Kuperstein Faina, Yavin Ephraim
Department of Neurobiology, The Weizmann Institute of Science, Rehovot, Israel.
Eur J Neurosci. 2002 Jul;16(1):44-54. doi: 10.1046/j.1460-9568.2002.02056.x.
Oxidative stress in the human brain has been strongly implicated as the cause of neuronal cell losses in Alzheimer's disease patients, but the exact mechanism still remains unknown. In this report several oxidative stress parameters and an associated signalling transduction cascade predating neuronal cell death in cultures treated with the oxidative stressors Fe(2+) (5 microm) and the amyloid beta (A beta(1-40)) peptide (5 microm) were studied. Production of reactive oxygen species as detected by dichlorofluorescein staining was apparent within 5 min in the presence of both agents. Lipid peroxide content increased by approximately 10-fold after 2 h, while mitochondrial activity was impaired by 40% after 6 h. Caspase-3 activity was elevated 5-6 fold, all indicative of oxidative cell stress. The combined presence of A beta(1-40) and Fe(2+) resulted in a rapid (5 min) ERK activation followed by a decline by 30 min and a second activation that continued up to 24 h when nuclear translocation was noticed. Neither treatment with Fe(2+) nor that with A beta(1-40) alone caused similar changes. Addition of either deferroxamine (DFe, 25 microm), catalase (0.4 mg/mL) or N-acetyl cysteine (0.5 mm) - the last two known as suppressants of oxidative stress - attenuated ERK activation and nuclear translocation. The mitogen-activated protein/ERK kinase (MEK) inhibitor U0126 blocked ERK and caspase 3 activation, suppressed ERK translocation and reduced the number of apoptotic cells, suggesting a central role for the ERK signalling cascade in A beta(1-40) plus Fe(2+) (A beta(1-40)/Fe(2+)) -induced apoptotic death. The full peptide A beta(1-42) was very effective at 0.5 microm while the inverse peptide A beta(40-1) at 5 microm was ineffective. The acetyl-amyloid-beta protein amide fragment 15-20 (V-pep) known to be an A beta aggregation inhibitor, prevented A beta(1-40)/Fe(2+)-induced toxicity. These findings indicate that metal ions chelators and antioxidants suppress the A beta(1-40)/Fe(2+)-induced oxidative stress cascade and may be beneficial in reducing the severity of Alzheimer's disease.
氧化应激被强烈认为是阿尔茨海默病患者神经元细胞损失的原因,但确切机制仍不清楚。在本报告中,研究了在用氧化应激剂Fe(2+)(5微摩尔)和淀粉样β肽(Aβ(1-40))(5微摩尔)处理的培养物中,几种氧化应激参数以及在神经元细胞死亡之前的相关信号转导级联反应。在两种试剂存在的情况下,二氯荧光素染色检测到的活性氧产生在5分钟内就很明显。2小时后脂质过氧化物含量增加了约10倍,而6小时后线粒体活性受损40%。半胱天冬酶-3活性升高了5-6倍,所有这些都表明存在氧化细胞应激。Aβ(1-40)和Fe(2+)共同存在导致快速(5分钟)的细胞外信号调节激酶(ERK)激活,随后在30分钟时下降,第二次激活持续到24小时,此时观察到核转位。单独用Fe(2+)或Aβ(1-40)处理均未引起类似变化。添加去铁胺(DFe,25微摩尔)、过氧化氢酶(0.4毫克/毫升)或N-乙酰半胱氨酸(0.5毫摩尔)-后两者是已知的氧化应激抑制剂-可减弱ERK激活和核转位。丝裂原活化蛋白/ERK激酶(MEK)抑制剂U0126阻断ERK和半胱天冬酶3激活,抑制ERK转位并减少凋亡细胞数量,表明ERK信号级联在Aβ(1-40)加Fe(2+)(Aβ(1-40)/Fe(2+))诱导的凋亡死亡中起核心作用。全长肽Aβ(1-42)在0.5微摩尔时非常有效,而反向肽Aβ(40-1)在5微摩尔时无效。已知作为Aβ聚集抑制剂的乙酰化淀粉样β蛋白酰胺片段15-20(V-肽)可预防Aβ(1-40)/Fe(2+)诱导的毒性。这些发现表明金属离子螯合剂和抗氧化剂可抑制Aβ(1-40)/Fe(2+)诱导的氧化应激级联反应,可能有助于减轻阿尔茨海默病的严重程度。
