Saitoh Yasukazu, Ouchida Rika, Miwa Nobuhiko
Division of Cell Biochemistry, Hiroshima Prefectural University School of BioSciences, Shobara, Hiroshima 727-0023, Japan.
J Cell Biochem. 2003 Dec 1;90(5):914-24. doi: 10.1002/jcb.10723.
The function of bcl-2 in preventing cell death is well known, but the mechanisms whereby bcl-2 functions are not well characterized. One mechanism whereby bcl-2 is thought to function is by alleviating the effects of oxidative stress upon the cell. To examine whether Bcl-2 can protect cells against oxidative injury resulting from post-hypoxic reoxygenation (H/R), we subjected rat fibroblasts Rat-1 and their bcl-2 transfectants b5 to hypoxia (5% CO2, 95% N2) followed by reoxygenation (5% CO2, 95% air). The bcl-2 transfectants exhibited the cell viability superior to that of their parent non-transfectants upon treatment with reoxygenation after 24-, 48-, or 72-h hypoxia, but not upon normoxic serum-deprivation or upon serum-supplied hypoxic treatment alone. Thus bcl-2 transfection can prevent cell death of some types, which occurred during H/R but yet not appreciably until termination of hypoxia. The time-sequential events of H/R-induced cell death were shown to be executed via (1) reactive oxygen species (ROS) production at 1-12 h after H/R, (2) activation of caspases-1 and -3, at 1-3 h and 3-6 h after H/R, respectively, and (3) loss of mitochondrial membrane potential (DeltaPsi) at 3-12 h after H/R. These cell death-associated events were prevented entirely except caspase-1 activation by bcl-2 transfection, and were preceded by Bcl-2 upregulation which was executed as early as at 0-1 h after H/R for the bcl-2 transfectants but not their non-transfected counterpart cells. Thus upregulation of Bcl-2 proteins may play a role in prevention of H/R-induced diminishment of cell viability, but may be executed not yet during hypoxia itself and be actually operated as promptly as ready to go immediately after beginning of H/R, resulting in cytoprotection through blockage of either ROS generation, caspase-3 activation, or DeltaPsi decline.
bcl-2在预防细胞死亡中的作用已广为人知,但其发挥作用的机制尚未完全明确。一种认为bcl-2发挥作用的机制是减轻氧化应激对细胞的影响。为了研究Bcl-2是否能保护细胞免受缺氧后复氧(H/R)所致的氧化损伤,我们将大鼠成纤维细胞Rat-1及其bcl-2转染细胞b5置于缺氧环境(5% CO₂,95% N₂),随后进行复氧(5% CO₂,95%空气)。在缺氧24、48或72小时后进行复氧处理时,bcl-2转染细胞的细胞活力优于其未转染的亲本细胞,但在常氧血清剥夺或仅进行血清供应的缺氧处理时则不然。因此,bcl-2转染可预防某些类型的细胞死亡,这些细胞死亡发生在H/R过程中,但直到缺氧结束才明显出现。H/R诱导的细胞死亡的时间顺序事件显示为:(1)H/R后1 - 12小时产生活性氧(ROS);(2)分别在H/R后1 - 3小时和3 - 6小时激活半胱天冬酶-1和-3;(3)H/R后3 - 12小时线粒体膜电位(ΔΨ)丧失。除了半胱天冬酶-1激活外,这些与细胞死亡相关的事件通过bcl-2转染被完全阻止,并且在bcl-2转染细胞中,Bcl-2上调早在H/R后0 - 1小时就开始执行,而其未转染的对应细胞则不然。因此,Bcl-2蛋白的上调可能在预防H/R诱导的细胞活力降低中起作用,但可能在缺氧期间尚未执行,实际上在H/R开始后立即准备就绪时迅速发挥作用,通过阻断ROS生成、半胱天冬酶-3激活或ΔΨ下降实现细胞保护。
