Abstract
Microgravity exposure as well as chronic disuse are two main causes of skeletal muscle atrophy in animals and humans. The antigravity calf soleus is a reference postural muscle to investigate the mechanism of disuse-induced maladaptation and plasticity of human and rodent (rats or mice) skeletal musculature. Here, we report microgravity-induced global gene expression changes in space-flown mouse skeletal muscle and the identification of yet unknown disuse susceptible transcripts found in soleus (a mainly slow phenotype) but not in extensor digitorum longus (a mainly fast phenotype dorsiflexor as functional counterpart to soleus). Adult C57Bl/N6 male mice (n = 5) flew aboard a biosatellite for 30 days on orbit (BION-M1 mission, 2013), a sex and age-matched cohort were housed in standard vivarium cages (n = 5), or in a replicate flight habitat as ground control (n = 5). Next to disuse atrophy signs (reduced size and myofiber phenotype I to II type shift) as much as 680 differentially expressed genes were found in the space-flown soleus, and only 72 in extensor digitorum longus (only 24 genes in common) compared to ground controls. Altered expression of gene transcripts matched key biological processes (contractile machinery, calcium homeostasis, muscle development, cell metabolism, inflammatory and oxidative stress response). Some transcripts (Fzd9, Casq2, Kcnma1, Ppara, Myf6) were further validated by quantitative real-time PCR (qRT-PCR). Besides previous reports on other leg muscle types we put forth for the first time a complete set of microgravity susceptible gene transcripts in soleus of mice as promising new biomarkers or targets for optimization of physical countermeasures and rehabilitation protocols to overcome disuse atrophy conditions in different clinical settings, rehabilitation and spaceflight.
Highlights
Long-term exposure to microgravity or extended periods of disuse are two main causes of the reduction of skeletal muscle mass and performance in animals and humans in space
In detail, following a preflight animal training and preselection program, mice were randomly divided in 3 groups: mice to be flown aboard the BION-M1 biosatellite exposed for 30 days to microgravity (BION Flown = BION flown (BF)), mice housed for 30 days under the same biosatellite bio-parameters on ground (BION Ground = BION ground (BG)), and mice housed in the animal facility of Moscow State University (Institute of Mitoengineering) concomitant to the duration of the biosatellite flight (FC = Flight Control)
BF and BG mice were fed with “space” paste food including all necessary major nutrients comparable to standard chow and water developed by the Institute for Biomedical Problems (IBMP, Moscow), while flight control (FC) mice were fed with standard chow and water ab libitum
Summary
Long-term exposure to microgravity (μG) or extended periods of disuse are two main causes of the reduction of skeletal muscle mass and performance in animals and humans in space. Due to the limited number of spaceflights, the first challenge in space biomedical research is the availability of large cohorts of biological samples (tissues, cells, body fluids, etc.) exposed to microgravity. In this regard, the use of small rodents, in particular mice, represent a suitable model for studying the effects of microgravity in vivo. 76 to yrs., industrialized countries), the results obtained from murine animals in short or mid-duration spaceflight (7 to 30 days) might be comparable to longer periods of microgravity exposure (up to six months or even more) in humans The estimated life span of mice is much shorter (approx. 1.5 to 2 yrs.) compared to humans (approx. 76 to yrs., industrialized countries), the results obtained from murine animals in short or mid-duration spaceflight (7 to 30 days) might be comparable to longer periods of microgravity exposure (up to six months or even more) in humans
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