Relation of Mitochondrial and Cytosolic Free Calcium to Cardiac Myocyte Recovery After Exposure to Anoxia

• Published in: Circulation research Vol. 71; no. 3; pp. 605 - 613
• Main Authors: Miyata, Haruo, Lakatta, Edward G, Stern, Michael D, Silverman, Howard S
• Format: Journal Article
• Language: English
• Published: Hagerstown, MD American Heart Association, Inc 01.09.1992; Lippincott
• Subjects: Animals; Biological and medical sciences; Calcium - metabolism; Cell Hypoxia; Cells, Cultured; Cytosol - metabolism; Fundamental and applied biological sciences. Psychology; Heart; Indoles; Mitochondria, Heart - metabolism; Myocardium - cytology; Myocardium - metabolism; Rats; Vertebrates: cardiovascular system; Heart; Anoxia; Cell organelle; Calcium; Rat; Rodentia; Ions; Cytosol; Myocyte; Vertebrata; Mitochondria; Mammalia; Circulatory system
• ISSN: 0009-7330; 1524-4571
• DOI: 10.1161/01.res.71.3.605

Mitochondrial calcium overload has been suggested as a marker for irreversible injury in the ischemic heart. A new technique is used to measure dynamic changes in mitochondrial free calcium concentration ([Ca]m) in electrically stimulated (0.2 Hz) adult rat cardiac myocytes during exposure to anoxia and reoxygenation. Cells were incubated with indo-1 AM, which distributes in both the cytosol and mitochondria. After Mn quenching of the cytosolic signal, cells were exposed to anoxia, and the residual fluorescence was monitored. [Ca]. averaged 94±3 nM (n=16) at baseline, less than the baseline diastolic cytosolic free calcium concentration ([Ca]c, 124±4 nM, n=12), which was measured in cells loaded with the pentapotassium salt of indo-1. [Ca]m and [Ca]c rose steadily only after the onset of ATP-depletion rigor contracture. At reoxygenation 35 minutes later, [Ca]c fell rapidly to preanoxic levels and then often showed a transient further rise. In contrast, [Ca]m showed only a slight transient fall and a secondary rise at reoxygenation. At reoxygenation, cells immediately either recovered, demonstrating partial relengthening and retaining their rectangular shape and response to stimulation, or they hypercontracted to rounded dysfunctional forms. Recovery occurred only in cells in which [Ca]m or [Ca]c remained below 250 nM before reoxygenation. Early during reoxygenation, [Ca]m remained higher in cells that hypercontracted (305±36 nM) than in cells that recovered (138±9 nM, p<0.05), whereas [Ca]c did not differ between the two groups (156±10 versus 128±10 nM, respectively; p=NS). The role of the sarcoplasmic reticulum in Ca regulation was evaluated in cells (n=16) pretreated with thapsigargin, an inhibitor of the sarcoplasmic reticulum Ca-ATPase. During anoxia [Ca]c and [Ca]m rose as they did without thapsigargin pretreatment. At reoxygenation, the rapid fall in [Ca]c was blunted, and [Ca]m showed an immediate increase in these cells, demonstrating the importance of the sarcoplasmic reticulum in postanoxic Ca regulation. In summary, cellular hypercontracture is not associated with a sudden and massive rise in [Ca]c immediately after reoxygenation. The basis for the relation between [Ca]m and cellular recovery as well as the mechanisms underlying the observed changes in [Ca]m remain to be defined.