Nitrogen metabolism profiling reveals cell state-specific pyrimidine synthesis pathway choice.

IF 20.8 1区医学 Q1 ENDOCRINOLOGY & METABOLISM

Nature metabolism Pub Date : 2026-04-29 DOI:10.1038/s42255-026-01520-0

Milan R Savani, Bingbing Li, Bailey C Smith, Wen Gu, Yi Xiao, Gerard Baquer, Tracey Shipman, Skyler S Oken, Namya Manoj, Lauren G Zacharias, Vinesh T Puliyappadamba, Sylwia A Stopka, Michael S Regan, Michael M Levitt, Charles K Edgar, William H Hicks, Soummitra Anand, Misty S Martin-Sandoval, Rainah Winston, João S Patrício, Xandria Johnson, Trevor S Tippetts, Diana D Shi, Andrew Lemoff, Timothy E Richardson, Pascal O Zinn, Ashley Solmonson, Thomas P Mathews, Nathalie Y R Agar, Ralph J DeBerardinis, Kalil G Abdullah, Samuel K McBrayer

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引用次数: 0

Abstract

Stable isotope-tracing assays track few metabolites, yet cells use many nutrients to sustain nitrogen metabolism. Here we create a platform for tracing 30 nitrogen isotope-labelled metabolites in parallel to enable a system-level understanding of cellular nitrogen metabolism. This platform reveals that while primitive cells engage both de novo and salvage pyrimidine synthesis pathways, differentiated cells nearly exclusively salvage uridine. This link between cell state and pyrimidine synthesis pathway preference persists in murine and human tissues. Mechanistically, we find that S1900 phosphorylation of CAD, the first enzyme of the de novo pathway, is induced by uridine deprivation in differentiated cells and constitutively enriched in primitive cells. Mimicking CAD S1900 phosphorylation in differentiated cells constitutively activates de novo pyrimidine synthesis, while blocking this modification impairs the cellular response to uridine starvation. Collectively, we establish a method for nitrogen metabolism profiling and define a mechanism of cell state-specific pyrimidine synthesis pathway choice.

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氮代谢谱揭示细胞状态特异性嘧啶合成途径选择。

稳定同位素示踪法追踪的代谢物很少，但细胞利用许多营养物质维持氮代谢。在这里，我们创建了一个平台，用于并行追踪30种氮同位素标记的代谢物，以实现对细胞氮代谢的系统级理解。该平台表明，虽然原始细胞参与从头合成和补救性嘧啶合成途径，但分化的细胞几乎只参与补救性尿苷。这种细胞状态和嘧啶合成途径偏好之间的联系在小鼠和人体组织中持续存在。在机制上，我们发现CAD的S1900磷酸化是新生途径的第一个酶，在分化细胞中由尿苷剥夺诱导，在原始细胞中组成性富集。在分化细胞中模拟CAD S1900磷酸化可组成性地激活新的嘧啶合成，而阻断这种修饰会损害细胞对尿苷缺乏的反应。总之，我们建立了一种氮代谢分析方法，并确定了细胞状态特异性嘧啶合成途径选择的机制。

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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来源期刊

Nature metabolism ENDOCRINOLOGY & METABOLISM-

CiteScore

27.50

自引率

2.40%

发文量

170

期刊介绍： Nature Metabolism is a peer-reviewed scientific journal that covers a broad range of topics in metabolism research. It aims to advance the understanding of metabolic and homeostatic processes at a cellular and physiological level. The journal publishes research from various fields, including fundamental cell biology, basic biomedical and translational research, and integrative physiology. It focuses on how cellular metabolism affects cellular function, the physiology and homeostasis of organs and tissues, and the regulation of organismal energy homeostasis. It also investigates the molecular pathophysiology of metabolic diseases such as diabetes and obesity, as well as their treatment. Nature Metabolism follows the standards of other Nature-branded journals, with a dedicated team of professional editors, rigorous peer-review process, high standards of copy-editing and production, swift publication, and editorial independence. The journal has a high impact factor, has a certain influence in the international area, and is deeply concerned and cited by the majority of scholars.