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Metabolic regulation of gene expression by histone lactylation

Author

Listed:
  • Di Zhang

    (The University of Chicago)

  • Zhanyun Tang

    (The Rockefeller University)

  • He Huang

    (The University of Chicago
    Chinese Academy of Sciences)

  • Guolin Zhou

    (The University of Chicago)

  • Chang Cui

    (The University of Chicago)

  • Yejing Weng

    (The University of Chicago)

  • Wenchao Liu

    (The University of Chicago)

  • Sunjoo Kim

    (Kyungpook National University)

  • Sangkyu Lee

    (Kyungpook National University)

  • Mathew Perez-Neut

    (The University of Chicago)

  • Jun Ding

    (The University of Chicago)

  • Daniel Czyz

    (The University of Chicago)

  • Rong Hu

    (University of California at San Diego
    University of California, San Diego School of Medicine)

  • Zhen Ye

    (University of California at San Diego
    University of California, San Diego School of Medicine)

  • Maomao He

    (University of Georgia)

  • Y. George Zheng

    (University of Georgia)

  • Howard A. Shuman

    (The University of Chicago)

  • Lunzhi Dai

    (The University of Chicago
    Sichuan University, and Collaborative Innovation Center of Biotherapy)

  • Bing Ren

    (University of California at San Diego
    University of California, San Diego School of Medicine)

  • Robert G. Roeder

    (The Rockefeller University)

  • Lev Becker

    (The University of Chicago
    University of Chicago Medicine Comprehensive Cancer Center
    The University of Chicago)

  • Yingming Zhao

    (The University of Chicago
    University of Chicago Medicine Comprehensive Cancer Center)

Abstract

The Warburg effect, which originally described increased production of lactate in cancer, is associated with diverse cellular processes such as angiogenesis, hypoxia, polarization of macrophages and activation of T cells. This phenomenon is intimately linked to several diseases including neoplasia, sepsis and autoimmune diseases1,2. Lactate, which is converted from pyruvate in tumour cells, is widely known as an energy source and metabolic by-product. However, its non-metabolic functions in physiology and disease remain unknown. Here we show that lactate-derived lactylation of histone lysine residues serves as an epigenetic modification that directly stimulates gene transcription from chromatin. We identify 28 lactylation sites on core histones in human and mouse cells. Hypoxia and bacterial challenges induce the production of lactate by glycolysis, and this acts as a precursor that stimulates histone lactylation. Using M1 macrophages that have been exposed to bacteria as a model system, we show that histone lactylation has different temporal dynamics from acetylation. In the late phase of M1 macrophage polarization, increased histone lactylation induces homeostatic genes that are involved in wound healing, including Arg1. Collectively, our results suggest that an endogenous ‘lactate clock’ in bacterially challenged M1 macrophages turns on gene expression to promote homeostasis. Histone lactylation thus represents an opportunity to improve our understanding of the functions of lactate and its role in diverse pathophysiological conditions, including infection and cancer.

Suggested Citation

  • Di Zhang & Zhanyun Tang & He Huang & Guolin Zhou & Chang Cui & Yejing Weng & Wenchao Liu & Sunjoo Kim & Sangkyu Lee & Mathew Perez-Neut & Jun Ding & Daniel Czyz & Rong Hu & Zhen Ye & Maomao He & Y. Ge, 2019. "Metabolic regulation of gene expression by histone lactylation," Nature, Nature, vol. 574(7779), pages 575-580, October.
    • Handle: RePEc:nat:nature:v:574:y:2019:i:7779:d:10.1038_s41586-019-1678-1
    DOI: 10.1038/s41586-019-1678-1
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    Citations

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    Cited by:

    1. Marlies Cortés & Agnese Brischetto & M. C. Martinez-Campanario & Chiara Ninfali & Verónica Domínguez & Sara Fernández & Raquel Celis & Anna Esteve-Codina & Juan J. Lozano & Julia Sidorova & Gloria Gar, 2023. "Inflammatory macrophages reprogram to immunosuppression by reducing mitochondrial translation," Nature Communications, Nature, vol. 14(1), pages 1-18, December.
    2. Zhenzhen Chen & Qiankun He & Tiankun Lu & Jiayi Wu & Gaoli Shi & Luyun He & Hong Zong & Benyu Liu & Pingping Zhu, 2023. "mcPGK1-dependent mitochondrial import of PGK1 promotes metabolic reprogramming and self-renewal of liver TICs," Nature Communications, Nature, vol. 14(1), pages 1-16, December.
    3. Hanyang Dong & Jianji Zhang & Hui Zhang & Yue Han & Congcong Lu & Chen Chen & Xiaoxia Tan & Siyu Wang & Xue Bai & Guijin Zhai & Shanshan Tian & Tao Zhang & Zhongyi Cheng & Enmin Li & Liyan Xu & Kai Zh, 2022. "YiaC and CobB regulate lysine lactylation in Escherichia coli," Nature Communications, Nature, vol. 13(1), pages 1-16, December.
    4. Yusuke Nasu & Abhi Aggarwal & Giang N. T. Le & Camilla Trang Vo & Yuki Kambe & Xinxing Wang & Felix R. M. Beinlich & Ashley Bomin Lee & Tina R. Ram & Fangying Wang & Kelsea A. Gorzo & Yuki Kamijo & Ma, 2023. "Lactate biosensors for spectrally and spatially multiplexed fluorescence imaging," Nature Communications, Nature, vol. 14(1), pages 1-17, December.
    5. Markus M. Rinschen & Oleg Palygin & Ashraf El-Meanawy & Xavier Domingo-Almenara & Amelia Palermo & Lashodya V. Dissanayake & Daria Golosova & Michael A. Schafroth & Carlos Guijas & Fatih Demir & Johan, 2022. "Accelerated lysine metabolism conveys kidney protection in salt-sensitive hypertension," Nature Communications, Nature, vol. 13(1), pages 1-17, December.
    6. Lianhui Sun & Yuan Zhang & Boyu Yang & Sijun Sun & Pengshan Zhang & Zai Luo & Tingting Feng & Zelin Cui & Ting Zhu & Yuming Li & Zhengjun Qiu & Guangjian Fan & Chen Huang, 2023. "Lactylation of METTL16 promotes cuproptosis via m6A-modification on FDX1 mRNA in gastric cancer," Nature Communications, Nature, vol. 14(1), pages 1-16, December.
    7. Fjodor Merkuri & Megan Rothstein & Marcos Simoes-Costa, 2024. "Histone lactylation couples cellular metabolism with developmental gene regulatory networks," Nature Communications, Nature, vol. 15(1), pages 1-19, December.
    8. Chi Zhou & Wenxin Li & Zhenxing Liang & Xianrui Wu & Sijing Cheng & Jianhong Peng & Kaixuan Zeng & Weihao Li & Ping Lan & Xin Yang & Li Xiong & Ziwei Zeng & Xiaobin Zheng & Liang Huang & Wenhua Fan & , 2024. "Mutant KRAS-activated circATXN7 fosters tumor immunoescape by sensitizing tumor-specific T cells to activation-induced cell death," Nature Communications, Nature, vol. 15(1), pages 1-21, December.
    9. Han Wang & Huiying Sun & Bilin Liang & Fang Zhang & Fan Yang & Bowen Cui & Lixia Ding & Xiang Wang & Ronghua Wang & Jiaoyang Cai & Yanjing Tang & Jianan Rao & Wenting Hu & Shuang Zhao & Wenyan Wu & Xi, 2023. "Chromatin accessibility landscape of relapsed pediatric B-lineage acute lymphoblastic leukemia," Nature Communications, Nature, vol. 14(1), pages 1-15, December.
    10. Tianshi Feng & Xuemei Zhao & Ping Gu & Wah Yang & Cunchuan Wang & Qingyu Guo & Qiaoyun Long & Qing Liu & Ying Cheng & Jin Li & Cynthia Kwan Yui Cheung & Donghai Wu & Xinyu Kong & Yong Xu & Dewei Ye & , 2022. "Adipocyte-derived lactate is a signalling metabolite that potentiates adipose macrophage inflammation via targeting PHD2," Nature Communications, Nature, vol. 13(1), pages 1-14, December.
    11. Shan Yao & Min-Dong Xu & Ying Wang & Shen-Ting Zhao & Jin Wang & Gui-Fu Chen & Wen-Bing Chen & Jian Liu & Guo-Bin Huang & Wen-Juan Sun & Yan-Yan Zhang & Huan-Li Hou & Lei Li & Xiang-Dong Sun, 2023. "Astrocytic lactate dehydrogenase A regulates neuronal excitability and depressive-like behaviors through lactate homeostasis in mice," Nature Communications, Nature, vol. 14(1), pages 1-18, December.

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