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AAV9-mediated MYBPC3 gene therapy with optimized expression cassette enhances cardiac function and survival in MYBPC3 cardiomyopathy models

Author

Listed:
  • Amara Greer-Short

    (Tenaya Therapeutics)

  • Anna Greenwood

    (Tenaya Therapeutics)

  • Elena C. Leon

    (Tenaya Therapeutics)

  • Tawny Neal Qureshi

    (Tenaya Therapeutics)

  • Konor Kraut

    (Tenaya Therapeutics)

  • Justin Wong

    (Tenaya Therapeutics)

  • Jonathan H. Tsui

    (Tenaya Therapeutics)

  • Christopher A. Reid

    (Tenaya Therapeutics)

  • Ze Cheng

    (Tenaya Therapeutics)

  • Emilee Easter

    (Tenaya Therapeutics)

  • Jin Yang

    (Tenaya Therapeutics)

  • Jaclyn Ho

    (Tenaya Therapeutics)

  • Stephanie Steltzer

    (Tenaya Therapeutics)

  • Ana Budan

    (Tenaya Therapeutics)

  • Marie Cho

    (Tenaya Therapeutics)

  • Rishikesan Chandrakumar

    (Tenaya Therapeutics)

  • Olga Cisne-Thompson

    (Tenaya Therapeutics)

  • Charles Feathers

    (Tenaya Therapeutics)

  • Tae Won Chung

    (Tenaya Therapeutics)

  • Neshel Rodriguez

    (Tenaya Therapeutics)

  • Samantha Jones

    (Tenaya Therapeutics)

  • Chris Alleyne-Levy

    (Tenaya Therapeutics)

  • Jun Liu

    (Tenaya Therapeutics)

  • Frank Jing

    (Tenaya Therapeutics)

  • William S. Prince

    (Tenaya Therapeutics)

  • JianMin Lin

    (Tenaya Therapeutics)

  • Kathryn N. Ivey

    (Tenaya Therapeutics)

  • Whittemore G. Tingley

    (Tenaya Therapeutics)

  • Timothy Hoey

    (Tenaya Therapeutics)

  • Laura M. Lombardi

    (Tenaya Therapeutics)

Abstract

Hypertrophic cardiomyopathy (HCM) affects approximately 600,000 people in the United States. Loss-of-function mutations in Myosin Binding Protein C3, MYBPC3, are the most common genetic cause of HCM, with the majority of mutations resulting in haploinsufficiency. To restore cardiac MYBPC3, we use an adeno-associated virus (AAV9) vector and engineer an optimized expression cassette with a minimal promoter and cis-regulatory elements (TN-201) to enhance packaging efficiency and cardiomyocyte expression. Rather than simply preventing cardiac dysfunction preclinically, we demonstrate in a symptomatic MYBPC3-deficient murine model the ability of AAV gene therapy to reverse cardiac hypertrophy and systolic dysfunction, improve diastolic dysfunction, and prolong survival. Dose-ranging efficacy studies exhibit restoration of wild-type MYBPC3 protein levels and saturation of cardiac improvement at the clinically relevant dose of 3E13 vg/kg, outperforming a previously published construct. These findings suggest that TN-201 may offer therapeutic benefits in MYBPC3-associated cardiomyopathy, pending further validation in clinical settings.

Suggested Citation

  • Amara Greer-Short & Anna Greenwood & Elena C. Leon & Tawny Neal Qureshi & Konor Kraut & Justin Wong & Jonathan H. Tsui & Christopher A. Reid & Ze Cheng & Emilee Easter & Jin Yang & Jaclyn Ho & Stephan, 2025. "AAV9-mediated MYBPC3 gene therapy with optimized expression cassette enhances cardiac function and survival in MYBPC3 cardiomyopathy models," Nature Communications, Nature, vol. 16(1), pages 1-18, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-57481-7
    DOI: 10.1038/s41467-025-57481-7
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