Changes in calcium cycling precede cardiac dysfunction during autoimmune myocarditis in mice.

Myocardial inflammation contributes to the development of dilated cardiomyopathy, as well as other cardiac diseases. We have previously shown decreased left ventricular function in mice with autoimmune myocarditis. To test the hypothesis that decreased function is mediated by changes in contractility and/or Ca2+ cycling, we isolated cardiac myocytes from mice with myocarditis and age-matched controls at two time points: day 18 (prior to cardiac dysfunction) and day 35 (during cardiac dysfunction). We measured cell shortening and the Ca2+ transient simultaneously at 28 degrees C and 0.3 Hz. We also quantified proteins which regulate contractility and [Ca2+](i), using Western blot analysis. Results showed no change in cell shortening or systolic Ca2+ on day 18, despite a significant reduction in diastolic Ca2+. By day 35, the decrease in diastolic Ca2+ was accompanied by significantly reduced cell shortening and a decrease in the systolic Ca2+ transient. Protein levels of the sarcoplasmic reticulum Ca2+ ATPase were unchanged at both time points, while phospholamban and the sodium/calcium exchanger were significantly reduced in myosin-immunized mice at both time points. Calsequestrin was unchanged at day 18, but was significantly reduced in the myosin-immunized mice on day 35. Results of this study suggest that decreased diastolic Ca2+, as well as protein levels of phospholamban and the sodium/calcium exchanger, may actually contribute to disease progression in autoimmune myocarditis, while changes in calsequestrin may be related to systolic dysfunction in this model.

Immunolocalization of annexins IV, V and VI in the failing and non-failing human heart.

UNLABELLED: The failing human heart is characterized by changes in the expression and function of proteins involved in intracellular Ca2+ cycling, resulting in altered Ca2+ transients and impaired contractile properties of cardiac muscle. The role of the cardiac annexins in this process remains unclear. Annexins may play a role in the regulation of Ca2+ pumps and exchangers on the sarcolemma, and have been shown to be altered in some cardiac disease states. OBJECTIVE: The goal of this study was to compare the immunolocalization and expression of annexins IV, V and VI in failing and non-failing human hearts. METHODS: We used immunostaining to identify the subcellular location of annexins IV, V and VI proteins within the myocardial cell, and Western blot analysis to quantify the proteins in the same hearts. RESULTS: Annexin IV showed a cytoplasmic distribution in both failing and non-failing human heart cells. Annexin V was localized at the z-line, around lipofuscin granules, and in the cytosol in the non-failing heart cells. Annexin VI was localized at the sarcolemma and intercalated disc. Protein levels of annexins IV and V were up-regulated in failing human hearts, while the expression of annexin VI was unchanged. CONCLUSIONS: Alterations in the intracellular localization of annexins, along with up-regulation of annexins IV and V in the failing human heart cells, suggests differential regulation of these Ca2+ regulatory proteins during heart failure.

Na-pump activity in rat kidney cortex cells and its relationship with the cell volume.

The present work was undertaken to evaluate whether changes in cell water content of rat kidney cortex cells can modulate the transport activity of the ouabain-insensitive Na pump as they modulate the ouabain-insensitive Na+-ATPase. It was found that there is a close relationship between the cell volume and activity of the Na pump, whereas Na,K-pump activity is not affected by variations in cell volume. When the cell water content is low, Na-pump activity (Na+ transport and Na+-ATPase activity) is minimal. Increases in cell water content produce a concomitant increase in Na-pump activity.