Abstract
Hyperosmotic shock induces early calpain activation, Smac/DIABLO release from the mitochondria, and p38/JNK activation in Xenopus oocytes. These pathways regulate late cytochrome c release and caspase-3 activation. Here, we show that JNK1-1 and JNK1-2 are activated early by osmostress, and sustained activation of both isoforms accelerates the apoptotic program. When caspase-3 is activated, JNK1-2 is proteolyzed at Asp-385 increasing the release of cytochrome c and caspase-3 activity, thereby creating a positive feedback loop. Expression of Bcl-xL markedly reduces hyperosmotic shock-induced apoptosis. In contrast, expression of Bid induces rapid caspase-3 activation, even in the absence of osmostress, which is blocked by Bcl-xL co-expression. In these conditions a significant amount of Bid in the cytosol is mono- and bi-ubiquitinated. Caspase-3 activation by hyperosmotic shock induces proteolysis of Bid and mono-ubiquitinated Bid at Asp-52 increasing the release of cytochrome c and caspase-3 activation, and thus creating a second positive feedback loop. Revealing the JNK isoforms and the loops activated by osmostress could help to design better treatments for human diseases caused by perturbations in fluid osmolarity.
Highlights
JNKs regulate osmostress-induced apoptosis in Xenopus oocytes [2], but the isoforms activated have not been characterized
JNK1-1 and JNK1-2 Are Activated by Hyperosmotic Shock—It has been reported that hyperosmotic shock induces rapid activation of two JNK isoforms (p40 and p49) in Xenopus oocytes [1, 2, 28], but these isoforms have not been characterized
These data demonstrate that JNK1-1 and JNK1-2 are activated by hyperosmotic shock and suggest that they might regulate osmostress-induced apoptosis
Summary
Oocyte Isolation and Treatment—Oocytes were obtained from sexually mature X. laevis females (purchased from Centre d’Elevage de Xenopes, Montpellier, France, or from Xenopus Express, Vernassal, France) anesthetized in 0.02% benzocaine, and portions of ovary were removed through a small incision on the abdomen. Oocytes were exposed to hyperosmotic shock by transferring them to a new dish containing MBS with 300 mM sorbitol, collected at different times, and treated as described below. Some oocytes were incubated with drugs dissolved in MBS at the concentrations and times indicated or injected with capped RNAs (cRNAs) and exposed to hyperosmotic shock. Mitochondrial and Cytosolic Fractions—For subcellular fractionation, 30 oocytes were lysed in 300 l of ice-cold extraction buffer, as described previously, and the extract obtained was centrifuged at 1000 ϫ g for 10 min at 4 °C to remove lipids and the yolk. Oocytes were injected with cytochrome c from horse heart (c-7752, Sigma), with or without inhibitors, or DMSO as a solvent control. Values of p Ͻ 0.05 were considered to be statistically significant
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