No direct effect of creatine phosphate on the cross-bridge cycle in cardiac myofibrils.

Creatine phosphate (CP) and creatine kinase (CK) are involved in the rapid resynthesis of ATP and thereby serve to stabilize ATP concentration and to maintain free ADP low inside cardiac muscle cells during contraction. Recently, it has been suggested from experiments in permeabilized multicellular preparations that CP/CK also regulate the kinetics of the actomyosin interaction (cross-bridge cycle) and may explain contractile dysfunction, for instance, during ischemia. However, the reported effects of CP/CK may be confounded by diffusion limitations in multicellular preparations in which inorganic phosphate (P(i)) and ADP may significantly accumulate during contraction. To test this hypothesis, we measured force production and the rates of force development (k (ACT) and k (TR)) in isolated cardiac myofibrils, in which rapid concentration changes of Ca(2+), CP/CK, and P(i) were imposed using a rapid perfusion change system. The results showed that CP/CK did not influence maximum force-generating capacity, whereas P(i) markedly reduced force and increased the rates of force development. No effects of CP/CK on the rates of force development were observed, consistent with the notion that CP/CK do not exert a direct effect on the actomyosin interaction.

Mechanism of cross-bridge detachment in isometric force relaxation of skeletal and cardiac myofibrils.

Skeletal and cardiac muscle relaxation is governed by the interplay between two macromolecular systems: (i) membrane bound Ca2+ transport proteins and (ii) sarcomeric proteins. Photolysis experiments in skinned muscle preparations and fast solution switching studies in single myofibrils offer means for isolating sarcomeric mechanisms of relaxation from those related to myoplasmic Ca2+ removal. Single myofibril experiments have recently shown that cross-bridge mechanics and detachment kinetics are the major determinants of the time course of relaxation. Full force decay in myofibrils occurs in two phases: a slow one followed by a rapid one. The latter is initiated by sarcomere 'give' and dominated by inter-sarcomere dynamics while the former occurs under nearly isometric conditions. Strong evidence has been found that the slow rate of force decay in myofibril relaxation reflects the rate at which cross-bridges leave force-generating states under isometric conditions. Dissection of chemo-mechanical transduction process in myofibrils indicates that both forward and backward transitions of cross-bridges from force-generating to non-force-generating states contribute to muscle relaxation.

Do stretch-induced changes in intracellular calcium modify the electrical activity of cardiac muscle?

Stretch of the myocardium influences the shape and amplitude of the intracellular Ca(2+)([Ca(2+)](i)) transient. Under isometric conditions stretch immediately increases myofilament Ca(2+) sensitivity, increasing force production and abbreviating the time course of the [Ca(2+)](i) transient (the rapid response). Conversely, muscle shortening can prolong the Ca(2+) transient by decreasing myofilament Ca(2+) sensitivity. During the cardiac cycle, increased ventricular dilation may increase myofilament Ca(2+) sensitivity during diastolic filling and the isovolumic phase of systole, but enhance the decrease in myofilament Ca(2+) sensitivity during the systolic shortening of the ejection phase. If stretch is maintained there is a gradual increase in the amplitude of the Ca(2+) transient and force production, which takes several minutes to develop fully (the slow response). The rapid and slow responses have been reported in whole hearts and single myocytes. Here we review stretch-induced changes in [Ca(2+)](i) and the underlying mechanisms. Myocardial stretch also modifies electrical activity and the opening of stretch-activated channels (SACs) is often used to explain this effect. However, the myocardium has many ionic currents that are regulated by [Ca(2+)](i) and in this review we discuss how stretch-induced changes in [Ca(2+)](i) can influence electrical activity via the modulation of these Ca(2+)-dependent currents. Our recent work in single ventricular myocytes has shown that axial stretch prolongs the action potential. This effect is sensitive to either SAC blockade by streptomycin or the buffering of [Ca(2+)](i) with BAPTA, suggesting that both SACs and [Ca(2+)](i) are important for the full effects of axial stretch on electrical activity to develop.

Effect of chronic hypoxia on agonist-induced tone and calcium signaling in rat pulmonary artery.

The effect of chronic hypoxia (CH) for 14 days on Ca2+ signaling and contraction induced by agonists in the rat main pulmonary artery (MPA) was investigated. In MPA myocytes obtained from control (normoxic) rats, endothelin (ET)-1, angiotensin II (ANG II), and ATP induced oscillations in intracellular Ca2+ concentration ([Ca2+]i) in 85-90% of cells, whereas they disappeared in myocytes from chronically hypoxic rats together with a decrease in the percentage of responding cells. However, both the amount of mobilized Ca2+ and the sources of Ca2+ implicated in the agonist-induced response were not changed. Analysis of the transient caffeine-induced [Ca2+]i response revealed that recovery of the resting [Ca2+]i value was delayed in myocytes from chronically hypoxic rats. The maximal contraction induced by ET-1 or ANG II in MPA rings from chronically hypoxic rats was decreased by 30% compared with control values. Moreover, the D-600- and thapsigargin-resistant component of contraction was decreased by 40% in chronically hypoxic rats. These data indicate that CH alters pulmonary arterial reactivity as a consequence of an effect on both Ca2+ signaling and Ca2+ sensitivity of the contractile apparatus. A Ca2+ reuptake mechanism appears as a CH-sensitive phenomenon that may account for the main effect of CH on Ca2+ signaling.

Effects of antibiotics on the contractility and Ca2+ transients of rat cardiac myocytes.

We have compared the effects of streptomycin sulphate, gentamicin sulphate and neomycin sulphate on cell shortening (our index of contractility) and intracellular Ca2+ ([Ca2+](i)) transients of rat ventricular myocytes. All three agents abolished shortening and [Ca2+](i), transients but streptomycin was significantly less potent than the other agents. The IC(50) of streptomycin was 0.37 mM for shortening and 0.78 mM for [Ca2+](i), approximately an order of magnitude greater than equivalent values for gentamicin and neomycin. Gentamicin and streptomycin shortened the action potential duration of most cells but prolonged the action potential duration of others. We therefore conclude that multiple ionic mechanisms affecting action potential duration are modulated by these antibiotics. Our observations are consistent with the negative inotropic effect of antibiotics being caused by a decrease in Ca2+ influx causing a reduction in the [Ca2+](i) transient.