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Microgravity Accelerates Skeletal Muscle Degeneration: Functional and Transcriptomic Insights from a Muscle Lab-on-Chip Model Onboard the ISS.

Guardado en:
Publicado en:bioRxiv (Jan 27, 2025)
Autor principal: Parafati, Maddalena
Otros Autores: Zon Thwin, Malany, Legrand K, Coen, Paul M, Malany, Siobhan
Publicado:
Cold Spring Harbor Laboratory Press
Materias:
Gene expression
Comparative analysis
Microfluidics
Patent applications
Musculoskeletal system
Skeletal muscle
Aging
Lab-on-a-chip
Weightlessness
Degeneration
Microgravity
Muscle contraction
Atrophy
Transcriptomics
Cellular stress response
Electrical stimuli
Immune response
Inflammation
Acceso en línea:Citation/Abstract
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Resumen:Microgravity accelerates skeletal muscle degeneration, mimicking aging, yet its effects on human muscle cell function and signaling remain underexplored. Using a muscle lab-on-chip model onboard the International Space Station, we examined how microgravity and electrically stimulated contractions influence muscle biology and age-related muscle changes. Our 3D bioengineered muscle model, cultured for 21 days (12 days in microgravity), included myobundles from young, active and older, sedentary individuals, with and without electrically stimulated contraction. Real-time data collected within an autonomous Space Tango CubeLabTM showed reduced contraction magnitude in microgravity. Global transcriptomic analysis revealed increased gene expression and particularly mitochondrial-related gene expression in microgravity for the electrically stimulated younger myobundles, while the older myobundles were less responsive. Moreover, a comparative analysis using a skeletal muscle aging gene expression database revealed that certain age-induced genes showed changes in expression in myobundles from the younger cohort when exposed to microgravity, whereas these genes remained unchanged in myobundles from the older cohort. Younger, electrically stimulated myobundles in microgravity exhibited higher expression of 45 aging genes involved in key aging pathways related to inflammation and immune function, mitochondrial dysfunction, and cellular stress; and decreased expression of 41 aging genes associated with inflammation, and cell growth. This study highlights a unique age-related molecular signature in muscle cells exposed to microgravity and underscores electrical stimulation as a potential countermeasure. These insights advance understanding of skeletal muscle aging and microgravity-induced degeneration, informing strategies for mitigating age-related muscle atrophy in space and on Earth.Competing Interest StatementSiobhan Malany is founder of Micro-gRx and a member of the scientific board. Legrand Malany is author of a patent application for the microfluidic device.
ISSN:2692-8205
DOI:10.1101/2025.01.26.634580
Fuente:Biological Science Database