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Enabling next-generation engineered TCR-T therapies based on high-throughput TCR discovery from diagnostic tumor biopsies

Author

Listed:
  • Thomas Kuilman

    (Neogene Therapeutics, A member of the AstraZeneca Group)

  • Deborah S. Schrikkema

    (Neogene Therapeutics, A member of the AstraZeneca Group)

  • Jules Gadiot

    (Neogene Therapeutics, A member of the AstraZeneca Group)

  • Raquel Gomez-Eerland

    (Neogene Therapeutics, A member of the AstraZeneca Group)

  • Laura Bies

    (Neogene Therapeutics, A member of the AstraZeneca Group)

  • Julia Walker

    (Neogene Therapeutics, A member of the AstraZeneca Group)

  • Robbert M. Spaapen

    (Neogene Therapeutics, A member of the AstraZeneca Group)

  • Hanna Kok

    (Neogene Therapeutics, A member of the AstraZeneca Group)

  • Demi Houg

    (Neogene Therapeutics, A member of the AstraZeneca Group)

  • Milena Viyacheva

    (Neogene Therapeutics, A member of the AstraZeneca Group)

  • Yvonne B. Claassen

    (Neogene Therapeutics, A member of the AstraZeneca Group)

  • Manuel Saornil

    (Neogene Therapeutics, A member of the AstraZeneca Group)

  • Oscar Krijgsman

    (Neogene Therapeutics, A member of the AstraZeneca Group)

  • Bas Stringer

    (Neogene Therapeutics, A member of the AstraZeneca Group)

  • Huiwen Ding

    (Neogene Therapeutics, A member of the AstraZeneca Group)

  • Anou Geleijnse

    (Neogene Therapeutics, A member of the AstraZeneca Group)

  • Anne C. Meinema

    (Neogene Therapeutics, A member of the AstraZeneca Group)

  • Bianca Weissbrich

    (Neogene Therapeutics, A member of the AstraZeneca Group)

  • Melissa Lancee

    (Neogene Therapeutics, A member of the AstraZeneca Group)

  • Carmen G. Engele

    (Neogene Therapeutics, A member of the AstraZeneca Group)

  • Marianna Sabatino

    (Neogene Therapeutics, A member of the AstraZeneca Group)

  • Pei-Ling Chen

    (Moffitt Cancer Center
    Moffitt Cancer Center)

  • Kenneth Y. Tsai

    (Moffitt Cancer Center
    Moffitt Cancer Center)

  • James J. Mulé

    (Moffitt Cancer Center
    Moffitt Cancer Center)

  • Vernon K. Sondak

    (Moffitt Cancer Center)

  • Jitske Bulk

    (Neogene Therapeutics, A member of the AstraZeneca Group
    Leiden University Medical Center)

  • Noel F. Miranda

    (Leiden University Medical Center)

  • Inge Jedema

    (The Netherlands Cancer Institute)

  • John G. Haanen

    (The Netherlands Cancer Institute
    The Netherlands Cancer Institute
    Leiden University Medical Center)

  • Jeroen W. J. Heijst

    (Neogene Therapeutics, A member of the AstraZeneca Group)

  • Ton N. Schumacher

    (The Netherlands Cancer Institute
    Leiden University Medical Center)

  • Carsten Linnemann

    (Neogene Therapeutics, A member of the AstraZeneca Group)

  • Gavin M. Bendle

    (Neogene Therapeutics, A member of the AstraZeneca Group)

Abstract

Adoptive cell therapy with tumor-infiltrating lymphocytes (TIL) can mediate tumor regression, including complete and durable responses, in a range of solid cancers, most notably in melanoma. However, its wider application and efficacy has been restricted by the limited accessibility, proliferative capacity and effector function of tumor-specific TIL. Here, we develop a platform for the efficient identification of tumor-specific TCR genes from diagnostic tumor biopsies, including core-needle biopsies frozen in a non-viable format, to enable engineered T cell therapy. Using a genetic screening approach that detects antigen-reactive TCRs with high sensitivity and specificity based on T cell activation, we show that high complexity TCR libraries can be efficiently screened against multiplexed antigen libraries to identify both HLA class I and II restricted TCRs. Through the identification of neoantigen-specific TCRs directly from melanoma as well as low tumor mutational burden microsatellite-stable colorectal carcinoma samples, we demonstrate the pan-cancer potential of this platform.

Suggested Citation

  • Thomas Kuilman & Deborah S. Schrikkema & Jules Gadiot & Raquel Gomez-Eerland & Laura Bies & Julia Walker & Robbert M. Spaapen & Hanna Kok & Demi Houg & Milena Viyacheva & Yvonne B. Claassen & Manuel S, 2025. "Enabling next-generation engineered TCR-T therapies based on high-throughput TCR discovery from diagnostic tumor biopsies," Nature Communications, Nature, vol. 16(1), pages 1-14, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-024-55420-6
    DOI: 10.1038/s41467-024-55420-6
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    References listed on IDEAS

    as
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