ATF4 Coordinates Transcriptomic and Structural Adaptations in Aging Muscle

Amber Crabtree; Mohd Mabood Khan; Estevao Scudese; Calixto Pablo Hernandez Perez; Prasanna Venkhatesh; Andrea G Marshall; Benjamin Rodriguez; Edgar Garza Lopez; Okwute M Ochayi; Estélio Henrique Martin Dantas; Pamela Martin; Matheus Baffi; Fabiana Scartoni; Margaret Mungai; Kit Neikirk; Jennifer Streeter; Renata Oliveira Pereira; Dao Fu Dai; Han Le; Harrison Mobley; Jeremiah Afolabi; Bret C Mobley; Celestine N Wanjalla; Duane Hall; Julia Berry; Oleg Kovtun; Jenny C Schafer; Sean Schaffer; Prasanna Katti; Chantell Evans; Andre Kinder; Joyonna Gamble George; Melanie McReynolds; Annet Kirabo; Sepiso Kenias Masenga; Antentor Hinton

doi:10.64898/2026.03.27.711928

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ATF4 Coordinates Transcriptomic and Structural Adaptations in Aging Muscle

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ATF4 Coordinates Transcriptomic and Structural Adaptations in Aging Muscle

Amber Crabtree, Mohd Mabood Khan, Estevao Scudese, Calixto Pablo Hernandez Perez, Prasanna Venkhatesh, Andrea G Marshall, Benjamin Rodriguez, Edgar Garza Lopez, Okwute M Ochayi, Estélio Henrique Martin Dantas, …

bioRxiv

Cold Spring Harbor Laboratory

03/28/2026

DOI: 10.64898/2026.03.27.711928

PMID: 41929138

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Abstract

Aging is associated with a progressive loss of skeletal muscle function, known as sarcopenia; however, the molecular mechanisms coordinating cellular stress responses and structural adaptations remain incompletely understood. The aim of this study was to investigate the role of activating transcription factor 4 (ATF4), a master regulator of the integrated stress response (ISR), in aging muscle using complementary human population and mouse model approaches. Older adults exhibited a marked decrease in aerobic capacity, muscle strength, and endurance when compared with young participants. These results paralleled findings in aged mice, with significant loss of muscle mass across multiple hindlimb muscles. Ultrastructural analysis revealed substantial age-related changes in mitochondrial morphology, including decreased volume, surface area, and branching index, as well as a shift toward smaller, more fragmented, and spherical mitochondria. These structural changes likely impair oxidative capacity and drive a feed-forward cycle of mitochondrial dysfunction and ISR activation. Our findings indicate that ATF4 coordinates transcriptomic and structural adaptations in aging muscle, identifying the ISR pathway as a potential therapeutic target for preserving muscle function in older adults.Aging is associated with a progressive loss of skeletal muscle function, known as sarcopenia; however, the molecular mechanisms coordinating cellular stress responses and structural adaptations remain incompletely understood. The aim of this study was to investigate the role of activating transcription factor 4 (ATF4), a master regulator of the integrated stress response (ISR), in aging muscle using complementary human population and mouse model approaches. Older adults exhibited a marked decrease in aerobic capacity, muscle strength, and endurance when compared with young participants. These results paralleled findings in aged mice, with significant loss of muscle mass across multiple hindlimb muscles. Ultrastructural analysis revealed substantial age-related changes in mitochondrial morphology, including decreased volume, surface area, and branching index, as well as a shift toward smaller, more fragmented, and spherical mitochondria. These structural changes likely impair oxidative capacity and drive a feed-forward cycle of mitochondrial dysfunction and ISR activation. Our findings indicate that ATF4 coordinates transcriptomic and structural adaptations in aging muscle, identifying the ISR pathway as a potential therapeutic target for preserving muscle function in older adults.

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Title: Subtitle: ATF4 Coordinates Transcriptomic and Structural Adaptations in Aging Muscle
Creators: Amber Crabtree - Vanderbilt University
Mohd Mabood Khan - Vanderbilt University Medical Center
Estevao Scudese - Vanderbilt University
Calixto Pablo Hernandez Perez
Prasanna Venkhatesh - Indian Institute of Science Education and Research, Tirupati
Andrea G Marshall - Meharry Medical College
Benjamin Rodriguez
Edgar Garza Lopez
Okwute M Ochayi - Baze University
Estélio Henrique Martin Dantas - Universidade Tiradentes
Pamela Martin - Meharry Medical College
Matheus Baffi - Universidade Católica de Petrópolis
Fabiana Scartoni - Universidade Federal do Estado do Rio de Janeiro
Margaret Mungai - Vanderbilt University
Kit Neikirk - Vanderbilt University
Jennifer Streeter - University of Iowa
Renata Oliveira Pereira - University of Iowa
Dao Fu Dai - Johns Hopkins University
Han Le - Vanderbilt University
Harrison Mobley - Vanderbilt University
Jeremiah Afolabi - Vanderbilt University Medical Center
Bret C Mobley - Vanderbilt University Medical Center
Celestine N Wanjalla - Vanderbilt University Medical Center
Duane Hall - University of Iowa
Julia Berry - Vanderbilt University Medical Center
Oleg Kovtun - Vanderbilt University
Jenny C Schafer - Vanderbilt University
Sean Schaffer - Vanderbilt University
Prasanna Katti - Indian Institute of Science Education and Research, Tirupati
Chantell Evans - Duke University
Andre Kinder - Faculdade de Medicina de Petrópolis
Joyonna Gamble George - Oregon State University
Melanie McReynolds - Vanderbilt University Medical Center
Annet Kirabo - Vanderbilt University Medical Center
Sepiso Kenias Masenga - Vanderbilt University
Antentor Hinton - Vanderbilt University
Resource Type: Preprint
Publication Details: bioRxiv
DOI: 10.64898/2026.03.27.711928
PMID: 41929138
ISSN: 2692-8205
eISSN: 2692-8205
Publisher: Cold Spring Harbor Laboratory
Language: English
Date posted: 03/28/2026
Academic Unit: Cardiovascular Medicine; Internal Medicine
Record Identifier: 9985149568802771

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