Macrophage metabolic rewiring rejuvenates muscle Raman signatures and cellular remodeling during regrowth in aged mice
Zachary J. Fennel, … , Anhong Zhou, Micah J. Drummond
Zachary J. Fennel, … , Anhong Zhou, Micah J. Drummond
Published September 9, 2025
Citation Information: JCI Insight. 2025;10(20):e194303. https://doi.org/10.1172/jci.insight.194303.
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Research Article Aging Metabolism Muscle biology

Macrophage metabolic rewiring rejuvenates muscle Raman signatures and cellular remodeling during regrowth in aged mice

Abstract

Impaired muscle regrowth in aging is underpinned by reduced proinflammatory macrophage function and subsequently impaired muscle cellular remodeling. Macrophage phenotype is metabolically controlled through TCA intermediate accumulation and activation of HIF1A. We hypothesized that transient hypoxia following disuse in old mice would enhance macrophage metabolic inflammatory function, thereby improving muscle cellular remodeling and recovery. Old (20 months) and young adult mice (4 months) were exposed to acute (24 hour) normobaric hypoxia immediately following 14 days of hind limb unloading and assessed during early reambulation (4 and 7 days) compared to age-matched controls. Treated aged mice had improved proinflammatory macrophage profiles, muscle cellular remodeling, and functional muscle recovery to the levels of young control mice. Likewise, young adult mice had enhanced muscle remodeling and functional recovery when treated with acute hypoxia. Treatment in aged mice restored the muscle molecular fingerprint and biochemical spectral patterns (Raman spectroscopy) observed in young mice and strongly correlated with improved collagen remodeling. Finally, intramuscular delivery of hypoxia-treated macrophages recapitulated the muscle remodeling and recovery effects of whole-body hypoxic exposure in old mice. These results emphasize the role of proinflammatory macrophages during muscle regrowth in aging and highlight immunometabolic approaches as a route to improve muscle cellular dynamics and regrowth.

Authors

Zachary J. Fennel, Negar Kosari, Paul-Emile Bourrant, Elena M. Yee, Robert J. Castro, Anu S. Kurian, Jonathan Palmer, Morgan Christensen, Katsuhiko Funai, Ryan M. O’Connell, Anhong Zhou, Micah J. Drummond

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Figure 1

Muscle functional recovery from disuse.

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Muscle functional recovery from disuse. (A) Summary of experimental desi...
(A) Summary of experimental design. (BE) Body weight and grip strength (n = 6–20) at baseline (BL), following hind limb unloading (HU), and 4 and 7 days of recovery from HU in old and young mice. (F and G) Ex vivo soleus specific force frequency (mN/mm2) from 10 to 200 Hz (n = 4–5) and representative absolute force tracing (mN) at 200 Hz stimulation from old mice. (H and I) Soleus-specific twitch at optimal length and representative peak twitch tracing. (J) Soleus average rate of relaxation (mN/s) between 20% and 80% of force frequency analysis. In BF, data points represent mean of individual mice; in H and J, each data point represents an individual mouse. Data presented as mean ± SD. *P < 0.05 for difference from BL or between groups; an asterisk (*) over a solid line in BE indicates a difference at or between those time points. Red color indicates hypoxia exposure, white color indicates control. #P < 0.05 for difference from HU. Significance assessed by mixed effects ANOVA (B and C), 2-way ANOVA with Holm-Bonferroni test (DF), or 2-tailed t test (H and J).