Hypothyroidism impairs skeletal muscle regeneration after injury by altering myogenic and nonmyogenic pathways
Paola Aguiari, Valentina Villani, Yan-Yun Liu, Gianni Carraro, Gregory A. Brent, Laura Perin, Anna Milanesi
Paola Aguiari, Valentina Villani, Yan-Yun Liu, Gianni Carraro, Gregory A. Brent, Laura Perin, Anna Milanesi
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Research Article Cell biology Endocrinology Muscle biology

Hypothyroidism impairs skeletal muscle regeneration after injury by altering myogenic and nonmyogenic pathways

Abstract

Thyroid hormone signaling is an essential regulator of skeletal muscle development, function, and metabolism, yet the specific signaling pathways required for muscle regeneration are not yet defined. We used scRNA-seq and the FUCCI (fluorescent ubiquitination-based cell cycle indicator) reporter mouse model to examine how hypothyroidism impacts repair processes after cardiotoxin-induced injury in mice. During regeneration, and up to 2 months after injury, hypothyroid muscles displayed smaller myofibers and a shift to slower oxidative fiber types. scRNA-seq of tibialis anterior muscle during regeneration revealed that hypothyroidism reduced myogenic-lineage diversity. Cell cycle analysis confirmed delayed cell cycle progression at 5 and 14 days after injury, with skeletal muscle stem cells stalled at the G1/S transition, hindering differentiation. Transcriptomic data revealed altered nonmyogenic dynamics, including elevated activated fibro-adipogenic progenitors (FAPs) early in repair and persistent proinflammatory macrophages. Integrative regulon and ligand-receptor analysis further demonstrated that triiodothyronine acted through dual modes: a direct transcriptional control of myogenic cell cycle and oxidative programs and an indirect paracrine remodeling mediated by FAP and immune signaling networks. This study identified what we believe to be novel effects of hypothyroidism on myogenic heterogeneity and impaired tissue repair, offering insights into muscle-wasting mechanisms relevant to hypothyroidism-associated myopathy and sarcopenia.

Authors

Paola Aguiari, Valentina Villani, Yan-Yun Liu, Gianni Carraro, Gregory A. Brent, Laura Perin, Anna Milanesi

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Figure 4

scRNA-seq and trajectory analysis reveal altered myogenic cell state transitions and impaired progression in hypothyroid muscle regeneration.

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scRNA-seq and trajectory analysis reveal altered myogenic cell state tra...
(A) t-SNE visualization of the integrated scRNA-seq datasets from control and hypothyroid myogenic-lineage cells, with clusters distinguished by color. (B) Graph depicting relative proportions of clusters in each sample shown as percentage. Number of cells for each sample: CTRL NI, 163; CTRL 5d, 201; CTRL 14d, 344; HYPO NI, 208; HYPO 5d, 399; HYPO 14d, 148. (C) Table showing fold change in gene expression of selected genes for cells in Myocytes (cluster 1), Quiescent/Activated (cluster 5), and Proliferating II (cluster 2) clusters, in uninjured muscle and 5 days and 14 dpi, comparing hypothyroid and control myogenic-lineage cells. (D) Monocle trajectory plots for control datasets showing the distribution of myogenic cells in 5 states. (E) Monocle trajectory plots split by time point, in uninjured muscle and 5 days and 14 dpi, showing the distribution of control myogenic cells in 5 states. (F) Graph showing the number of cells in each control Monocle trajectory state. (G) Graph showing the percentage of cells from each time point for each control Monocle trajectory state. (H) Violin plots showing gene expression for selected genes in the control-specific myocyte states. (I) Monocle trajectory plots for hypothyroid datasets showing the distribution of hypothyroid myogenic cells in 3 states. (J) Monocle trajectory plots split by time point, in uninjured muscle and 5 days and 14 dpi, showing the distribution of hypothyroid myogenic cells in 3 states. (K) Graph showing the number of cells in each hypothyroid Monocle trajectory state. (L) Graph showing the percentage of cells from each time point for each hypothyroid Monocle trajectory state. C, control; H, hypothyroid.