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Investigate the effect of mitochondrial energy state on Ca2+ sparks and handling

$248,292R00FY2011HLNIH

University Of Alabama At Birmingham, Birmingham AL

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Abstract

Heart disease is the single largest killer of the American. A growing body of evidence has shown that there is a close relationship between Ca2+ handling abnormalities and development of heart disease. Therefore it is fundamentally important to understand the regulation of Ca2+ signaling under pathological conditions. Local control of Ca2+-induced Ca2+ release (CICR) depends on the spatial organization of L-type Ca2+ channels and ryanodine receptors (RyR) in the dyad. Analogously, Ca2+ uptake by mitochondria is facilitated by their close proximity to the Ca2+ release sites, a process required for stimulating oxidative phosphorylation during changes in work. Mitochondrial feedback on CICR, however, is less well understood. Since mitochondria are a primary source of reactive oxygen species (ROS), they could potentially influence the cytosolic redox state, in turn altering RyR open probability. In this proposed study, a two photon laser microscope system will be used to directly examine how acute changes in energy state dynamically influence Ca2+ spark properties under various experimental conditions. Cytosolic Ca2+ (or ROS), A^m, and NADH will be recorded simultaneously in isolated guinea pig cardiomyocytes and analyzed offline using imaged. The spatiotemporal coupling between mitochondria! depolarization and Ca2+ sparks will be analyzed using a quantitative approach. Furthermore, a computational model of mitochondria and Ca2+ release unit will be developed to quantitatively investigate the interaction between mitochondrial energetics and local Ca2+ handling. Finally, an integrated model of the cardiomyocyte incorporating substrate metabolism, cellular electrophysiology, pH regulation and E-C coupling will be developed to investigate the mechanisms underlying alterations in energy production, ion channels, Ca2+ handling and pH, as well as the resulting reduction of cardiac contractile function during ischemia-reperfusion. By combining the experimental and computational results, these studies will allow for a complete understanding the origin of post-ischemic injury and development of heart failure, and significantly spur the development of novel heart disease therapies.

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