Overproduction of reactive oxygen species (ROS) is one of the major causes of cell death in ischemic reperfusion injury, and, in animal models, electron microscopy has shown mixed apoptotic and necrotic characteristics in the same myocyte (i.e. oncosis). Using time-lapse confocal recording of live cardiomyocytes, I have shown that H2O2 (OH•) causes a marked increase in Na+ and Ca2+ levels in both the cytosol ([Na]cyt, [Ca]cyt) and mitochondria ([Na]m, [Ca]m). The H2O2-induced intracellular Na+ ([Na]i) overload contributes to the H2O2-induced [Ca]cyt/[Ca]m overload via activation of the reverse mode of the Na-Ca exchanger. When myocytes are treated for 40 min with 100 μM H2O2 in normal medium, then returns to H2O2-free medium, the percentage of apoptotic cells increases from 4% at 0 h to 55% and 85% at 4.5 and 16 h, respectively. H2O2-induced apoptosis is completely prevented using Na-free, but not Ca-free, medium. When a Na+ ionophore cocktail in Ca-free medium is used instead of H2O2 to increase the [Na]i by more than 30 mM without any change in the [Ca]i, cytochrome c release and caspase 3-dependent apoptosis occurres, showing that [Na]i overload per se induces apoptosis. I also show that the increase in the mitochondrial, but not the cytosolic, Na+ levels results in the opening of the permeation transition pore, followed by cytochrome c release. These findings therefore suggest that H2O2-induced [Na]m overload is an important upstream signal for the apoptotic machinery. My study further identifies a novel pathway for ROS-induced oncosis in which the apoptotic features are caused by H2O2-induced mitochondrial Na+ ([Na]m) overload, resulting in cytochrome c release and caspase 3 activation, while the necrotic features are caused by PARP activation, resulting in ATP/NAD+ depletion. I also show that opening of novel TRPM2 channels in cardiomyocytes is involved in the H2O2-induced [Na+]m (and [Ca2+]m) overload, since: (i) immunocytochemical studies show that the plasmalemma is labeled by anti-TRPM2 antibody, (ii) the patch-clamp technique shows that Na+ and Ca2+ currents are activated by addition of H2O2 or by inclusion in the pipette solution of either of two specific messengers (β-NAD+ or ADPR), which open the TRPM2 channel, and that the electrophysiological properties induced are very similar, (iii) endogenous NAD+ and ADPR levels are increased by H2O2, while a decrease in their levels inhibits H2O2-induced [Na]i/[Ca]i overload, and (iv) clotrimazole, a putative TRPM2 channel inhibitor, which inhibits the ADPR/TRPM2-induced current, also inhibits the H2O2-induced Na+ overload. Importantly, co-treatment with clotrimazole and DHQ (a PARP inhibitor) nearly completely abolishes the H2O2-induced apoptotic and necrotic processes. These results therefore suggest that activation of both TRPM2 and PARP is involved in the myocyte oncosis. This could be a novel therapeutic target in I/R-induced myocyte loss. It has been shown that arachidonic acid (AA) plays important physiological or pathophysiological roles. In the second part of my study, I have found in cultured rat astrocytes that: (i) endothelin-1 or thapsigargin (Tg) induces store-depleted activated Ca2+ entry (CCE), which is inhibited by 2-aminoethoxydiphenyl borane (2-APB) or La3+; (ii) AA (10 μM) and other unsaturated fatty acids (8,11,14-eicosatrienoic acid and y-linoleic acid) have an initial inhibitory effect on the CCE, due to AA- or fatty acid-induced internal acid load; (iii) after full activation of CCE, AA induces a further Ca2+ influx, which is not inhibited by 2-APB or La3+, indicating that AA activates a second Ca2+ entry pathway, which coexists with CCE; and (iv) Tg or AA activates two independent and co-existing non-selective cation channels and the Tg-induced currents are initially inhibited by addition of AA or weak acids. A possible pathophysiological effect of the AA-induced [Ca]i overload is to cause delayed cell death in astrocytes.