S. Fernández-Arroyo, E. Cuyás, J. Bosch-Barrera, T. Alarcón, J. Joven, J. Menéndez
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引用次数: 28
Abstract
Generation of induced pluripotent stem (iPS) cells and cancer biogenesis share similar metabolic switches. Most studies have focused on how the establishment of a cancer-like glycolytic phenotype is necessary for the optimal routing of somatic cells for achieving stemness. However, relatively little effort has been dedicated towards elucidating how one-carbon (1C) metabolism is retuned during acquisition of stem cell identity. Here we used ultra-high pressure liquid chromatography coupled to an electrospray ionization source and a triple-quadrupole mass spectrometer [UHPLC-ESI-QqQ-MS/MS] to quantitatively examine the methionine/folate bi-cyclic 1C metabolome during nuclear reprogramming of somatic cells into iPS cells. iPS cells optimize the synthesis of the universal methyl donor S-adenosylmethionine (SAM), apparently augment the ability of the redox balance regulator NADPH in SAM biosynthesis, and greatly increase their methylation potential by triggering a high SAM:S-adenosylhomocysteine (SAH) ratio. Activation of the methylation cycle in iPS cells efficiently prevents the elevation of homocysteine (Hcy), which could alter global DNA methylation and induce mitochondrial toxicity, oxidative stress and inflammation. In this regard, the methyl donor choline is also strikingly accumulated in iPS cells, suggesting perhaps an overactive intersection of the de novo synthesis of choline with the methionine-Hcy cycle. Activation of methylogenesis and maintenance of an optimal SAM:Hcy ratio might represent an essential function of 1C metabolism to provide a labile pool of methyl groups and NADPH-dependent redox products required for successfully establishing and maintaining an embryonic-like DNA methylation imprint in stem cell states.
诱导多能干细胞(iPS)的产生和癌症生物发生具有相似的代谢开关。大多数研究都集中在癌症样糖酵解表型的建立对于实现干细胞的最佳路径是必要的。然而,很少有人致力于阐明在干细胞身份获得过程中如何恢复一碳(1C)代谢。本文采用超高压液相色谱耦合电喷雾电离源和三重四极杆质谱仪[UHPLC-ESI-QqQ-MS/MS]定量检测体细胞核重编程为iPS细胞过程中蛋氨酸/叶酸双环1C代谢组。iPS细胞优化了通用甲基供体s -腺苷蛋氨酸(SAM)的合成,明显增强了氧化还原平衡调节因子NADPH在SAM生物合成中的能力,并通过触发高SAM: s -腺苷同型半胱氨酸(SAH)比例大大增加了它们的甲基化电位。激活iPS细胞的甲基化周期可以有效地阻止同型半胱氨酸(Hcy)的升高,后者可能改变整体DNA甲基化并诱导线粒体毒性、氧化应激和炎症。在这方面,甲基供体胆碱也显著地积累在iPS细胞中,这可能表明胆碱的重新合成与蛋氨酸- hcy循环的过度活跃交叉。甲基化发生的激活和最佳SAM:Hcy比率的维持可能是1C代谢的基本功能,它提供了一个稳定的甲基库和nadph依赖的氧化还原产物,这是成功建立和维持干细胞状态下胚胎样DNA甲基化印记所必需的。