9291 Hypothyroidism impairs skeletal muscle regeneration after injury

Disclosure: P. Aguiari: None. V. Villani: None. K.Y. Liu: None. G.A. Brent: None. L. Perin: None. A. Milanesi: None. Thyroid hormone (TH) signaling plays an essential role in muscle development and function, in the maintenance of muscle mass, and in regeneration after injury. Disruption of TH signal...

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Published in:Journal of the Endocrine Society Vol. 8; no. Supplement_1
Main Authors: Aguiari, Paola, Villani, Valentina, Liu, Kaitlyn Y, Brent, Gregory A, Perin, Laura, Milanesi, Anna
Format: Journal Article
Language:English
Published: US Oxford University Press 05-10-2024
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Summary:Disclosure: P. Aguiari: None. V. Villani: None. K.Y. Liu: None. G.A. Brent: None. L. Perin: None. A. Milanesi: None. Thyroid hormone (TH) signaling plays an essential role in muscle development and function, in the maintenance of muscle mass, and in regeneration after injury. Disruption of TH signaling results in an abnormal skeletal muscle phenotype, impaired regeneration, and sarcopenia with aging, reflecting the myopathic changes described in hypothyroid patients. Muscle stem cells (MuSCs) are the mediators of post-natal skeletal muscle plasticity. Normally quiescent, in response to injury they enter the cell cycle (myoblasts) and proliferate. Myoblasts then exit the cell cycle and differentiate into myocytes that will fuse with existing myofibers to restore tissue architecture and function. Via TH receptor alpha, TH regulates all the stages of the regeneration program and regulates the expression of multiple myogenic genes. Despite all this evidence, to date there are no studies investigating MuSCs behavior in response to injury during hypothyroidism. We characterized injury-induced regeneration of the tibialis anterior muscle (TAM) in euthyroid and hypothyroid mice, fed a low iodine + 0.15% propylthiouracil diet. To investigate the cell cycle dynamics of MuSCs, we generated Pax7-Fucci mice carrying the fluorescent ubiquitination-based cell-cycle indicator (Fucci) system under the Pax7 promoter. Muscle injury was induced via cardiotoxin injection in the TAM of 3-month-old Pax7-Fucci mice. Hypothyroid mice present signs of impaired regeneration compared to euthyroid mice. From histological analysis, at different time points, we observed smaller fiber diameters, myofibers with central nuclei, and a significantly reduced number of fast glycolytic type IIb fibers, the prevalent muscle fiber type in the TA muscle. ScRNAseq analysis shows that at a late phase of regeneration (14 days after injury) hypothyroid MuSCs and myoblasts are still in the activation state and overexpress genes related to DNA replication and cell proliferation, while genes related to myogenic differentiation and cell cycle exit are downregulated. Differentiated myocytes in the hypothyroid fibers present an immature phenotype and are characterized by overexpression of embryonic/temporary and slow myosin genes and downregulation of mature fast myosins. Cell cycle analysis of the Fucci signal through Flow Cytometry confirmed a higher number of activated hypothyroid MuSCs at 4, 7, and 28 days after injury. These cells accumulate in the S phase and are unable to exit the cell cycle and differentiate towards myocytes. These data demonstrate that hypothyroidism impairs muscle tissue regeneration halting MuSCs progression through the cell cycle, myoblast cell cycle exit, and fiber maturation. Investigating muscle stem cell behavior and response to injury during hypothyroidism is crucial to understanding the mechanism behind thyroid hormone-induced myopathies and identifying possible therapeutical targets. Presentation: 6/2/2024
ISSN:2472-1972
2472-1972
DOI:10.1210/jendso/bvae163.1811