时变通量组学揭示了整个哺乳动物细胞周期中 TCA 循环通量的振荡。
Temporal fluxomics reveals oscillations in TCA cycle flux throughout the mammalian cell cycle.
机构信息
Department of Computer Science, Technion, Haifa, Israel.
Department of Biology, Technion, Haifa, Israel.
出版信息
Mol Syst Biol. 2017 Nov 6;13(11):953. doi: 10.15252/msb.20177763.
Abstract
Cellular metabolic demands change throughout the cell cycle. Nevertheless, a characterization of how metabolic fluxes adapt to the changing demands throughout the cell cycle is lacking. Here, we developed a temporal-fluxomics approach to derive a comprehensive and quantitative view of alterations in metabolic fluxes throughout the mammalian cell cycle. This is achieved by combining pulse-chase LC-MS-based isotope tracing in synchronized cell populations with computational deconvolution and metabolic flux modeling. We find that TCA cycle fluxes are rewired as cells progress through the cell cycle with complementary oscillations of glucose versus glutamine-derived fluxes: Oxidation of glucose-derived flux peaks in late G1 phase, while oxidative and reductive glutamine metabolism dominates S phase. These complementary flux oscillations maintain a constant production rate of reducing equivalents and oxidative phosphorylation flux throughout the cell cycle. The shift from glucose to glutamine oxidation in S phase plays an important role in cell cycle progression and cell proliferation.
摘要
细胞代谢需求在细胞周期中不断变化。然而,对于代谢通量如何适应细胞周期中不断变化的需求,目前还缺乏描述。在这里,我们开发了一种时间代谢组学方法,通过结合同步细胞群中的脉冲追踪 LC-MS 基于同位素示踪与计算反卷积和代谢通量建模,全面、定量地观察哺乳动物细胞周期中代谢通量的变化。我们发现,随着细胞通过细胞周期,三羧酸 (TCA) 循环通量被重新布线,葡萄糖与谷氨酰胺衍生通量互补振荡:葡萄糖衍生通量的氧化在 G1 晚期达到峰值,而氧化和还原谷氨酰胺代谢在 S 期占主导地位。这些互补的通量振荡在整个细胞周期中维持还原当量和氧化磷酸化通量的恒定产生速率。S 期葡萄糖向谷氨酰胺氧化的转变对细胞周期进程和细胞增殖起着重要作用。
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