Musculoskeletal miRNA profiling after exposure to simulated space stressors in mice
Carly Orr, Emma Mackey, Azemat Jamshidi-Parsian, Stephanie Byrum, Rupak Pathak, Robert Griffin, Nathan S. Reyna

TL;DR
This study finds two microRNAs in mice that are affected by simulated space conditions, possibly influencing genes linked to oxidative stress and cancer.
Contribution
The study identifies two novel microRNAs (Mir6236 and Mir6240) that are downregulated in skeletal muscle under simulated space stressors.
Findings
Mir6236 and Mir6240 were significantly downregulated in murine skeletal muscle after simulated space conditions.
These microRNAs may regulate ROS-associated genes like FN1, EZR, TRX2, and MAP2K1.
Their dysregulation suggests a potential role in tumor progression.
Abstract
Prolonged spaceflight exposes astronauts to chronic irradiation and microgravity, inducing oxidative stress through the production of reactive oxygen species (ROS). This study identified two microRNAs, Mir6236 and Mir6240, that were significantly downregulated in murine skeletal muscle following simulated space conditions. Sequencing and bioinformatics analysis revealed these microRNAs likely regulate key ROS-associated genes and pathways, including FN1, EZR, TRX2, and MAP2K1. Their dysregulation suggests a role in tumor progression, underscoring the need to further investigate microRNA-mediated gene regulation under space-like conditions to better understand the long-term health risks associated with extended space travel.
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Taxonomy
TopicsSpaceflight effects on biology · Muscle Physiology and Disorders · Exercise and Physiological Responses
