Vitamin A retinoic acid contributes to muscle stem cell and mitochondrial function loss in old age
Paula M. Fraczek, … , Jacqueline A. Larouche, Carlos A. Aguilar
Paula M. Fraczek, … , Jacqueline A. Larouche, Carlos A. Aguilar
Published March 25, 2025
Citation Information: JCI Insight. 2025;10(9):e183706. https://doi.org/10.1172/jci.insight.183706.
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Research Article Aging Muscle biology Stem cells

Vitamin A retinoic acid contributes to muscle stem cell and mitochondrial function loss in old age

Abstract

Adult stem cells decline in number and function in old age, and identifying factors that can delay or revert age-associated adult stem cell dysfunction are vital for maintaining a healthy lifespan. Here we show that vitamin A, a micronutrient that is derived from diet and metabolized into retinoic acid, acts as an antioxidant and transcriptional regulator in muscle stem cells. We first show that obstruction of dietary vitamin A in young animals drives mitochondrial and cell cycle dysfunction in muscle stem cells that mimics old age. Next, we pharmacologically targeted retinoic acid signaling in myoblasts and aged muscle stem cells ex vivo and in vivo and observed reductions in oxidative damage, enhanced mitochondrial function, and improved maintenance of quiescence through fatty acid oxidation. We next detected that the receptor for vitamin A–derived retinol, stimulated by retinoic acid 6 or Stra6, was diminished with muscle stem cell activation and in old age. To understand the relevance of Stra6 loss, we knocked down Stra6 and observed an accumulation of mitochondrial reactive oxygen species, as well as changes in mitochondrial morphology and respiration. These results demonstrate that vitamin A regulates mitochondria and metabolism in muscle stem cells and highlight a unique mechanism connecting stem cell function with vitamin intake.

Authors

Paula M. Fraczek, Pamela Duran, Benjamin A. Yang, Valeria Ferre, Leanne Alawieh, Jesus A. Castor-Macias, Vivian T. Wong, Steve D. Guzman, Celeste Piotto, Klimentini Itsani, Jacqueline A. Larouche, Carlos A. Aguilar

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Figure 6

Stra6 loss induces mitochondrial dysfunction.

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Stra6 loss induces mitochondrial dysfunction. (A) Representative image o...
(A) Representative image of mitochondrial membrane depolarization via JC-1 labeling (represented as ratio of red/green fluorescence) and representative images of red JC-1 aggregates indicating healthy, polarized mitochondria and Hoechst-counterstained nuclei (scale bars = 100 µm; Stra6-knockdown cells on the right and negative control siRNA cells on the left). (B) Quantification of JC-1 Red/Green ratio for knockdown and control, n = 3 wells per condition. Comparisons made via t test. Data are represented as averages across samples showing mean ± SEM. (C) Quantification of mitochondrial ROS using MitoTracker Orange CM-H2TMRos normalized to total mitochondrial stained by MitoTracker Deep Red (n = 3 wells per condition). (D) Quantification of Ki67 mean fluorescence intensity (n = 6 image fields across 2 wells per condition) after siRNA knockdown of Stra6 (blue) or negative control (red). (E) Line graphs of oxygen consumption rate (OCR) measured via Seahorse XFe96 Mito Stress Test in Stra6-knockdown cells (blue line, n = 11 wells) and negative control cells (red line, n = 12 wells) after injections of oligomycin, FCCP, and rotenone/antimycin A. (FI) Quantification of OCR during basal cell respiration (F), change in OCR related to ATP production (G), proton leak (H), and OCR/ECAR ratio (I) in Stra6-knockdown cells and negative control cells. Comparisons of Seahorse Mito Stress parameters were made via t test. *P < 0.05, **P < 0.01, ***P < 0.001.