Iron overload decreases CaV1.3-dependent L-type Ca2+ currents leading to bradycardia, altered electrical conduction, and atrial fibrillation.

Background— Chronic iron overload (CIO) is associated with blood disorders such as thalassemias and hemochromatosis. A major prognostic indicator of survival in patients with CIO is iron-mediated cardiomyopathy characterized by contractile dysfunction and electrical disturbances, including slow heart rate (bradycardia) and heart block. Methods and Results— We used a mouse model of CIO to investigate the effects of iron on sinoatrial node (SAN) function. As in humans, CIO reduced heart rate (≈20%) in conscious mice as well as in anesthetized mice with autonomic nervous system blockade and in isolated Langendorff-perfused mouse hearts, suggesting that bradycardia originates from altered intrinsic SAN pacemaker function. Indeed, spontaneous action potential frequencies in SAN myocytes with CIO were reduced in association with decreased L-type Ca2+ current (ICa,L) densities and positive (rightward) voltage shifts in ICa,L activation. Pacemaker current (If) was not affected by CIO. Because ICa,L in SAN myocytes (as well as in atrial and conducting system myocytes) activates at relatively negative potentials due to the presence of CaV1.3 channels (in addition to CaV1.2 channels), our data suggest that elevated iron preferentially suppresses CaV1.3 channel function. Consistent with this suggestion, CIO reduced CaV1.3 mRNA levels by ≈40% in atrial tissue (containing SAN) and did not lower heart rate in CaV1.3 knockout mice. CIO also induced PR-interval prolongation, heart block, and atrial fibrillation, conditions also seen in CaV1.3 knockout mice. Conclusions— Our results demonstrate that CIO selectively reduces CaV1.3-mediated ICa,L, leading to bradycardia, slowing of electrical conduction, and atrial fibrillation as seen in patients with iron overload.