Mitochondrial electron transport chain complex III activity is essential for neural differentiation of mouse P19 cell line

Journal of World Mitochondria Society Pub Date : 2016-09-19 DOI:10.18143/JWMS_V2I2_1961

N. Pashkovskaia, Uta Gey, G. Rödel

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Abstract

Besides energy production as their main function mitochondria contribute to diverse regulatory pathways1. For instance, it has been reported that the activity of the mitochondrial electron transport chain (mETC) complexes I and III are essential for cell cycle, apoptosis and stem cell differentiation2–4. In our work, we show that mETC complex III activity is essential for neurogenic differentiation of P19 stem cells. P19 is an embryonic carcinoma mouse cell line that provides a powerful model for neurogenesis5. The efficiency of differentiation was estimated by the appearance of cells with neuron-like morphology and the detection of the neuron-specific marker protein beta-III-tubulin. The role of mETC role in P19 cell differentiation was analysed by including the mETC complex III inhibitors Antimycin A (250 nM) and Myxothiazol (10 nM), respectively, in the differentiation medium. Both Antimycin A and Myxothiazol prevented neurogenic differentiation of P19 cells. Interestingly, the inhibitors did not change the ATP/ADP ratio and hence did not affect energy production, but induced the release of reactive oxygen species (ROS) as estimated by MitoSox staining.

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线粒体电子传递链复合体III活性对小鼠P19细胞系的神经分化至关重要

线粒体除了主要功能是产生能量外，还参与多种调控途径1。例如，据报道线粒体电子传递链(mETC)复合物I和III的活性对细胞周期、凋亡和干细胞分化至关重要2 - 4。在我们的工作中，我们发现mETC复合物III的活性对于P19干细胞的神经源性分化至关重要。P19是一种胚胎癌小鼠细胞系，为神经发生提供了强有力的模型5。分化效率通过神经元样形态细胞的外观和神经元特异性标记蛋白β - iii -微管蛋白的检测来估计。通过在分化培养基中分别加入mETC复合物III抑制剂antiycin A (250 nM)和Myxothiazol (10 nM)，分析mETC在P19细胞分化中的作用。抗霉素A和粘噻唑均能抑制P19细胞的神经源性分化。有趣的是，抑制剂没有改变ATP/ADP的比例，因此不影响能量的产生，但根据MitoSox染色估计，它们会诱导活性氧(ROS)的释放。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of World Mitochondria Society

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