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A phenopushing platform to identify compounds that alleviate acute hypoxic stress by fast-tracking cellular adaptation

Author

Listed:
  • Li Li

    (University of California San Francisco)

  • Heinz Hammerlindl

    (University of California San Francisco)

  • Susan Q. Shen

    (University of California San Francisco
    University of California San Francisco)

  • Feng Bao

    (University of California San Francisco)

  • Sabrina Hammerlindl

    (University of California San Francisco)

  • Steven J. Altschuler

    (University of California San Francisco)

  • Lani F. Wu

    (University of California San Francisco)

Abstract

Severe acute hypoxic stress is a major contributor to the pathology of human diseases, including ischemic disorders. Current treatments focus on managing consequences of hypoxia, with few addressing cellular adaptation to low-oxygen environments. Here, we investigate whether accelerating hypoxia adaptation could provide a strategy to alleviate acute hypoxic stress. We develop a high-content phenotypic screening platform to identify compounds that fast-track adaptation to hypoxic stress. Our platform captures a high-dimensional phenotypic hypoxia response trajectory consisting of normoxic, acutely stressed, and chronically adapted cell states. Leveraging this trajectory, we identify compounds that phenotypically shift cells from the acutely stressed state towards the adapted state, revealing mTOR/PI3K or BET inhibition as strategies to induce this phenotypic shift. Importantly, our compound hits promote the survival of liver cells exposed to ischemia-like stress, and rescue cardiomyocytes from hypoxic stress. Our “phenopushing” platform offers a general, target-agnostic approach to identify compounds and targets that accelerate cellular adaptation, applicable across various stress conditions.

Suggested Citation

  • Li Li & Heinz Hammerlindl & Susan Q. Shen & Feng Bao & Sabrina Hammerlindl & Steven J. Altschuler & Lani F. Wu, 2025. "A phenopushing platform to identify compounds that alleviate acute hypoxic stress by fast-tracking cellular adaptation," Nature Communications, Nature, vol. 16(1), pages 1-13, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-57754-1
    DOI: 10.1038/s41467-025-57754-1
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    References listed on IDEAS

    as
    1. Anna S. Dickson & Tekle Pauzaite & Esther Arnaiz & Brian M. Ortmann & James A. West & Norbert Volkmar & Anthony W. Martinelli & Zhaoqi Li & Niek Wit & Dennis Vitkup & Arthur Kaser & Paul J. Lehner & J, 2023. "A HIF independent oxygen-sensitive pathway for controlling cholesterol synthesis," Nature Communications, Nature, vol. 14(1), pages 1-16, December.
    2. Anna S. Dickson & Tekle Pauzaite & Esther Arnaiz & Brian M. Ortmann & James A. West & Norbert Volkmar & Anthony W. Martinelli & Zhaoqi Li & Niek Wit & Dennis Vitkup & Arthur Kaser & Paul J. Lehner & J, 2023. "Author Correction: A HIF independent oxygen-sensitive pathway for controlling cholesterol synthesis," Nature Communications, Nature, vol. 14(1), pages 1-1, December.
    3. Mingzhu Yin & Ying Guo & Rui Hu & Wesley L. Cai & Yao Li & Shiyao Pei & Hongyin Sun & Cong Peng & Jiali Li & Rui Ye & Qiaohong Yang & Nenghui Wang & Yongguang Tao & Xiang Chen & Qin Yan, 2020. "Potent BRD4 inhibitor suppresses cancer cell-macrophage interaction," Nature Communications, Nature, vol. 11(1), pages 1-14, December.
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