Autonomous beating rate adaptation in human stem cell-derived cardiomyocytes.

The therapeutic success of human stem cell-derived cardiomyocytes critically depends on their ability to respond to and integrate with the surrounding electromechanical environment. Currently, the immaturity of human cardiomyocytes derived from stem cells limits their utility for regenerative medicine and biological research. We hypothesize that biomimetic electrical signals regulate the intrinsic beating properties of cardiomyocytes.

Ca2+-activated adenylyl cyclase 1 introduces Ca2+-dependence to beta-adrenergic stimulation of HCN2 current.

Previous observations show that β-adrenergic modulation of pacemaker current (I(f)) in sinoatrial node (SAN) cells is impaired by disruption of normal Ca(2+)-homeostasis with ryanodine or BAPTA. Recently, the presence of Ca(2+)-activated adenylyl cyclase (AC) 1 was reported in SAN, and was proposed as a possible mechanism of Ca(2+)-dependence of β-adrenergic modulation. However, direct evidence that pacemaker (HCN) channels can be regulated by Ca(2+)-activated AC and that such regulation introduces Ca(2+) dependence, is lacking.

Age-dependent changes in Na current magnitude and TTX-sensitivity in the canine sinoatrial node.

In rabbit, sodium current (I(Na)) contributes to newborn sinoatrial node (SAN) automaticity but is absent in adult SAN, where heart rate is slower. In contrast, heart rate is high and I(Na) is functional in adult mouse SAN. Given the slower heart rates of large mammals, we asked if I(Na) is functionally active in SAN of newborn or adult canine heart.

Expression of skeletal but not cardiac Na+ channel isoform preserves normal conduction in a depolarized cardiac syncytium.

Aims: Reentrant arrhythmias often develop in the setting of myocardial infarction and ensuing slow propagation. Increased Na(+) channel expression could prevent or disrupt reentrant circuits by speeding conduction if channel availability is not limited by membrane depolarization within the diseased myocardium. We therefore asked if, in the setting of membrane depolarization, action potential (AP) upstroke and normal conduction can be better preserved by the expression of a Na(+) channel isoform with altered biophysical properties compared to the native cardiac Na(+) channel isoform, namely having a positively shifted, voltage-dependent inactivation.