Contraction Coupling In Myocytes Research Articles

Analysis of factors affecting Ca2+‐dependent inactivation dynamics of L‐type Ca2+ current of cardiac myocytes in pulmonary vein of rabbit

L-type Ca(2+) channels (ICaLs) are inactivated by an increase in intracellular [Ca(2+)], known as Ca(2+)-dependent inactivation (CDI). CDI is also induced by Ca(2+) released from the sarcoplasmic reticulum (SR), known as release-dependent inhibition (RDI). As both CDI and RDI occur in the junctional subsarcolemmal nanospace (JSS), we investigated which factors are involved within the JSS using isolated cardiac myocytes from the main pulmonary vein of the rabbit. Using the whole-cell patch clamp technique, RDI was readily observed with the application of a pre-pulse followed by a test pulse, during which the ICaLs exhibited a decrease in peak current amplitude and a slower inactivation. A fast acting Ca(2+) chelator, 1,2-bis(o-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid (BAPTA), abolished this effect. As the time interval between the pre-pulse and test pulse increased, the ICaLs exhibited greater recovery and the RDI was relieved. Inhibition of the ryanodine receptor (RyR) or the SR Ca(2+)-ATPase (SERCA) greatly attenuated RDI and facilitated ICaL recovery. Removal of extracellular Na(+),which inhibits the Na(+)-Ca(2+) exchange (Incx), greatly enhanced RDI and slowed ICaL recovery, suggesting that Incx critically controls the [Ca(2+)] in the JSS. We incorporated the Ca(2+)-binding kinetics of the ICaL into a previously published computational model. By assuming two Ca(2+)-binding sites in the ICaL, of which one is of low-affinity with fast kinetics and the other is of high-affinity with slower kinetics, the new model was able to successfully reproduce RDI and its regulation by Incx. The model suggests that Incx accelerates Ca(2+) removal from the JSS to downregulate CDI and attenuates SR Ca(2+) refilling. The model may be useful to elucidate complex mechanisms involved in excitation–contraction coupling in myocytes.

Arrhythmogenic Ca 2+ release from cardiac myofilaments

We investigated the initiation of Ca 2+waves underlying triggered propagated contractions (TPCs) occurring in rat cardiac trabeculae under conditions that simulate the functional non-uniformity caused by mechanical or ischemic local damage of the myocardium. A mechanical discontinuity along the trabeculae was created by exposing the preparation to a small constant flow jet of solution with a composition that reduces excitation–contraction coupling in myocytes within that segment. Force was measured and sarcomere length as well as [Ca 2+] i were measured regionally. When the jet-contained Caffeine, BDM or Low-[Ca 2+], muscle-twitch force decreased and the sarcomeres in the exposed segment were stretched by shortening of the normal regions outside the jet. During relaxation the sarcomeres in the exposed segment shortened rapidly. Short trains of stimulation at 2.5 Hz reproducibly caused Ca 2+-waves to rise from the borders exposed to the jet. Ca 2+-waves started during force relaxation of the last stimulated twitch and propagated into segments both inside and outside of the jet. Arrhythmias, in the form of non-driven rhythmic activity, were triggered when the amplitude of the Ca 2+-wave increased by raising [Ca 2+] o. The arrhythmias disappeared when the muscle uniformity was restored by turning the jet off. We have used the four state model of the cardiac cross bridge (Xb) with feedback of force development to Ca 2+ binding by Troponin-C (TnC) and observed that the force–Ca 2+ relationship as well as the force–sarcomere length relationship and the time course of the force and Ca 2+ transients in cardiac muscle can be reproduced faithfully by a single effect of force on deformation of the TnC·Ca complex and thereby on the dissociation rate of Ca 2+. Importantly, this feedback predicts that rapid decline of force in the activated sarcomere causes release of Ca 2+ from TnC.Ca 2+,which is sufficient to initiate arrhythmogenic Ca 2+ release from the sarcoplasmic reticulum. These results show that non-uniform contraction can cause Ca 2+-waves underlying TPCs, and suggest that Ca 2+ dissociated from myofilaments plays an important role in the initiation of arrhythmogenic Ca 2+-waves.

Altered Excitation–Contraction Coupling in Myocytes from Remodeled Myocardium after Chronic Myocardial Infarction

Following myocardial infarction (MI), the left ventricle undergoes progressive dilatation and eccentric hypertrophy, i.eremodeling, which is greater in the adjacent than the remote region. The cellular mechanisms underlying these regional differences were studied. One (n=5) and 8 weeks (n=8) after anteroapical MI in sheep, cardiac myocytes were isolated from the adjacent and remote regions. At 8 weeks after MI, myocyte function in the remote region was not different from values either in sham controls (n=3) or animals 1 week after MI. At 8 weeks after MI, myocyte contractile function (% contraction) was decreased, P<0.01, in the adjacent region (6.4±0.4%), as compared with the remote region (8.8±0.5%) and was associated with decreased amplitude of Ca2+transients (adjacent, 0.69±0.09 v remote, 1.08±0.20, P<0.05) and L-type Ca2+current density (adjacent, 3.6±0.2 v remote, 4.8±0.2 pA/pF, P<0.05). Relaxation was also impaired significantly in myocytes from the adjacent region, associated with decreased protein levels of SERCA2a. The myocytes were hypertrophied more in the adjacent region than the remote region. Furthermore, focal areas of central myofibrillar lysis and increased glycogen deposition were observed in the adjacent region. These results indicate that impaired excitation–contraction coupling underlies dysfunction of myocytes from the adjacent non-infarcted myocardium after chronic MI, even in the absence of heart failure. Hypertrophy is implicated as the mechanism, since these changes were noted at 8 weeks, but not at 1 week after MI.

Isoform expression of the sarcoplasmic reticulum Ca2+ release channel (ryanodine channel) in human myocardium.

The Ca2+ release channel of the sarcoplasmic reticulum (SR) is essential for the release of Ca2+ from intracellular stores and is expressed widely in various excitable cells. It plays a key role particularly in excitation contraction coupling in myocytes in skeletal and cardiac muscle. Three isoforms of the SR Ca2+ release channel have been cloned. Recently coexpression of different isoforms was reported in different animal species and various tissues. In human cardiac tissue, however, isoform expression is not yet established. Therefore the aim of this study was to characterize isoform expression of the SR Ca2+ release channel in the human heart. We examined specific isoform expression of mRNA and proteins of the SR Ca2+ release channel in the four different chambers of the heart and the interventricular septum from explanted human hearts from nonfailing organ donors (n=8). Reverse transcriptase PCR from total cardiac RNA with isoform specific primers and western blots from myocardial homogenates with isoform specific antibodies were performed. Quantification of protein expression was achieved by densitometric scanning and computer analysis and is expressed as densitometric units per microgram of protein. A single band DNA signal was detected by reverse transcriptase PCR for the skeletal isoform 1 and the cardiac isoform 2 and isoform 3 in all regions of the human heart investigated. Specific protein expression was detected in all five myocardial regions of the human heart in western blots for the skeletal isoform I and cardiac isoform 2, and a weaker specific band was also detectable for isoform 3 of the SR Ca2+ release channel. Quantification of protein expression showed significant (P=0.008) lower expression of isoform 1 in the right ventricle (42+/-4 densitometric units/g tissue) and similar expression in all other regions (right atrium 58+/-3; septum 51+/-5, left atrium 54+/-5; left ventricle 51+/-6). Isoform 2 of the SR Ca2+ release channel was also significantly lower (P=0.001) in the right ventricle (33+/-4 densitometric/g tissue) and similar in the other heart chambers (right atrium 42+/-5: septum 41+/-3, left atrium 52+/-6, left ventricle 42+/-3). Differences in isoform 3 of the SR Ca2+ release channel for the various myocardial regions did not reach significant levels (right atrium 45+/-6, right ventricle 38+/-5, septum 49+/-8, left atrium 46+/-7, and in left ventricle 45+/-3 densitometric units/g tissue). In conclusion, all three isoforms of the SR Ca2+ release channel were determined in the human heart at both mRNA and protein levels with different quantitative expression in the different heart chambers. Coexpression of the three different isoforms with different functional properties might increase the complexity of regulation of excitation contraction coupling in the human heart in a chamber specific mode.