At the Nexus Between Epigenetics and Senescence: The Effects of Senolytic (BI01) Administration on DNA Methylation Clock Age and the Methylome in Aged and Regenerated Skeletal Muscle

Toby L. Chambers; Jaden Wells; Pieter Jan Koopmans; Francielly Morena; Zain B. Malik; Nicholas P. Greene; Antonio Filareto; Michael Franti; Patrizia Sini; Harald Weinstabl; Robert T. Brooke; Milda Milčiūtė; Juozas Gordevičius; Steve Horvath; Yuan Wen; Cory M. Dungan; Kevin A. Murach

doi:10.1111/acel.70068

At the Nexus Between Epigenetics and Senescence: The Effects of Senolytic (BI01) Administration on DNA Methylation Clock Age and the Methylome in Aged and Regenerated Skeletal Muscle

Toby L. Chambers, Jaden Wells, Pieter Jan Koopmans, Francielly Morena, Zain B. Malik, Nicholas P. Greene, Antonio Filareto, Michael Franti, Patrizia Sini, Harald Weinstabl, Robert T. Brooke, Milda Milčiūtė, Juozas Gordevičius, Steve Horvath, Yuan Wen, Cory M. Dungan, Kevin A. Murach

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

3 Scopus citations

Abstract

Senescent cells emerge with aging and injury. The contribution of senescent cells to DNA methylation age (DNAmAGE) in vivo is uncertain. Furthermore, stem cell therapy can mediate “rejuvenation”, but how tissue regeneration controlled by resident stem cells affects whole tissue DNAmAGE is unclear. We assessed DNAmAGE with or without senolytics (BI01) in aged male mice (24–25 months) 35 days following muscle healing (BaCl₂-induced regeneration versus non-injured). Young injured mice (5–6 months) without senolytics were comparators. DNAmAGE was decelerated by up to 68% after injury in aged muscle. DNAmAGE was modestly but further significantly decelerated by injury recovery with senolytics. ~1/4 of measured CpGs were altered by injury then recovery regardless of senolytics in aged muscle. Specific methylation changes caused by senolytics included differential regulation of Col, Hdac, Hox, and Wnt genes, which likely contributed to improved regeneration. Altered extracellular matrix remodeling using histological analysis aligned with the methylomic findings with senolytics. Without senolytics, regeneration had a contrasting effect in young mice and tended not to influence or modestly accelerate DNAmAGE. Comparing young to old injury recovery without senolytics using methylome-transcriptome integration, we found a more coordinated molecular profile in young and differential regulation of genes implicated in muscle stem cell performance: Axin2, Egr1, Fzd4, Meg3, and Spry1. Muscle injury and senescent cells affect DNAmAGE and aging influences the transcriptomic-methylomic landscape after resident stem cell-driven tissue reformation. Our data have implications for understanding muscle plasticity with aging and developing therapies aimed at collagen remodeling and senescence.

Original language	English
Article number	e70068
Journal	Aging Cell
Volume	24
Issue number	7
DOIs	https://doi.org/10.1111/acel.70068
State	Published - Jul 2025

Bibliographical note

Publisher Copyright:
© 2025 The Author(s). Aging Cell published by Anatomical Society and John Wiley & Sons Ltd.

Funding

Funding: This study was supported by NIH grants AG063944 and AG080047 to K.A.M. This work was performed while K.A.M. was a Glenn Foundation/American Federation for Aging Research Junior Investigator Awardee. The authors thank Charlotte A. Peterson, PhD, for supporting this project (NIH grants AG049806 and AG069909). The authors also thank Christopher S. Fry, PhD, for his input on R-CHP analysis. The graphical abstract and Figure 1A were generated using BioRender. This study was supported by NIH grants AG063944 and AG080047 to K.A.M. This work was performed while K.A.M. was a Glenn Foundation/American Federation for Aging Research Junior Investigator Awardee. Funding: Asb Col Fgfrl1 Fzd5 Hdac Hox Mapk Smad4 Wnt The authors thank Charlotte A. Peterson, PhD, for supporting this project (NIH grants AG049806 and AG069909). The authors also thank Christopher S. Fry, PhD, for his input on R‐CHP analysis. The graphical abstract and Figure 1A were generated using BioRender.

Funders	Funder number
Glenn Foundation for Medical Research
National Institutes of Health (NIH)	AG063944, AG069909, AG049806, AG080047
American Goat Federation	AG069909, AG049806

Keywords

DNAmAGE
aging
extracellular matrix
methylation clock
omics integration

ASJC Scopus subject areas

Aging
Cell Biology

Access to Document

10.1111/acel.70068

Cite this

Chambers, T. L., Wells, J., Koopmans, P. J., Morena, F., Malik, Z. B., Greene, N. P., Filareto, A., Franti, M., Sini, P., Weinstabl, H., Brooke, R. T., Milčiūtė, M., Gordevičius, J., Horvath, S., Wen, Y., Dungan, C. M., & Murach, K. A. (2025). At the Nexus Between Epigenetics and Senescence: The Effects of Senolytic (BI01) Administration on DNA Methylation Clock Age and the Methylome in Aged and Regenerated Skeletal Muscle. Aging Cell, 24(7), Article e70068. https://doi.org/10.1111/acel.70068

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title = "At the Nexus Between Epigenetics and Senescence: The Effects of Senolytic (BI01) Administration on DNA Methylation Clock Age and the Methylome in Aged and Regenerated Skeletal Muscle",

abstract = "Senescent cells emerge with aging and injury. The contribution of senescent cells to DNA methylation age (DNAmAGE) in vivo is uncertain. Furthermore, stem cell therapy can mediate “rejuvenation”, but how tissue regeneration controlled by resident stem cells affects whole tissue DNAmAGE is unclear. We assessed DNAmAGE with or without senolytics (BI01) in aged male mice (24–25 months) 35 days following muscle healing (BaCl2-induced regeneration versus non-injured). Young injured mice (5–6 months) without senolytics were comparators. DNAmAGE was decelerated by up to 68\% after injury in aged muscle. DNAmAGE was modestly but further significantly decelerated by injury recovery with senolytics. \textasciitilde{}1/4 of measured CpGs were altered by injury then recovery regardless of senolytics in aged muscle. Specific methylation changes caused by senolytics included differential regulation of Col, Hdac, Hox, and Wnt genes, which likely contributed to improved regeneration. Altered extracellular matrix remodeling using histological analysis aligned with the methylomic findings with senolytics. Without senolytics, regeneration had a contrasting effect in young mice and tended not to influence or modestly accelerate DNAmAGE. Comparing young to old injury recovery without senolytics using methylome-transcriptome integration, we found a more coordinated molecular profile in young and differential regulation of genes implicated in muscle stem cell performance: Axin2, Egr1, Fzd4, Meg3, and Spry1. Muscle injury and senescent cells affect DNAmAGE and aging influences the transcriptomic-methylomic landscape after resident stem cell-driven tissue reformation. Our data have implications for understanding muscle plasticity with aging and developing therapies aimed at collagen remodeling and senescence.",

keywords = "DNAmAGE, aging, extracellular matrix, methylation clock, omics integration",

author = "Chambers, \{Toby L.\} and Jaden Wells and Koopmans, \{Pieter Jan\} and Francielly Morena and Malik, \{Zain B.\} and Greene, \{Nicholas P.\} and Antonio Filareto and Michael Franti and Patrizia Sini and Harald Weinstabl and Brooke, \{Robert T.\} and Milda Mil{\v c}iūtė and Juozas Gordevi{\v c}ius and Steve Horvath and Yuan Wen and Dungan, \{Cory M.\} and Murach, \{Kevin A.\}",

note = "Publisher Copyright: {\textcopyright} 2025 The Author(s). Aging Cell published by Anatomical Society and John Wiley \& Sons Ltd.",

year = "2025",

month = jul,

doi = "10.1111/acel.70068",

language = "English",

volume = "24",

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Chambers, TL, Wells, J, Koopmans, PJ, Morena, F, Malik, ZB, Greene, NP, Filareto, A, Franti, M, Sini, P, Weinstabl, H, Brooke, RT, Milčiūtė, M, Gordevičius, J, Horvath, S, Wen, Y, Dungan, CM & Murach, KA 2025, 'At the Nexus Between Epigenetics and Senescence: The Effects of Senolytic (BI01) Administration on DNA Methylation Clock Age and the Methylome in Aged and Regenerated Skeletal Muscle', Aging Cell, vol. 24, no. 7, e70068. https://doi.org/10.1111/acel.70068

TY - JOUR

T1 - At the Nexus Between Epigenetics and Senescence

T2 - The Effects of Senolytic (BI01) Administration on DNA Methylation Clock Age and the Methylome in Aged and Regenerated Skeletal Muscle

AU - Chambers, Toby L.

AU - Wells, Jaden

AU - Koopmans, Pieter Jan

AU - Morena, Francielly

AU - Malik, Zain B.

AU - Greene, Nicholas P.

AU - Filareto, Antonio

AU - Franti, Michael

AU - Sini, Patrizia

AU - Weinstabl, Harald

AU - Brooke, Robert T.

AU - Milčiūtė, Milda

AU - Gordevičius, Juozas

AU - Horvath, Steve

AU - Wen, Yuan

AU - Dungan, Cory M.

AU - Murach, Kevin A.

PY - 2025/7

Y1 - 2025/7

N2 - Senescent cells emerge with aging and injury. The contribution of senescent cells to DNA methylation age (DNAmAGE) in vivo is uncertain. Furthermore, stem cell therapy can mediate “rejuvenation”, but how tissue regeneration controlled by resident stem cells affects whole tissue DNAmAGE is unclear. We assessed DNAmAGE with or without senolytics (BI01) in aged male mice (24–25 months) 35 days following muscle healing (BaCl2-induced regeneration versus non-injured). Young injured mice (5–6 months) without senolytics were comparators. DNAmAGE was decelerated by up to 68% after injury in aged muscle. DNAmAGE was modestly but further significantly decelerated by injury recovery with senolytics. ~1/4 of measured CpGs were altered by injury then recovery regardless of senolytics in aged muscle. Specific methylation changes caused by senolytics included differential regulation of Col, Hdac, Hox, and Wnt genes, which likely contributed to improved regeneration. Altered extracellular matrix remodeling using histological analysis aligned with the methylomic findings with senolytics. Without senolytics, regeneration had a contrasting effect in young mice and tended not to influence or modestly accelerate DNAmAGE. Comparing young to old injury recovery without senolytics using methylome-transcriptome integration, we found a more coordinated molecular profile in young and differential regulation of genes implicated in muscle stem cell performance: Axin2, Egr1, Fzd4, Meg3, and Spry1. Muscle injury and senescent cells affect DNAmAGE and aging influences the transcriptomic-methylomic landscape after resident stem cell-driven tissue reformation. Our data have implications for understanding muscle plasticity with aging and developing therapies aimed at collagen remodeling and senescence.

AB - Senescent cells emerge with aging and injury. The contribution of senescent cells to DNA methylation age (DNAmAGE) in vivo is uncertain. Furthermore, stem cell therapy can mediate “rejuvenation”, but how tissue regeneration controlled by resident stem cells affects whole tissue DNAmAGE is unclear. We assessed DNAmAGE with or without senolytics (BI01) in aged male mice (24–25 months) 35 days following muscle healing (BaCl2-induced regeneration versus non-injured). Young injured mice (5–6 months) without senolytics were comparators. DNAmAGE was decelerated by up to 68% after injury in aged muscle. DNAmAGE was modestly but further significantly decelerated by injury recovery with senolytics. ~1/4 of measured CpGs were altered by injury then recovery regardless of senolytics in aged muscle. Specific methylation changes caused by senolytics included differential regulation of Col, Hdac, Hox, and Wnt genes, which likely contributed to improved regeneration. Altered extracellular matrix remodeling using histological analysis aligned with the methylomic findings with senolytics. Without senolytics, regeneration had a contrasting effect in young mice and tended not to influence or modestly accelerate DNAmAGE. Comparing young to old injury recovery without senolytics using methylome-transcriptome integration, we found a more coordinated molecular profile in young and differential regulation of genes implicated in muscle stem cell performance: Axin2, Egr1, Fzd4, Meg3, and Spry1. Muscle injury and senescent cells affect DNAmAGE and aging influences the transcriptomic-methylomic landscape after resident stem cell-driven tissue reformation. Our data have implications for understanding muscle plasticity with aging and developing therapies aimed at collagen remodeling and senescence.

KW - DNAmAGE

KW - aging

KW - extracellular matrix

KW - methylation clock

KW - omics integration

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UR - https://www.scopus.com/inward/citedby.url?scp=105005190833&partnerID=8YFLogxK

U2 - 10.1111/acel.70068

DO - 10.1111/acel.70068

M3 - Article

C2 - 40259517

AN - SCOPUS:105005190833

SN - 1474-9718

VL - 24

JO - Aging Cell

JF - Aging Cell

IS - 7

M1 - e70068

ER -

At the Nexus Between Epigenetics and Senescence: The Effects of Senolytic (BI01) Administration on DNA Methylation Clock Age and the Methylome in Aged and Regenerated Skeletal Muscle

Abstract

Bibliographical note

Funding

Keywords

ASJC Scopus subject areas

Access to Document

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