Department of Neuroscience, University of Connecticut Health Center, Farmington, 06030, USA.
Acta Physiol (Oxf). 2011 Sep;203(1):225-34. doi: 10.1111/j.1748-1716.2010.02229.x. Epub 2011 Jan 19.
Multiple cell death pathways are activated in cerebral ischaemia. Much of the initial injury, especially in the core of the infarct where cerebral blood flow is severely reduced, is necrotic and secondary to severe energy failure. However, there is considerable evidence that delayed cell death continues for several days, primarily in the penumbral region. As reperfusion therapies grow in number and effectiveness, restoration of blood flow early after injury may lead to a shift towards apoptosis. It is important to elucidate what are the key mediators of apoptotic cell death after stroke, as inhibition of apoptosis may have therapeutic implications. There are two well described pathways that lead to apoptotic cell death; the caspase pathway and the more recently described caspase-independent pathway triggered by poly-ADP-ribose polymers (PARP) activation. Caspase-induced cell death is initiated by release of mitochondrial cytochrome c, formation of the cytosolic apoptosome, and activation of endonucleases leading to a multitude of small randomly cleaved DNA fragments. In contrast caspase-independent cell death is secondary to activation of apoptosis inducing factor (AIF). Mitochondrial AIF translocates to the nucleus, where it induces peripheral chromatin condensation, as well as characteristic high-molecular-weight (50 kbp) DNA fragmentation. Although caspase-independent cell death has been recognized for some time and is known to contribute to ischaemic injury, the upstream triggering events leading to activation of this pathway remain unclear. The two major theories are that ischaemia leads to nicotinamide adenine dinucleotide (NAD+) depletion and subsequent energy failure, or alternatively that cell death is directly triggered by a pro-apoptotic factor produced by activation of the DNA repair enzyme PARP. PARP activation is robust in the ischaemic brain producing variable lengths of poly-ADP-ribose (PAR) polymers as byproducts of PARP activation. PAR polymers may be directly toxic by triggering mitochondrial AIF release independently of NAD+ depletion. Recently, sex differences have been discovered that illustrate the importance of understanding these molecular pathways, especially as new therapeutics targeting apoptotic cell death are developed. Cell death in females proceeds primarily via caspase activation whereas caspase-independent mechanisms triggered by the activation of PARP predominate in the male brain. This review summarizes the current literature in an attempt to clarify the roles of NAD+ and PAR polymers in caspase-independent cell death, and discuss sex specific cell death to provide an example of the possible importance of these downstream mediators.
脑缺血会激活多种细胞死亡途径。最初的损伤,特别是在脑血流严重减少的梗死核心区,主要是坏死的,是由于严重的能量衰竭引起的。然而,有大量证据表明,延迟性细胞死亡会持续数天,主要发生在半影区。随着再灌注治疗的数量和效果的增加,损伤后早期恢复血流可能会导致细胞凋亡的转变。阐明中风后细胞凋亡的关键介质是什么很重要,因为抑制细胞凋亡可能具有治疗意义。有两种已被充分描述的途径会导致细胞凋亡; caspase 途径和最近描述的 caspase 非依赖性途径,该途径由聚 ADP-核糖聚合酶 (PARP) 激活触发。caspase 诱导的细胞死亡是由线粒体细胞色素 c 的释放、细胞质凋亡小体的形成以及导致大量随机小片段 DNA 片段的内切酶的激活引发的。相比之下,caspase 非依赖性细胞死亡是凋亡诱导因子 (AIF) 激活的结果。线粒体 AIF 易位到细胞核,在那里它诱导周边染色质浓缩,以及特征性的高分子量(50 kbp)DNA 片段化。虽然 caspase 非依赖性细胞死亡已经被认识了一段时间,并且已知会导致缺血性损伤,但导致该途径激活的上游触发事件仍不清楚。两个主要理论是,缺血导致烟酰胺腺嘌呤二核苷酸 (NAD+) 耗竭,随后能量衰竭,或者细胞死亡直接由 DNA 修复酶 PARP 激活产生的促凋亡因子触发。PARP 的激活在缺血性大脑中非常强烈,产生不同长度的聚 ADP-核糖 (PAR) 聚合物作为 PARP 激活的副产物。PAR 聚合物可能通过触发线粒体 AIF 释放而不依赖于 NAD+ 耗竭而直接产生毒性。最近,发现了性别差异,这说明了理解这些分子途径的重要性,特别是随着针对细胞凋亡的新治疗方法的发展。女性的细胞死亡主要通过 caspase 激活进行,而男性大脑中主要通过 PARP 激活触发的 caspase 非依赖性机制进行。这篇综述总结了目前的文献,试图阐明 NAD+和 PAR 聚合物在 caspase 非依赖性细胞死亡中的作用,并讨论性别特异性细胞死亡,以提供这些下游介质可能重要性的一个例子。
