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Fig. 5. Positive inotropic effect of raising extracellular Ca2+. Progressive centripetal propagation of Ca2+ signals promotes contraction of atrial cardiomyocytes. The traces shown were obtained from a single atrial myocyte that was electrically paced and loaded with the Ca2+ indicator fluo3. Ca2+ elevation is denoted by an increase in fluo3 emission. The cell was electrically paced at a constant frequency, just as if it was receiving a regular action potential from the sinoatrial node. To simulate the effect of a positive inotropic agonist, the extracellular Ca2+ concentration was elevated from 1 to 10 mM as indicated. This provides a larger Ca2+ influx signal and ultimately leads to increased SR Ca2+ content, thereby mimicking the effect of ß-adrenergic stimulation (Huser et al., 1996; Mackenzie et al., 2004a), but without changing the phosphorylation status of any of the proteins involved in EC coupling. The inward movement of Ca2+ within the cell was monitored by observing changes in nuclear Ca2+ concentration. Since atrial cell nuclei are centrally positioned, and nuclear Ca2+ derives almost exclusively from the surrounding cytoplasm, they are ideal cellular areas in which the ability of Ca2+ to penetrate into cells can be assessed. The change of extracellular Ca2+ did not affect the amplitude of Ca2+ signals in the sub-sarcolemmal region where EC coupling was initiated, but it caused a progressive increase in Ca2+ signalling in the remainder of the cell, as shown by the increased amplitude of the signals in the nuclear region. Concomitantly with greater inward movement of Ca2+, the cellular contraction was enhanced.
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