Kugelman A, Choy H A, Liu R, Shi M M, Gozal E, Forman H J
Department of Pediatrics, Childrens Hospital Los Angeles, California.
Am J Respir Cell Mol Biol. 1994 Nov;11(5):586-92. doi: 10.1165/ajrcmb.11.5.7946387.
The tripeptide glutathione (GSH) is used by cells to detoxify hydroperoxides, produced during oxidative stress, and is consumed in the process. Previous studies have indicated that cells can be protected against oxidative stress by extracellular GSH through its degradation catalyzed by the exoenzyme gamma-glutamyl transpeptidase (gamma GT) and its de novo synthesis within the cytosol. We hypothesized that gamma GT would be increased as part of the adaptation of cells to oxidative stress. We examined whether oxidative stress could increase gamma GT activity, protein, and mRNA in a lung epithelial cell line (L2). Cultures were subjected to H2O2-mediated toxicity by 15 min of exposure to the redox cycling quinone, menadione. Menadione (50 microM) caused an initial decrease (27 +/- 9% of baseline after 15 min) in intracellular GSH, followed by resynthesis to levels significantly higher than baseline (335 +/- 40% after 24 h, P < 0.001). This elevation was prevented by acivicin, a gamma GT inhibitor. Menadione also caused a dose-dependent increase in gamma GT enzymatic activity (715 +/- 125% of control at 24 h after 15 min of exposure to 100 microM menadione, P < 0.001) that was prevented by actinomycin D. Western blot analysis indicated increased levels of gamma GT protein with increasing menadione. A concentration-dependent increase in gamma GT-mRNA was also observed. Previous investigation has demonstrated that an increase in gamma GT activity enhances the capacity of cells to utilize extracellular GSH. The findings presented here are consistent with a role for gamma GT in cellular adaptation to oxidative stress.
三肽谷胱甘肽(GSH)被细胞用于清除氧化应激过程中产生的氢过氧化物,且在此过程中被消耗。先前的研究表明,细胞可通过细胞外GSH得到保护,免受氧化应激影响,这一过程由胞外酶γ-谷氨酰转肽酶(γGT)催化其降解,并在胞质溶胶中重新合成。我们推测,γGT会作为细胞适应氧化应激的一部分而增加。我们研究了氧化应激是否会增加肺上皮细胞系(L2)中γGT的活性、蛋白质和mRNA水平。通过将培养物暴露于氧化还原循环醌甲萘醌15分钟,使其受到H2O2介导的毒性作用。甲萘醌(50μM)使细胞内GSH最初降低(15分钟后降至基线的27±9%),随后重新合成至显著高于基线的水平(24小时后为335±40%,P<0.001)。γGT抑制剂阿西维辛可阻止这种升高。甲萘醌还导致γGT酶活性呈剂量依赖性增加(暴露于100μM甲萘醌15分钟后24小时,为对照的715±125%,P<0.001),放线菌素D可阻止这种增加。蛋白质印迹分析表明,随着甲萘醌浓度增加,γGT蛋白水平升高。还观察到γGT-mRNA呈浓度依赖性增加。先前的研究表明,γGT活性增加可增强细胞利用细胞外GSH的能力。此处呈现的研究结果与γGT在细胞适应氧化应激中的作用一致。
