Metabolic flux analysis in leaf metabolism quantifies the link between photorespiration and one carbon metabolism

IF 13.6 1区生物学 Q1 PLANT SCIENCES

Nature Plants Pub Date : 2025-09-03 DOI:10.1038/s41477-025-02091-w

Kelem Gashu, Joshua A. M. Kaste, Sanja Roje, Berkley J. Walker

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Abstract

Photorespiration is the second largest carbon flux in most leaves and is integrated into metabolism broadly including one-carbon (C1) metabolism. Photorespiratory intermediates such as serine and others may serve as sources of C1 units, but it is unclear to what degree this happens in vivo, whether altered photorespiration changes flux to C1 metabolism, and if so through which intermediates. To clarify these questions, we quantified carbon flux from photorespiration to C1 metabolism using 13CO2 labelling and isotopically non-stationary metabolic flux analysis in Arabidopsis thaliana under different O2 concentrations which modulate photorespiration. The results revealed that ~5.8% of assimilated carbon passes to C1 metabolism under ambient photorespiratory conditions, but this flux greatly decreases under limited photorespiration. Furthermore, the primary carbon flux from photorespiration to C1 metabolism is through serine. Our results provide fundamental insight into how photorespiration is integrated into C1 metabolism, with possible implications for C1 metabolic response to climate change. This paper quantified carbon flux between two major plant metabolisms—photorespiration and C1 metabolism—using 13CO2 labelling and isotopically non-stationary metabolic flux analysis.

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叶片代谢通量分析量化了光呼吸与单碳代谢之间的联系

光呼吸是大多数叶片的第二大碳通量，并广泛融入代谢，包括一碳（C1）代谢。光呼吸中间体如丝氨酸和其他中间体可能作为C1单位的来源，但尚不清楚这种情况在体内发生的程度，改变的光呼吸是否会改变C1代谢的通量，以及如果是通过哪些中间体改变的。为了澄清这些问题，我们利用13CO2标记和同位素非平稳代谢通量分析，定量了拟南芥在不同O2浓度下从光呼吸到C1代谢的碳通量。结果表明，在环境光呼吸条件下，约5.8%的同化碳通过C1代谢，但在有限的光呼吸条件下，这一通量大大减少。此外，从光呼吸到C1代谢的主要碳通量是通过丝氨酸。我们的研究结果为光呼吸如何整合到C1代谢中提供了基本的见解，并可能对C1代谢对气候变化的响应产生影响。

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来源期刊

Nature Plants PLANT SCIENCES-

CiteScore

25.30

自引率

2.20%

发文量

196

期刊介绍： Nature Plants is an online-only, monthly journal publishing the best research on plants — from their evolution, development, metabolism and environmental interactions to their societal significance.