Transient HIF2A inhibition promotes satellite cell proliferation and muscle regeneration
Liwei Xie, … , Jarrod A. Call, Hang Yin
Liwei Xie, … , Jarrod A. Call, Hang Yin
Published March 13, 2018
Citation Information: J Clin Invest. 2018;128(6):2339-2355. https://doi.org/10.1172/JCI96208.
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Research Article Muscle biology

Transient HIF2A inhibition promotes satellite cell proliferation and muscle regeneration

Abstract

The remarkable regeneration capability of skeletal muscle depends on the coordinated proliferation and differentiation of satellite cells (SCs). The self-renewal of SCs is critical for long-term maintenance of muscle regeneration potential. Hypoxia profoundly affects the proliferation, differentiation, and self-renewal of cultured myoblasts. However, the physiological relevance of hypoxia and hypoxia signaling in SCs in vivo remains largely unknown. Here, we demonstrate that SCs are in an intrinsic hypoxic state in vivo and express hypoxia-inducible factor 2A (HIF2A). HIF2A promotes the stemness and long-term homeostatic maintenance of SCs by maintaining their quiescence, increasing their self-renewal, and blocking their myogenic differentiation. HIF2A stabilization in SCs cultured under normoxia augments their engraftment potential in regenerative muscle. Conversely, HIF2A ablation leads to the depletion of SCs and their consequent regenerative failure in the long-term. In contrast, transient pharmacological inhibition of HIF2A accelerates muscle regeneration by increasing SC proliferation and differentiation. Mechanistically, HIF2A induces the quiescence and self-renewal of SCs by binding the promoter of the Spry1 gene and activating Spry1 expression. These findings suggest that HIF2A is a pivotal mediator of hypoxia signaling in SCs and may be therapeutically targeted to improve muscle regeneration.

Authors

Liwei Xie, Amelia Yin, Anna S. Nichenko, Aaron M. Beedle, Jarrod A. Call, Hang Yin

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Figure 6

Genetic ablation of HIF2A transiently improves muscle regeneration but impairs long-term muscle regeneration potential.

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Genetic ablation of HIF2A transiently improves muscle regeneration but i...
(A) Representative images of TA muscles from SC-HIF2AKO mice and control littermates (n = 6 mice/group/time point). The muscles were CTX injured 10 days after tamoxifen-induced HIF2A ablation (10 dpr). Immunofluorescence of Pax7 after CTX injury (10 and 21 dpi) revealed an increase in Pax7+ SCs (arrowheads) in SC-HIF2AKO mice. Scale bars: 20 μm. (B and C) Number of Pax7+ SCs per TA muscle section at 10 dpi (B) and 21 dpi (C). (D) Representative images of TA muscles from SC-HIF2AKO mice and control littermates (n = 6 mice/group/time point). The muscles were CTX injured 10 days after tamoxifen-induced HIF2A ablation (10 dpr). Immunofluorescence of eMyHC and laminin B2 days after CTX injury (5, 10, and 21 dpi) revealed accelerated muscle regeneration in SC-HIF2AKO mice. Scale bars: 20 μm. (E) Representative images of TA muscles from SC-HIF2AKO mice and control littermates (n = 3 mice/group). The muscles were CTX injured 6 months after tamoxifen-induced HIF2A ablation. H&E staining of TA muscles 30 days after CTX injury revealed impaired muscle regeneration in SC-HIF2AKO mice. Scale bars: 20 μm. **P < 0.01, by 2-sided Student’s t test. Data represent the mean ± SEM.