癌细胞中的一碳代谢：基于中心代谢核心模型的重要综述。

One-carbon metabolism in cancer cells: a critical review based on a core model of central metabolism.

机构信息

IBGC CNRS UMR 5095 and Université de Bordeaux, 1, rue Camille Saint-Saëns, 33077 BORDEAUX-cedex, France.

出版信息

Biochem Soc Trans. 2021 Feb 26;49(1):1-15. doi: 10.1042/BST20190008.

DOI:10.1042/BST20190008

Abstract

One-carbon metabolism (1C-metabolism), also called folate metabolism because the carbon group is attached to folate-derived tetrahydrofolate, is crucial in metabolism. It is at the heart of several essential syntheses, particularly those of purine and thymidylate. After a short reminder of the organization of 1C-metabolism, I list its salient features as reported in the literature. Then, using flux balance analysis, a core model of central metabolism and the flux constraints for an 'average cancer cell metabolism', I explore the fundamentals underlying 1C-metabolism and its relationships with the rest of metabolism. Some unreported properties of 1C-metabolism emerge, such as its potential roles in mitochondrial NADH exchange with cytosolic NADPH, participation in NADH recycling, and optimization of cell proliferation.

摘要

一碳代谢（1C-metabolism），也称为叶酸代谢，因为碳原子连接在叶酸衍生的四氢叶酸上，在代谢中至关重要。它是几种必需合成物的核心，特别是嘌呤和胸苷酸的合成。在简短提醒 1C 代谢的组织之后，我列出了文献中报道的其显著特征。然后，使用通量平衡分析，一种中心代谢的核心模型和“普通癌细胞代谢”的通量限制，我探讨了 1C 代谢的基础及其与代谢其他部分的关系。出现了一些未报告的 1C 代谢特性，例如它在与胞质 NADPH 的线粒体 NADH 交换、参与 NADH 循环和优化细胞增殖中的潜在作用。

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癌细胞中的一碳代谢：基于中心代谢核心模型的重要综述。

One-carbon metabolism in cancer cells: a critical review based on a core model of central metabolism.

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