Ablation of satellite cell-specific clock gene, Bmal1, alters force production, muscle damage, and repair following contractile-induced injury

Ryan E. Kahn; Pei Zhu; Ishan Roy; Clara Peek; John A. Hawley; Sudarshan Dayanidhi

doi:10.1096/fj.202402145RR

Ablation of satellite cell-specific clock gene, Bmal1, alters force production, muscle damage, and repair following contractile-induced injury

Ryan E. Kahn, Pei Zhu, Ishan Roy, Clara Peek, John A. Hawley^*, Sudarshan Dayanidhi^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

Abstract

Following injury, skeletal muscle undergoes repair via satellite cell (SC)-mediated myogenic progression. In SCs, the circadian molecular clock gene, Bmal1, is necessary for appropriate myogenic progression and repair with evidence that muscle molecular clocks can also affect force production. Utilizing a mouse model allowing for inducible depletion of Bmal1 within SCs, we determined contractile function, SC myogenic progression and muscle damage and repair following eccentric contractile-induced injury. At baseline, SC-Bmal1^iKO animals exhibited a ~20–25% reduction in normalized force production (ex vivo and in vivo) versus control SC-Bmal1^Cntrl and SC-Bmal1^iKO untreated littermates (p <.05). Following contractile injury, SC-Bmal1^iKO animals displayed reduced muscle damage and subsequent repair post-injury (Dystrophin^negative fibers 24 h: SC-Bmal1^Cntrl 199 ± 41; SC-Bmal1^iKO 36 ± 13, p <.05) (eMHC⁺ fibers 7 day: SC-Bmal1^Cntrl 217.8 ± 115.5; SC-Bmal1^iKO 27.8 ± 17.3; Centralized nuclei 7 day: SC-Bmal1^Cntrl 160.7 ± 70.5; SC-Bmal1^iKO 46.2 ± 15.7). SC-Bmal1^iKO animals also showed reduced neutrophil infiltration, consistent with less injury (Neutrophil content 24 h: SC-Bmal1^Cntrl 2.4 ± 0.4; SC-Bmal1^iKO 0.4 ± 0.2, % area fraction, p <.05). SC-Bmal1^iKO animals had greater SC activation/proliferation at an earlier timepoint (p <.05) and an unexplained increase in activation 7 days post injury. Collectively, these data suggest SC-Bmal1 plays a regulatory role in force production, influencing the magnitude of muscle damage/repair, with an altered SC myogenic progression following contractile-induced muscle injury.

Original language	English (US)
Article number	e70325
Journal	FASEB Journal
Volume	39
Issue number	2
DOIs	https://doi.org/10.1096/fj.202402145RR
State	Published - Jan 31 2025

Funding

We acknowledge extensive discussions with Professors Orly Lacham\u2010Kaplan and Leonidas Karagounis. We thank Rick Lieber for the use of his ex vivo contractility setup. This work was supported, in part, by a Novo Nordisk Foundation Challenge Grant (NNF14OC0011493) to JAH, National Institutes of Health grant HD094602 to SD. Graphical abstract created on BioRender.com .

Keywords

contractile injury
force production
molecular clocks
muscle repair
muscle stem cells
myogenic progression

ASJC Scopus subject areas

Biotechnology
Biochemistry
Molecular Biology
Genetics

Access to Document

10.1096/fj.202402145RR

Cite this

@article{d0f8499948d6483e93d5b5731b672df4,

title = "Ablation of satellite cell-specific clock gene, Bmal1, alters force production, muscle damage, and repair following contractile-induced injury",

abstract = "Following injury, skeletal muscle undergoes repair via satellite cell (SC)-mediated myogenic progression. In SCs, the circadian molecular clock gene, Bmal1, is necessary for appropriate myogenic progression and repair with evidence that muscle molecular clocks can also affect force production. Utilizing a mouse model allowing for inducible depletion of Bmal1 within SCs, we determined contractile function, SC myogenic progression and muscle damage and repair following eccentric contractile-induced injury. At baseline, SC-Bmal1iKO animals exhibited a ~20–25% reduction in normalized force production (ex vivo and in vivo) versus control SC-Bmal1Cntrl and SC-Bmal1iKO untreated littermates (p <.05). Following contractile injury, SC-Bmal1iKO animals displayed reduced muscle damage and subsequent repair post-injury (Dystrophinnegative fibers 24 h: SC-Bmal1Cntrl 199 ± 41; SC-Bmal1iKO 36 ± 13, p <.05) (eMHC+ fibers 7 day: SC-Bmal1Cntrl 217.8 ± 115.5; SC-Bmal1iKO 27.8 ± 17.3; Centralized nuclei 7 day: SC-Bmal1Cntrl 160.7 ± 70.5; SC-Bmal1iKO 46.2 ± 15.7). SC-Bmal1iKO animals also showed reduced neutrophil infiltration, consistent with less injury (Neutrophil content 24 h: SC-Bmal1Cntrl 2.4 ± 0.4; SC-Bmal1iKO 0.4 ± 0.2, % area fraction, p <.05). SC-Bmal1iKO animals had greater SC activation/proliferation at an earlier timepoint (p <.05) and an unexplained increase in activation 7 days post injury. Collectively, these data suggest SC-Bmal1 plays a regulatory role in force production, influencing the magnitude of muscle damage/repair, with an altered SC myogenic progression following contractile-induced muscle injury.",

keywords = "contractile injury, force production, molecular clocks, muscle repair, muscle stem cells, myogenic progression",

author = "Kahn, {Ryan E.} and Pei Zhu and Ishan Roy and Clara Peek and Hawley, {John A.} and Sudarshan Dayanidhi",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). The FASEB Journal published by Wiley Periodicals LLC on behalf of Federation of American Societies for Experimental Biology.",

year = "2025",

month = jan,

day = "31",

doi = "10.1096/fj.202402145RR",

language = "English (US)",

volume = "39",

journal = "FASEB Journal",

issn = "0892-6638",

publisher = "John Wiley & Sons Inc.",

number = "2",

}

TY - JOUR

T1 - Ablation of satellite cell-specific clock gene, Bmal1, alters force production, muscle damage, and repair following contractile-induced injury

AU - Kahn, Ryan E.

AU - Zhu, Pei

AU - Roy, Ishan

AU - Peek, Clara

AU - Hawley, John A.

AU - Dayanidhi, Sudarshan

PY - 2025/1/31

Y1 - 2025/1/31

N2 - Following injury, skeletal muscle undergoes repair via satellite cell (SC)-mediated myogenic progression. In SCs, the circadian molecular clock gene, Bmal1, is necessary for appropriate myogenic progression and repair with evidence that muscle molecular clocks can also affect force production. Utilizing a mouse model allowing for inducible depletion of Bmal1 within SCs, we determined contractile function, SC myogenic progression and muscle damage and repair following eccentric contractile-induced injury. At baseline, SC-Bmal1iKO animals exhibited a ~20–25% reduction in normalized force production (ex vivo and in vivo) versus control SC-Bmal1Cntrl and SC-Bmal1iKO untreated littermates (p <.05). Following contractile injury, SC-Bmal1iKO animals displayed reduced muscle damage and subsequent repair post-injury (Dystrophinnegative fibers 24 h: SC-Bmal1Cntrl 199 ± 41; SC-Bmal1iKO 36 ± 13, p <.05) (eMHC+ fibers 7 day: SC-Bmal1Cntrl 217.8 ± 115.5; SC-Bmal1iKO 27.8 ± 17.3; Centralized nuclei 7 day: SC-Bmal1Cntrl 160.7 ± 70.5; SC-Bmal1iKO 46.2 ± 15.7). SC-Bmal1iKO animals also showed reduced neutrophil infiltration, consistent with less injury (Neutrophil content 24 h: SC-Bmal1Cntrl 2.4 ± 0.4; SC-Bmal1iKO 0.4 ± 0.2, % area fraction, p <.05). SC-Bmal1iKO animals had greater SC activation/proliferation at an earlier timepoint (p <.05) and an unexplained increase in activation 7 days post injury. Collectively, these data suggest SC-Bmal1 plays a regulatory role in force production, influencing the magnitude of muscle damage/repair, with an altered SC myogenic progression following contractile-induced muscle injury.

AB - Following injury, skeletal muscle undergoes repair via satellite cell (SC)-mediated myogenic progression. In SCs, the circadian molecular clock gene, Bmal1, is necessary for appropriate myogenic progression and repair with evidence that muscle molecular clocks can also affect force production. Utilizing a mouse model allowing for inducible depletion of Bmal1 within SCs, we determined contractile function, SC myogenic progression and muscle damage and repair following eccentric contractile-induced injury. At baseline, SC-Bmal1iKO animals exhibited a ~20–25% reduction in normalized force production (ex vivo and in vivo) versus control SC-Bmal1Cntrl and SC-Bmal1iKO untreated littermates (p <.05). Following contractile injury, SC-Bmal1iKO animals displayed reduced muscle damage and subsequent repair post-injury (Dystrophinnegative fibers 24 h: SC-Bmal1Cntrl 199 ± 41; SC-Bmal1iKO 36 ± 13, p <.05) (eMHC+ fibers 7 day: SC-Bmal1Cntrl 217.8 ± 115.5; SC-Bmal1iKO 27.8 ± 17.3; Centralized nuclei 7 day: SC-Bmal1Cntrl 160.7 ± 70.5; SC-Bmal1iKO 46.2 ± 15.7). SC-Bmal1iKO animals also showed reduced neutrophil infiltration, consistent with less injury (Neutrophil content 24 h: SC-Bmal1Cntrl 2.4 ± 0.4; SC-Bmal1iKO 0.4 ± 0.2, % area fraction, p <.05). SC-Bmal1iKO animals had greater SC activation/proliferation at an earlier timepoint (p <.05) and an unexplained increase in activation 7 days post injury. Collectively, these data suggest SC-Bmal1 plays a regulatory role in force production, influencing the magnitude of muscle damage/repair, with an altered SC myogenic progression following contractile-induced muscle injury.

KW - contractile injury

KW - force production

KW - molecular clocks

KW - muscle repair

KW - muscle stem cells

KW - myogenic progression

UR - http://www.scopus.com/inward/record.url?scp=85215288370&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=85215288370&partnerID=8YFLogxK

U2 - 10.1096/fj.202402145RR

DO - 10.1096/fj.202402145RR

M3 - Article

C2 - 39812604

AN - SCOPUS:85215288370

SN - 0892-6638

VL - 39

JO - FASEB Journal

JF - FASEB Journal

IS - 2

M1 - e70325

ER -

Ablation of satellite cell-specific clock gene, Bmal1, alters force production, muscle damage, and repair following contractile-induced injury

Abstract

Funding

Keywords

ASJC Scopus subject areas

Access to Document

Other files and links

Fingerprint

Cite this