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The engineered CD80 variant fusion therapeutic davoceticept combines checkpoint antagonism with conditional CD28 costimulation for anti-tumor immunity

Author

Listed:
  • Mark F. Maurer

    (Alpine Immune Sciences, Inc.)

  • Katherine E. Lewis

    (Alpine Immune Sciences, Inc.)

  • Joseph L. Kuijper

    (Alpine Immune Sciences, Inc.)

  • Dan Ardourel

    (Alpine Immune Sciences, Inc.)

  • Chelsea J. Gudgeon

    (Alpine Immune Sciences, Inc.)

  • Siddarth Chandrasekaran

    (Alpine Immune Sciences, Inc.
    Notch Therapeutics, Inc.)

  • Sherri L. Mudri

    (Alpine Immune Sciences, Inc.)

  • Kayla N. Kleist

    (Alpine Immune Sciences, Inc.)

  • Chris Navas

    (Alpine Immune Sciences, Inc.
    Lyell Immunopharma, Inc.)

  • Martin F. Wolfson

    (Alpine Immune Sciences, Inc.)

  • Mark W. Rixon

    (Alpine Immune Sciences, Inc.)

  • Ryan Swanson

    (Alpine Immune Sciences, Inc.
    Neoleukin Therapeutics, Inc.)

  • Stacey R. Dillon

    (Alpine Immune Sciences, Inc.)

  • Steven D. Levin

    (Alpine Immune Sciences, Inc.
    Parvus Therapeutics, Inc.)

  • Yengo Raymond Kimbung

    (Medicon Villiage)

  • Masato Akutsu

    (Medicon Villiage
    Keio University)

  • Derek T. Logan

    (Medicon Villiage)

  • Björn Walse

    (Medicon Villiage)

  • Kristine M. Swiderek

    (Alpine Immune Sciences, Inc.
    Mozart Therapeutics, Inc.)

  • Stanford L. Peng

    (Alpine Immune Sciences, Inc.)

Abstract

Despite the recent clinical success of T cell checkpoint inhibition targeting the CTLA-4 and PD-1 pathways, many patients either fail to achieve objective responses or they develop resistance to therapy. In some cases, poor responses to checkpoint blockade have been linked to suboptimal CD28 costimulation and the inability to generate and maintain a productive adaptive anti-tumor immune response. To address this, here we utilize directed evolution to engineer a CD80 IgV domain with increased PD-L1 affinity and fuse this to an immunoglobulin Fc domain, creating a therapeutic (ALPN-202, davoceticept) capable of providing CD28 costimulation in a PD-L1-dependent fashion while also antagonizing PD-1 - PD-L1 and CTLA-4–CD80/CD86 interactions. We demonstrate that by combining CD28 costimulation and dual checkpoint inhibition, ALPN-202 enhances T cell activation and anti-tumor efficacy in cell-based assays and mouse tumor models more potently than checkpoint blockade alone and thus has the potential to generate potent, clinically meaningful anti-tumor immunity in humans.

Suggested Citation

  • Mark F. Maurer & Katherine E. Lewis & Joseph L. Kuijper & Dan Ardourel & Chelsea J. Gudgeon & Siddarth Chandrasekaran & Sherri L. Mudri & Kayla N. Kleist & Chris Navas & Martin F. Wolfson & Mark W. Ri, 2022. "The engineered CD80 variant fusion therapeutic davoceticept combines checkpoint antagonism with conditional CD28 costimulation for anti-tumor immunity," Nature Communications, Nature, vol. 13(1), pages 1-14, December.
    • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-29286-5
    DOI: 10.1038/s41467-022-29286-5
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    1. Se Jin Im & Masao Hashimoto & Michael Y. Gerner & Junghwa Lee & Haydn T. Kissick & Matheus C. Burger & Qiang Shan & J. Scott Hale & Judong Lee & Tahseen H. Nasti & Arlene H. Sharpe & Gordon J. Freeman, 2016. "Defining CD8+ T cells that provide the proliferative burst after PD-1 therapy," Nature, Nature, vol. 537(7620), pages 417-421, September.
    2. Carin C. Stamper & Yan Zhang & James F. Tobin & David V. Erbe & Shinji Ikemizu & Simon J. Davis & Mark L. Stahl & Jasbir Seehra & William S. Somers & Lidia Mosyak, 2001. "Crystal structure of the B7-1/CTLA-4 complex that inhibits human immune responses," Nature, Nature, vol. 410(6828), pages 608-611, March.
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