Changes in cellular Ca2+ and Na+ regulation during the progression towards heart failure in the guinea pig.

KEY POINTS: During compensated hypertrophy in vivo fractional shortening (FS) remains constant until heart failure (HF) develops, when FS decreases from 70% to 39%. Compensated hypertrophy is accompanied by an increase in INa,late and a decrease in Na+ ,K+ -ATPase current. These changes persist as HF develops. SR Ca2+ content increases during compensated hypertrophy then decreases in HF. In healthy cells, increases in SR Ca2+ content and Ca2+ transients can be achieved by the same amount of inhibition of the Na+ ,K+ -ATPase as measured in the diseased cells. SERCA function remains constant during compensated hypertrophy then decreases in HF, when there is also an increase in spark frequency and spark-mediated Ca2+ leak. We suggest an increase in INa,late and a decrease in Na+ ,K+ -ATPase current and function alters the balance of Ca2+ flux mediated by the Na+ /Ca2+ exchange that limits early contractile impairment. ABSTRACT: We followed changes in cardiac myocyte Ca2+ and Na+ regulation from the formation of compensated hypertrophy (CH) until signs of heart failure (HF) are apparent using a trans-aortic pressure overload (TAC) model. In this model, in vivo fractional shortening (FS) remained constant despite HW:BW ratio increasing by 39% (CH) until HF developed 150 days post-TAC when FS decreased from 70% to 39%. Using live and fixed fluorescence imaging and electrophysiological techniques, we found an increase in INa,late from -0.34 to -0.59 A F-1 and a decrease in Na+ ,K+ -ATPase current from 1.09 A F-1 to 0.54 A F-1 during CH. These changes persisted as HF developed (INa,late increased to -0.82 A F-1 and Na+ ,K+ -ATPase current decreased to 0.51 A F-1 ). Sarcoplasmic reticulum (SR) Ca2+ content increased during CH then decreased in HF (from 32 to 15 µm l-1 ) potentially supporting the maintenance of FS in the whole heart and Ca2+ transients in single myocytes during the former stage. We showed using glycoside blockade in healthy myocytes that increases in SR Ca2+ content and Ca2+ transients can be driven by the same amount of inhibition of the Na+ ,K+ -ATPase as measured in the diseased cells. SERCA function remains constant in CH but decreases (τ for SERCA-mediated Ca2+ removal changed from 6.3 to 3.0 s-1 ) in HF. In HF there was an increase in spark frequency and spark-mediated Ca2+ leak. We suggest an increase in INa,late and a decrease in Na+ ,K+ -ATPase current and function alters the balance of Ca2+ flux mediated by the Na+ /Ca2+ exchange that limits early contractile impairment.