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Depletion of skeletal muscle satellite cells attenuates pathology in muscular dystrophy

Author

Listed:
  • Justin G. Boyer

    (Cincinnati Children’s Hospital Medical Center
    University of Cincinnati)

  • Jiuzhou Huo

    (Cincinnati Children’s Hospital Medical Center)

  • Sarah Han

    (Cincinnati Children’s Hospital Medical Center)

  • Julian R. Havens

    (Cincinnati Children’s Hospital Medical Center
    University of Cincinnati)

  • Vikram Prasad

    (Cincinnati Children’s Hospital Medical Center)

  • Brian L. Lin

    (Johns Hopkins Medical Institutions)

  • David A. Kass

    (Johns Hopkins Medical Institutions)

  • Taejeong Song

    (University of Cincinnati)

  • Sakthivel Sadayappan

    (University of Cincinnati)

  • Ramzi J. Khairallah

    (Myologica, LLC)

  • Christopher W. Ward

    (University of Maryland School of Medicine)

  • Jeffery D. Molkentin

    (Cincinnati Children’s Hospital Medical Center
    University of Cincinnati)

Abstract

Skeletal muscle can repair and regenerate due to resident stem cells known as satellite cells. The muscular dystrophies are progressive muscle wasting diseases underscored by chronic muscle damage that is continually repaired by satellite cell-driven regeneration. Here we generate a genetic strategy to mediate satellite cell ablation in dystrophic mouse models to investigate how satellite cells impact disease trajectory. Unexpectedly, we observe that depletion of satellite cells reduces dystrophic disease features, with improved histopathology, enhanced sarcolemmal stability and augmented muscle performance. Mechanistically, we demonstrate that satellite cells initiate expression of the myogenic transcription factor MyoD, which then induces re-expression of fetal genes in the myofibers that destabilize the sarcolemma. Indeed, MyoD re-expression in wildtype adult skeletal muscle reduces membrane stability and promotes histopathology, while MyoD inhibition in a mouse model of muscular dystrophy improved membrane stability. Taken together these observations suggest that satellite cell activation and the fetal gene program is maladaptive in chronic dystrophic skeletal muscle.

Suggested Citation

  • Justin G. Boyer & Jiuzhou Huo & Sarah Han & Julian R. Havens & Vikram Prasad & Brian L. Lin & David A. Kass & Taejeong Song & Sakthivel Sadayappan & Ramzi J. Khairallah & Christopher W. Ward & Jeffery, 2022. "Depletion of skeletal muscle satellite cells attenuates pathology in muscular dystrophy," Nature Communications, Nature, vol. 13(1), pages 1-10, December.
  • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-30619-7
    DOI: 10.1038/s41467-022-30619-7
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    References listed on IDEAS

    as
    1. Seung-Min Lee & Seol Hee Lee & Youngae Jung & Younglang Lee & Jong Hyun Yoon & Jeong Yi Choi & Chae Young Hwang & Young Hoon Son & Sung Sup Park & Geum-Sook Hwang & Kwang-Pyo Lee & Ki-Sun Kwon, 2020. "FABP3-mediated membrane lipid saturation alters fluidity and induces ER stress in skeletal muscle with aging," Nature Communications, Nature, vol. 11(1), pages 1-15, December.
    2. Christoph Lepper & Simon J. Conway & Chen-Ming Fan, 2009. "Adult satellite cells and embryonic muscle progenitors have distinct genetic requirements," Nature, Nature, vol. 460(7255), pages 627-631, July.
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    Cited by:

    1. Matthieu Dos Santos & Akansha M. Shah & Yichi Zhang & Svetlana Bezprozvannaya & Kenian Chen & Lin Xu & Weichun Lin & John R. McAnally & Rhonda Bassel-Duby & Ning Liu & Eric N. Olson, 2023. "Opposing gene regulatory programs governing myofiber development and maturation revealed at single nucleus resolution," Nature Communications, Nature, vol. 14(1), pages 1-14, December.

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