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Engineering the lymph node environment promotes antigen-specific efficacy in type 1 diabetes and islet transplantation

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Listed:
  • Joshua M. Gammon

    (University of Maryland, College Park)

  • Sean T. Carey

    (University of Maryland, College Park)

  • Vikas Saxena

    (University of Maryland Medical School)

  • Haleigh B. Eppler

    (University of Maryland, College Park)

  • Shannon J. Tsai

    (University of Maryland, College Park)

  • Christina Paluskievicz

    (University of Maryland Medical School)

  • Yanbao Xiong

    (University of Maryland Medical School)

  • Lushen Li

    (University of Maryland Medical School)

  • Marian Ackun-Farmmer

    (University of Maryland, College Park)

  • Lisa H. Tostanoski

    (University of Maryland, College Park)

  • Emily A. Gosselin

    (University of Maryland, College Park)

  • Alexis A. Yanes

    (University of Maryland, College Park)

  • Xiangbin Zeng

    (University of Maryland, College Park)

  • Robert S. Oakes

    (University of Maryland, College Park
    VA Maryland Health Care System)

  • Jonathan S. Bromberg

    (University of Maryland Medical School
    University of Maryland Medical School)

  • Christopher M. Jewell

    (University of Maryland, College Park
    University of Maryland Medical School
    VA Maryland Health Care System
    University of Maryland Medical School)

Abstract

Antigen-specific tolerance is a key goal of experimental immunotherapies for autoimmune disease and allograft rejection. This outcome could selectively inhibit detrimental inflammatory immune responses without compromising functional protective immunity. A major challenge facing antigen-specific immunotherapies is ineffective control over immune signal targeting and integration, limiting efficacy and causing systemic non-specific suppression. Here we use intra-lymph node injection of diffusion-limited degradable microparticles that encapsulate self-antigens with the immunomodulatory small molecule, rapamycin. We show this strategy potently inhibits disease during pre-clinical type 1 diabetes and allogenic islet transplantation. Antigen and rapamycin are required for maximal efficacy, and tolerance is accompanied by expansion of antigen-specific regulatory T cells in treated and untreated lymph nodes. The antigen-specific tolerance in type 1 diabetes is systemic but avoids non-specific immune suppression. Further, microparticle treatment results in the development of tolerogenic structural microdomains in lymph nodes. Finally, these local structural and functional changes in lymph nodes promote memory markers among antigen-specific regulatory T cells, and tolerance that is durable. This work supports intra-lymph node injection of tolerogenic microparticles as a powerful platform to promote antigen-dependent efficacy in type 1 diabetes and allogenic islet transplantation.

Suggested Citation

  • Joshua M. Gammon & Sean T. Carey & Vikas Saxena & Haleigh B. Eppler & Shannon J. Tsai & Christina Paluskievicz & Yanbao Xiong & Lushen Li & Marian Ackun-Farmmer & Lisa H. Tostanoski & Emily A. Gosseli, 2023. "Engineering the lymph node environment promotes antigen-specific efficacy in type 1 diabetes and islet transplantation," Nature Communications, Nature, vol. 14(1), pages 1-18, December.
    • Handle: RePEc:nat:natcom:v:14:y:2023:i:1:d:10.1038_s41467-023-36225-5
    DOI: 10.1038/s41467-023-36225-5
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    References listed on IDEAS

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    1. Koichi Araki & Alexandra P. Turner & Virginia Oliva Shaffer & Shivaprakash Gangappa & Susanne A. Keller & Martin F. Bachmann & Christian P. Larsen & Rafi Ahmed, 2009. "mTOR regulates memory CD8 T-cell differentiation," Nature, Nature, vol. 460(7251), pages 108-112, July.
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