Skeletal muscle Rac1 mediates exercise training adaptations towards muscle glycogen resynthesis and protein synthesis

Steffen H. Raun; Carlos Henriquez-Olguín; Emma Frank; Farina Schlabs; Nanna Just Hahn; Jonas Roland Knudsen; Mona S. Ali; Nicoline R. Andersen; Lisbeth L.V. Møller; Jonathan Davey; Hongwei Qian; Ana Coelho; Christian S. Carl; Christian T. Voldstedlund; Bente Kiens; Rikard Holmdahl; Paul Gregorevic; Thomas E. Jensen; Atul S. Deshmukh; Erik A. Richter; Lykke Sylow

doi:10.1016/j.redox.2025.103844

Skeletal muscle Rac1 mediates exercise training adaptations towards muscle glycogen resynthesis and protein synthesis

Steffen H. Raun^*, Carlos Henriquez-Olguín, Emma Frank, Farina Schlabs, Nanna Just Hahn, Jonas Roland Knudsen, Mona S. Ali, Nicoline R. Andersen, Lisbeth L.V. Møller, Jonathan Davey, Hongwei Qian, Ana Coelho, Christian S. Carl, Christian T. Voldstedlund, Bente Kiens, Rikard Holmdahl, Paul Gregorevic, Thomas E. Jensen, Atul S. Deshmukh, Erik A. RichterLykke Sylow^*

^*Corresponding author af dette arbejde

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

3 Citationer (Scopus)

3 Downloads (Pure)

Abstract

Long-term exercise training elicits tremendous health benefits; however, the molecular understanding is incomplete and identifying therapeutic targets has been challenging. Rho GTPases are among the most regulated groups of proteins after exercise in human skeletal muscle, yet, unexplored candidates for mediating the effects of exercise training. We found that the Rho GTPase Rac1 was activated acutely after multiple exercise modalities in human skeletal muscle. Loss of Rac1 specifically in muscle attenuated contraction-induced muscle protein synthesis, diminished improvements in running capacity, and prevented muscle hypertrophy after exercise training in mice. Additionally, Ncf1∗ mice revealed that Rac1 regulated glycogen resynthesis via a NOX2-dependent mechanism. Molecularly, Rac1 was required for contraction-induced p38MAPK signaling towards HSP27, MNK1, and CREB phosphorylation. In vivo muscle-targeted overexpression of a hyperactive Rac1-mutant elevated reactive oxidant species production during exercise but did not affect muscle mass. Using mass spectrometry-based proteomics, we found that loss or gain of Rac1 muscle protein affected pathways related to cytoskeleton organization, muscle adaptation, and large ribosomal subunits. Thus, skeletal muscle Rac1 mediates both molecular and functional adaptation to exercise training.

Originalsprog	Engelsk
Artikelnummer	103844
Tidsskrift	Redox Biology
Vol/bind	86
Antal sider	14
ISSN	2213-2317
DOI	https://doi.org/10.1016/j.redox.2025.103844
Status	Udgivet - 2025

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Raun, S. H., Henriquez-Olguín, C., Frank, E., Schlabs, F., Hahn, N. J., Knudsen, J. R., Ali, M. S., Andersen, N. R., Møller, L. L. V., Davey, J., Qian, H., Coelho, A., Carl, C. S., Voldstedlund, C. T., Kiens, B., Holmdahl, R., Gregorevic, P., Jensen, T. E., Deshmukh, A. S., ... Sylow, L. (2025). Skeletal muscle Rac1 mediates exercise training adaptations towards muscle glycogen resynthesis and protein synthesis. Redox Biology, 86, Artikel 103844. https://doi.org/10.1016/j.redox.2025.103844

Raun, SH , Henriquez-Olguín, C , Frank, E , Schlabs, F, Hahn, NJ, Knudsen, JR, Ali, MS, Andersen, NR , Møller, LLV, Davey, J, Qian, H, Coelho, A, Carl, CS , Voldstedlund, CT , Kiens, B, Holmdahl, R, Gregorevic, P, Jensen, TE , Deshmukh, AS , Richter, EA & Sylow, L 2025, 'Skeletal muscle Rac1 mediates exercise training adaptations towards muscle glycogen resynthesis and protein synthesis', Redox Biology, bind 86, 103844. https://doi.org/10.1016/j.redox.2025.103844

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title = "Skeletal muscle Rac1 mediates exercise training adaptations towards muscle glycogen resynthesis and protein synthesis",

abstract = "Long-term exercise training elicits tremendous health benefits; however, the molecular understanding is incomplete and identifying therapeutic targets has been challenging. Rho GTPases are among the most regulated groups of proteins after exercise in human skeletal muscle, yet, unexplored candidates for mediating the effects of exercise training. We found that the Rho GTPase Rac1 was activated acutely after multiple exercise modalities in human skeletal muscle. Loss of Rac1 specifically in muscle attenuated contraction-induced muscle protein synthesis, diminished improvements in running capacity, and prevented muscle hypertrophy after exercise training in mice. Additionally, Ncf1∗ mice revealed that Rac1 regulated glycogen resynthesis via a NOX2-dependent mechanism. Molecularly, Rac1 was required for contraction-induced p38MAPK signaling towards HSP27, MNK1, and CREB phosphorylation. In vivo muscle-targeted overexpression of a hyperactive Rac1-mutant elevated reactive oxidant species production during exercise but did not affect muscle mass. Using mass spectrometry-based proteomics, we found that loss or gain of Rac1 muscle protein affected pathways related to cytoskeleton organization, muscle adaptation, and large ribosomal subunits. Thus, skeletal muscle Rac1 mediates both molecular and functional adaptation to exercise training.",

keywords = "Contraction, Exercise training, Glycogen, Metabolism, Muscle hypertrophy, Protein synthesis, Rac1, Skeletal muscle",

author = "Raun, {Steffen H.} and Carlos Henriquez-Olgu{\'i}n and Emma Frank and Farina Schlabs and Hahn, {Nanna Just} and Knudsen, {Jonas Roland} and Ali, {Mona S.} and Andersen, {Nicoline R.} and M{\o}ller, {Lisbeth L.V.} and Jonathan Davey and Hongwei Qian and Ana Coelho and Carl, {Christian S.} and Voldstedlund, {Christian T.} and Bente Kiens and Rikard Holmdahl and Paul Gregorevic and Jensen, {Thomas E.} and Deshmukh, {Atul S.} and Richter, {Erik A.} and Lykke Sylow",

note = "Publisher Copyright: {\textcopyright} 2025",

year = "2025",

doi = "10.1016/j.redox.2025.103844",

language = "English",

volume = "86",

journal = "Redox Biology",

issn = "2213-2317",

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TY - JOUR

T1 - Skeletal muscle Rac1 mediates exercise training adaptations towards muscle glycogen resynthesis and protein synthesis

AU - Raun, Steffen H.

AU - Henriquez-Olguín, Carlos

AU - Frank, Emma

AU - Schlabs, Farina

AU - Hahn, Nanna Just

AU - Knudsen, Jonas Roland

AU - Ali, Mona S.

AU - Andersen, Nicoline R.

AU - Møller, Lisbeth L.V.

AU - Davey, Jonathan

AU - Qian, Hongwei

AU - Coelho, Ana

AU - Carl, Christian S.

AU - Voldstedlund, Christian T.

AU - Kiens, Bente

AU - Holmdahl, Rikard

AU - Gregorevic, Paul

AU - Jensen, Thomas E.

AU - Deshmukh, Atul S.

AU - Richter, Erik A.

AU - Sylow, Lykke

PY - 2025

Y1 - 2025

N2 - Long-term exercise training elicits tremendous health benefits; however, the molecular understanding is incomplete and identifying therapeutic targets has been challenging. Rho GTPases are among the most regulated groups of proteins after exercise in human skeletal muscle, yet, unexplored candidates for mediating the effects of exercise training. We found that the Rho GTPase Rac1 was activated acutely after multiple exercise modalities in human skeletal muscle. Loss of Rac1 specifically in muscle attenuated contraction-induced muscle protein synthesis, diminished improvements in running capacity, and prevented muscle hypertrophy after exercise training in mice. Additionally, Ncf1∗ mice revealed that Rac1 regulated glycogen resynthesis via a NOX2-dependent mechanism. Molecularly, Rac1 was required for contraction-induced p38MAPK signaling towards HSP27, MNK1, and CREB phosphorylation. In vivo muscle-targeted overexpression of a hyperactive Rac1-mutant elevated reactive oxidant species production during exercise but did not affect muscle mass. Using mass spectrometry-based proteomics, we found that loss or gain of Rac1 muscle protein affected pathways related to cytoskeleton organization, muscle adaptation, and large ribosomal subunits. Thus, skeletal muscle Rac1 mediates both molecular and functional adaptation to exercise training.

AB - Long-term exercise training elicits tremendous health benefits; however, the molecular understanding is incomplete and identifying therapeutic targets has been challenging. Rho GTPases are among the most regulated groups of proteins after exercise in human skeletal muscle, yet, unexplored candidates for mediating the effects of exercise training. We found that the Rho GTPase Rac1 was activated acutely after multiple exercise modalities in human skeletal muscle. Loss of Rac1 specifically in muscle attenuated contraction-induced muscle protein synthesis, diminished improvements in running capacity, and prevented muscle hypertrophy after exercise training in mice. Additionally, Ncf1∗ mice revealed that Rac1 regulated glycogen resynthesis via a NOX2-dependent mechanism. Molecularly, Rac1 was required for contraction-induced p38MAPK signaling towards HSP27, MNK1, and CREB phosphorylation. In vivo muscle-targeted overexpression of a hyperactive Rac1-mutant elevated reactive oxidant species production during exercise but did not affect muscle mass. Using mass spectrometry-based proteomics, we found that loss or gain of Rac1 muscle protein affected pathways related to cytoskeleton organization, muscle adaptation, and large ribosomal subunits. Thus, skeletal muscle Rac1 mediates both molecular and functional adaptation to exercise training.

KW - Contraction

KW - Exercise training

KW - Glycogen

KW - Metabolism

KW - Muscle hypertrophy

KW - Protein synthesis

KW - Rac1

KW - Skeletal muscle

U2 - 10.1016/j.redox.2025.103844

DO - 10.1016/j.redox.2025.103844

M3 - Journal article

C2 - 40886619

AN - SCOPUS:105014537995

SN - 2213-2317

VL - 86

JO - Redox Biology

JF - Redox Biology

M1 - 103844

ER -