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莱伯遗传性视神经病变中视网膜神经节特异性细胞死亡的机制。

Mechanisms of retinal ganglion specific-cell death in Leber hereditary optic neuropathy.

作者信息

Levin Leonard A

出版信息

Trans Am Ophthalmol Soc. 2007;105:379-91.

PMID:18427623
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2258117/
Abstract

PURPOSE

Leber hereditary optic neuropathy (LHON) results from point mutations in mitochondrial DNA (mtDNA) present in all cells but is only manifested in retinal ganglion cells (RGCs). Given that RGCs use superoxide for intracellular signaling after axotomy, and that LHON mutations increase superoxide levels in non-RGC transmitochondrial cybrids, I hypothesized that RGCs regulate superoxide levels differently than other neuronal cells.

METHODS

Superoxide production in mitochondria isolated from the RGC-5 cell line, rat brain, or neuroblastoma SK-N-AS cells was measured and correlated with levels of mitochondrial electron transport chain (METC) complexes.

RESULTS

The rate of superoxide production in brain mitochondria was more than 5 times the rate in RGC-5 cells when complex I substrates were used. Rotenone significantly increased the rate of superoxide production in brain but not RGC-5 mitochondria. Succinate-dependent superoxide production was similar in brain and RGC-5 mitochondria, but was increased by the complex III inhibitor antimycin A only in brain cells. Neuroblastoma mitochondria demonstrated similar superoxide generation rates as brain cells. Lower rates of superoxide production probably reflected lower levels of METC components.

CONCLUSIONS

These results demonstrate that RGC-5 mitochondria produce superoxide at significantly lower rates than brain mitochondria. Tighter regulation of superoxide levels in RGCs would prevent aberrant apoptosis signaling. LHON mtDNA mutations may interfere with superoxide regulation, possibly leading to aberrant RGC death and consequent optic neuropathy.

摘要

目的

Leber遗传性视神经病变(LHON)由存在于所有细胞中的线粒体DNA(mtDNA)点突变引起,但仅在视网膜神经节细胞(RGC)中表现出来。鉴于RGC在轴突切断后利用超氧化物进行细胞内信号传导,并且LHON突变会增加非RGC转线粒体杂交细胞中的超氧化物水平,我推测RGC调节超氧化物水平的方式与其他神经元细胞不同。

方法

测量从RGC-5细胞系、大鼠脑或神经母细胞瘤SK-N-AS细胞中分离的线粒体中超氧化物的产生,并将其与线粒体电子传递链(METC)复合物的水平相关联。

结果

当使用复合物I底物时,脑线粒体中超氧化物的产生速率是RGC-5细胞中速率的5倍以上。鱼藤酮显著增加了脑线粒体中超氧化物的产生速率,但对RGC-5线粒体没有影响。琥珀酸依赖性超氧化物的产生在脑和RGC-5线粒体中相似,但仅在脑细胞中被复合物III抑制剂抗霉素A增加。神经母细胞瘤线粒体显示出与脑细胞相似的超氧化物产生速率。较低的超氧化物产生速率可能反映了METC成分的较低水平。

结论

这些结果表明,RGC-5线粒体产生超氧化物的速率明显低于脑线粒体。RGC中超氧化物水平的更严格调节将防止异常的凋亡信号传导。LHON mtDNA突变可能会干扰超氧化物调节,可能导致RGC异常死亡并进而导致视神经病变。

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