 2 to 6 micromol/L) "cardiac" NaV1.5 isoform; however, TTX-sensitive (KD, 1 to 25 nmol/L) "neuronal" Na channel isoforms have recently been detected in several cardiac preparations. In the present study, we determined the functional subcellular localization of Na channel isoforms (according to their TTX sensitivity) in rat ventricular myocytes by recording INa in control and detubulated myocytes. We found that TTX-sensitive INa (KD, &8.8 nmol/L) makes up 14+/-3% of total INa in control and < or =4% in detubulated myocytes and calculated that &80% of TTX-sensitive INa is located in the t-tubules, where it generates &1/3 of t-tubular INa. In contrast, TTX-resistant INa is located predominantly (&78%) at the surface membrane. We also investigated the possible contribution of TTX-sensitive INa to excitation-contraction coupling, using 200 nmol/L TTX to selectively block TTX-sensitive INa. TTX decreased the rate of depolarization of the action potential by 10% but did not delay the rise of systolic Ca2+ in the center of the cell (transverse confocal line scan), suggesting that TTX-sensitive INa does not play a role in synchronizing Ca2+ release at the t-tubules; the amplitude of the Ca2+ transient and contraction were also unchanged by 200 nmol/L TTX. The quantity of charge entering via ICa elicited by control or TTX action potential waveforms was similar, suggesting that the trigger for Ca2+ release is not altered by blocking TTX-sensitive INa. We conclude that neuronal INa is concentrated at the t-tubules, but there is no evidence of a requirement for these channels in normal excitation-contraction coupling in ventricular myocytes.

Depletion of T-tubules and specific subcellular changes in sarcolemmal proteins in tachycardia-induced heart failure.

The T-tubule membrane network is integrally involved in excitation-contraction coupling in ventricular myocytes. Ventricular myocytes from canine hearts with tachycardia-induced dilated cardiomyopathy exhibit a decrease in accessible T-tubules to the membrane-impermeant dye, di8-ANNEPs. The present study investigated the mechanism of loss of T-tubule staining and examined for changes in the subcellular distribution of membrane proteins essential for excitation-contraction coupling. Isolated ventricular myocytes from canine hearts with and without tachycardia-induced heart failure were studied using fluorescence confocal microscopy and membrane fractionation techniques using a variety of markers specific for sarcolemmal and sarcoplasmic reticulum proteins. Probes for surface glycoproteins, Na/K ATPase, Na/Ca exchanger and Ca(v)1.2 demonstrated a prominent but heterogeneous reduction in T-tubule labeling in both intact and permeabilised failing myocytes, indicating a true depletion of T-tubules and associated membrane proteins. Membrane fractionation studies showed reductions in L-type Ca(2+) channels and beta-adrenergic receptors but increased levels of Na/Ca exchanger protein in both surface sarcolemma and T-tubular sarcolemma-enriched fractions; however, the membrane fraction enriched in junctional complexes of sarcolemma and junctional sarcoplasmic reticulum demonstrated no significant changes in the density of any sarcolemmal protein or sarcoplasmic reticulum protein assayed. Failing canine ventricular myocytes exhibit prominent depletion of T-tubules and changes in the density of a variety of proteins in both surface and T-tubular sarcolemma but with preservation of the protein composition of junctional complexes. This subcellular remodeling contributes to abnormal excitation-contraction coupling in heart failure.

Biphasic effects of cell volume on excitation-contraction coupling in rabbit ventricular myocytes.

We studied the effects of osmotic swelling on the components of excitation-contraction coupling in ventricular myocytes. Myocyte volume rapidly increased 30% in hyposmotic (0.6T) solution and was constant thereafter. Cell shortening transiently increased 31% after 4 min in 0.6T but then decreased to 68% of control after 20 min. In parallel, the L-type Ca(2+) current (I(Ca-L)) transiently increased 10% and then declined to 70% of control. Similar biphasic effects on shortening were observed under current clamp. In contrast, action potential duration was unchanged at 4 min but decreased to 72% of control after 20 min. Ca(2+) transients were measured with fura 2-AM. The emission ratio with excitation at 340 and 380 nm (f(340)/f(380)) decreased by 12% after 3 min in 0.6T, whereas shortening and I(Ca-L) increased at the same time. After 8 min, shortening, I(Ca-L), and the f(340)/f(380) ratio decreased 28, 25, and 59%, respectively. The results suggest that osmotic swelling causes biphasic changes in I(Ca-L) that contribute to its biphasic effects on contraction. In addition, swelling initially appears to reduce the Ca(2+) transient initiated by a given I(Ca-L), and later, both I(Ca-L) and the Ca(2+) transient are inhibited.

Impaired cardiac excitation-contraction coupling in ventricular myocytes from Ames dwarf mice with IGF-I deficiency.

Growth hormone (GH) and insulin-like growth factor-I (IGF-I) are involved in the regulation of cardiovascular function. GH/IGF-I deficiency is associated with impaired cardiac performance manifested as reduced left ventricular ejection fraction and diastolic filling. This study was to determine the impact of IGF-I deficiency on single cardiac myocyte excitation-contraction (E-C) coupling. Ventricular myocytes were isolated from adult Ames dwarf mice and age-matched wild-type siblings. Dwarf mice are characterized by severe IGF-I deficiency. Mechanical properties were evaluated using a video edge detection system. Myocytes were electrically stimulated at 0.5 Hz. The contractile properties analysed included peak shortening (PS), time to peak shortening (TPS) and time to 90% relengthening (TR(90)), and maximal velocities of shortening/relengthening (+/-d L/d t). Intracellular Ca(2+) transients were evaluated by fura-2 fluorescence microscopy. Dwarf mice exhibited significantly reduced body and heart weights and severely deficient plasma IGF-I. Myocytes from dwarf mice displayed significantly smaller cell lengths (CLs), prolonged TPS/TR(90) and reduced +/-d L/d t compared with the wild-type littermates. The absolute PS was similar although PS/CL was enhanced in the dwarf group. Myocytes from dwarf animals displayed reduced peak intracellular Ca(2+) levels and slowed intracellular Ca(2+) clearing associated with a comparable resting intracellular Ca(2+). Furthermore, myocytes from the dwarf hearts were equally responsive to an elevation in extracellular Ca(2+) and exhibited an augmented stepwise decrease in response to minimal increase in stimulating frequencies compared with those from the wild-type group. These results suggest that deficiency in IGF-I may be directly associated with cardiac E-C coupling dysfunction at the ventricular myocyte level.

Progression of Heart Failure

The cardiac ryanodine receptor (RyR2)/Ca2+ release channel on the sarcoplasmic reticulum (SR) is regulated by evolutionarily highly conserved signaling pathways that control excitation-contraction (EC) coupling in the heart. Phosphorylation of RyR2 by cAMP-dependent protein kinase (PKA) plays a key role in regulating the channel in response to stress via activation of the sympathetic nervous system (the “fight-or-flight response”).1 Maladaptive PKA hyperphosphorylation of RyR2 in failing hearts alters channel function, which may cause depletion of SR Ca2+ and diastolic release of SR Ca2+. This can initiate delayed afterdepolarizations that trigger ventricular arrhythmias.1 Mutations in RyR2 recently have been identified in patients with catecholaminergic induced sudden cardiac death (SCD).2–4⇓⇓ There may be a direct link between the PKA hyperphosphorylation of RyR2 that occurs during the progression of heart failure and fatal cardiac arrhythmias. Regulation of cardiac EC coupling by the release of Ca2+ from the SR via RyR2 in cardiomyocytes, known as Ca2+-induced Ca2+ release (CICR), has been appreciated for more than a decade.5,6⇓ Furthermore, it is well known that the amplitude of the Ca2+ transient generated by SR Ca2+ release determines contractile force in cardiomyocytes. The systems that regulate SR Ca2+ release include: (1) the triggers (predominantly Ca2+ influx through the voltage-gated Ca2+ channel on the plasma membrane); (2) the SR Ca2+ release channel or type 2 RyR2; and (3) the SR Ca2+ reuptake pump (SERCA2a) and its regulator phospholamban. These systems (trigger, release, and reuptake) are modulated by signaling pathways, including the β-adrenergic receptor (β-AR) signaling pathway (ie, phosphorylation by PKA). Activation of the sympathetic nervous system in response to stress results in elevation of cAMP levels and activation of PKA. Phosphorylation of RyR2 may not correlate directly …

Altered cardiac excitation-contraction coupling in ventricular myocytes from spontaneously diabetic BB rats.

Cardiac excitation-contraction (E-C) coupling abnormalities in chemically induced diabetes have been well defined. Heart dysfunction has also been reported in diabetes of genetic origin. The purpose of this study was to determine whether heart dysfunction in genetically predisposed diabetes is attributable to impaired E-C coupling at the cellular level. Myocytes were isolated from 1-yr-old BioBreed (BB) spontaneously diabetic-prone (BB/DP) rats and their diabetic-resistant littermates (BB/DR). Mechanical properties were evaluated by use of a video edge-detection system. Myocytes were electrically stimulated at 0.5 Hz. The contractile properties analyzed included peak shortening (PS), time-to-peak shortening (TPS), time-to-90% relengthening (TR(90)), and maximal velocities of shortening and relengthening (+/-dL/dt). Intracellular Ca(2+) handling was evaluated with fura 2 fluorescent dye. Myocytes from spontaneously diabetic hearts exhibited a depressed PS, prolonged TPS and TR(90), and reduced +/-dL/dt. Consistent with the mechanical response, myocytes from the BB/DP group displayed reduced resting and peak intracellular Ca(2+) concentration associated with a slowed Ca(2+)-transient decay. Furthermore, myocytes from BB/DP hearts were less responsive to increases in extracellular Ca(2+) and norepinephrine and equally responsive to increases in stimulation frequency and KCl compared with those from the BB/DR group. These results suggest that the genetic diabetic state produces altered cardiac E-C coupling, in part, because of abnormalities of the myocyte, similar to that demonstrable after chemically induced diabetes or during human diabetes.

Calcium transients in isolated cardiac myocytes are altered by 1,1,1-trichloroethane

1,1,1-Trichloroethane is a widely used solvent that is annually linked to several cases of sudden death following accidental exposure or abuse. Sudden death is believed to be due to ventricular fibrillation or myocardial depression. The purpose of this study was to investigate the mechanism of myocardial depression by assessing the influence of 1,1,1-trichloroethane on intracellular Ca transients in single neonatal rat ventricular myocytes using spectrofluorometric analysis of fura-2-Ca binding. Cells were exposed to 1,1,1-trichloroethane in Hanks' balanced salt solution aliquoted as a 0.2% DMSO solution by a single pass suffusion in an environmentally controlled chamber. 1,1,1-Trichloroethane (0.25 m m–8 m m) reduced the height of electrically (1 Hz, 60 V, 10 ms) induced Ca transients concentration dependently and reversibly to a maximum of about 50% with no effect on diastolic Ca concentration. Video motion analysis revealed an inhibition of contractility in the same concentration range. 1,1,1-Trichloroethane inhibited cytosolic Ca increase in response to KCl-induced (90 m m) depolarizations and further decreased the limited Ca transients in ryanodine (1 μ m) pretreated myocytes. Increased external Ca (5 m m) antagonized the effect of 0.5 m m 1,1,1-trichloroethane on the Ca transients. 1,1,1-Trichloroethane reduced the caffeine (10 m m) releasable Ca pool in myocytes. These results show that 1,1,1-trichloroethane inhibits Ca mobilization during excitation-contraction coupling in ventricular myocytes. An inhibitory action on the influx of extracellular Ca as well as on sarcoplasmic reticulum Ca release and sequestration is likely to be responsible for this action.

Neurohumoral regulation of excitation-contraction coupling in ventricular myocytes from cardiomyopathic hamsters

The aim was to evaluate the regulation of contractility by autonomic stimulation in the necrotic stage of cardiomyopathy in male Syrian hamsters. The electrical and contractile activity of isolated intracellularly stimulated ventricular myocytes has been recorded and dose-response curves to [Ca2+]o, and to beta adrenergic, alpha adrenergic, and muscarinic agonists and antagonists were examined. Ventricular cardiomyocytes were isolated by enzymatic dissociation of hearts from 90 to 120 day old cardiomyopathic hamsters CHF 147 and from age matched non-myopathic controls: CHF 148 or golden hamsters. The membrane potential was recorded by suction (patch) electrodes. The contractile activity was recorded by a video system as the shortenings of the myocytes. The contractile response (EC50) to beta adrenergic stimulation (isoprenaline) showed a bimodal distribution: 60% of the myopathic myocytes responded like the controls, while in the remaining 40% the sensitivity was significantly decreased. The electrical activity and beta adrenergic receptor density were not different from the controls. The alpha adrenergic stimulation (by phenylephrine) was enhanced, while response to the muscarinic agonist carbachol (in the presence of isoprenaline) was attenuated in the myopathic cells. Sensitivity to [Ca2+]o was unchanged. Profound changes occur in the contractile response of myocytes from cardio-myopathic hamster to stimulation by mediators of the autonomic nervous system, which at this necrotic stage are not related to any significant changes in basal contractile response to [Ca2+]o, to the electrical activity, or to the number of beta adrenergic receptors.

Ethanol inhibits electrically-induced calcium transients in isolated rat cardiac myocytes

The fluorescent Ca 2+ indicator fura-2 was used to follow cytosolic Ca 2+ transients during excitation-contraction coupling in suspensions of isolated rat heart cells induced to beat synchronously by electrical field stimulation. The Ca 2+ transient reached a maximum at about 30 ms after application of the electrical stimulus and then relaxed to the basal level over the following 200 ms. Treatment of the myocytes with 0.25 to 2.0% ethanol (40 to 340 m m) caused a decrease in the peak of the Ca 2+ transient, with no apparent change in the time to peak. This effect of ethanol occurred progressively over a period of about 1 min before a new stable state was achieved. At 1% ethanol the peak Ca 2+ level was reduced by 50%. Ethanol reversed the stimulatory effect of isoproterenol on peak Ca 2+ and at high levels of ethanol the β-adrenergic agonist no longer caused any enhancement of the Ca 2+ transient. Ethanol did not cause any marked change in the basal Ca 2+ level between beats. The effects of ethanol were readily reversible. These results suggest that the negative inotropic effect of ethanol observed in intact cardiac muscle preparations may result in part from interference with the Ca 2+ fluxes responsible for excitation-contraction coupling in ventricular myocytes.