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Sucrose-driven carbon redox rebalancing eliminates the Crabtree effect and boosts energy metabolism in yeast

Author

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  • Zhiqiang Xiao

    (Hunan University
    Hunan Academy of Agricultural Sciences
    Hunan Agricultural Products Processing Institute)

  • Yifei Zhao

    (Hunan University
    Hunan Academy of Agricultural Sciences
    Hunan Agricultural Products Processing Institute)

  • Yongtong Wang

    (Hunan University
    Hunan Academy of Agricultural Sciences
    Hunan Agricultural Products Processing Institute)

  • Xinjia Tan

    (Hunan University
    Hunan Academy of Agricultural Sciences
    Hunan Agricultural Products Processing Institute)

  • Lian Wang

    (Tianjin University)

  • Jiwei Mao

    (Chalmers University of Technology)

  • Siqi Zhang

    (Hunan University
    Hunan Academy of Agricultural Sciences
    Hunan Agricultural Products Processing Institute)

  • Qiyuan Lu

    (Hunan University
    Hunan Academy of Agricultural Sciences
    Hunan Agricultural Products Processing Institute)

  • Fanglin Hu

    (Hunan University
    Hunan Academy of Agricultural Sciences
    Hunan Agricultural Products Processing Institute)

  • Shasha Zuo

    (Hunan University
    Hunan Academy of Agricultural Sciences
    Hunan Agricultural Products Processing Institute)

  • Juan Liu

    (Hunan Academy of Agricultural Sciences
    Hunan Agricultural Products Processing Institute)

  • Yang Shan

    (Hunan University
    Hunan Academy of Agricultural Sciences
    Hunan Agricultural Products Processing Institute)

Abstract

Saccharomyces cerevisiae primarily generates energy through glycolysis and respiration. However, the manifestation of the Crabtree effect results in substantial carbon loss and energy inefficiency, which significantly diminishes product yield and escalates substrate costs in microbial cell factories. To address this challenge, we introduce the sucrose phosphorolysis pathway and delete the phosphoglucose isomerase gene PGI1, effectively decoupling glycolysis from respiration and facilitating the metabolic transition of yeast to a Crabtree-negative state. Additionally, a synthetic energy system is engineered to regulate the NADH/NAD+ ratio, ensuring sufficient ATP supply and maintaining redox balance for optimal growth. The reprogrammed yeast strain exhibits significantly higher yields of various non-ethanol compounds, with lactic acid and 3-hydroxypropionic acid production increasing by 8- to 11-fold comparing to the conventional Crabtree-positive strain. This study describes an approach for overcoming the Crabtree effect in yeast, substantially improving energy metabolism, carbon recovery, and product yields.

Suggested Citation

  • Zhiqiang Xiao & Yifei Zhao & Yongtong Wang & Xinjia Tan & Lian Wang & Jiwei Mao & Siqi Zhang & Qiyuan Lu & Fanglin Hu & Shasha Zuo & Juan Liu & Yang Shan, 2025. "Sucrose-driven carbon redox rebalancing eliminates the Crabtree effect and boosts energy metabolism in yeast," Nature Communications, Nature, vol. 16(1), pages 1-16, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-60578-8
    DOI: 10.1038/s41467-025-60578-8
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    References listed on IDEAS

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    1. repec:osf:socarx:n9ecw_v1 is not listed on IDEAS
    2. Quanli Liu & Tao Yu & Xiaowei Li & Yu Chen & Kate Campbell & Jens Nielsen & Yun Chen, 2019. "Rewiring carbon metabolism in yeast for high level production of aromatic chemicals," Nature Communications, Nature, vol. 10(1), pages 1-13, December.
    3. Ning Qin & Lingyun Li & Xiaozhen Wan & Xu Ji & Yu Chen & Chaokun Li & Ping Liu & Yijie Zhang & Weijie Yang & Junfeng Jiang & Jianye Xia & Shuobo Shi & Tianwei Tan & Jens Nielsen & Yun Chen & Zihe Liu, 2024. "Increased CO2 fixation enables high carbon-yield production of 3-hydroxypropionic acid in yeast," Nature Communications, Nature, vol. 15(1), pages 1-15, December.
    4. Zongjie Dai & Mingtao Huang & Yun Chen & Verena Siewers & Jens Nielsen, 2018. "Global rewiring of cellular metabolism renders Saccharomyces cerevisiae Crabtree negative," Nature Communications, Nature, vol. 9(1), pages 1-8, December.
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