TY - JOUR
T1 - Effects of microgravity simulation on zebrafish transcriptomes and bone physiology—exposure starting at 5 days post fertilization
T2 - Npj Microgravity
AU - Aceto, J.
AU - Nourizadeh-Lillabadi, R.
AU - Bradamante, S.
AU - Maier, J.A.
AU - Alestrom, P.
AU - van Loon, J.J.W.A.
AU - Muller, M.
N1 - ISI Document Delivery No.: DN9HE Times Cited: 1 Cited Reference Count: 58 Aceto, Jessica Nourizadeh-Lillabadi, Rasoul Bradamante, Silvia Maier, Jeanette A. Alestrom, Peter van Loon, Jack J. W. A. Muller, Marc 1 5 7 NATURE PUBLISHING GROUP NEW YORK NPJ MICROGRAVITY
PY - 2016
Y1 - 2016
N2 - Physiological modifications in near weightlessness, as experienced by astronauts during space flight, have been the subject of numerous studies. Various animal models have been used on space missions or in microgravity simulation on ground to understand the effects of gravity on living animals. Here, we used the zebrafish larvae as a model to study the effect of microgravity simulation on bone formation and whole genome gene expression. To simulate microgravity (sim-μg), we used two-dimensional (2D) clinorotation starting at 5 days post fertilization to assess skeletal formation after 5 days of treatment. To assess early, regulatory effects on gene expression, a single day clinorotation was performed. Clinorotation for 5 days caused a significant decrease of bone formation, as shown by staining for cartilage and bone structures. This effect was not due to stress, as assessed by measuring cortisol levels in treated larvae. Gene expression results indicate that 1-day simulated microgravity affected musculoskeletal, cardiovascular, and nuclear receptor systems. With free-swimming model organisms such as zebrafish larvae, the 2D clinorotation setup appears to be a very appropriate approach to sim-μg. We provide evidence for alterations in bone formation and other important biological functions; in addition several affected genes and pathways involved in bone, muscle or cardiovascular development are identified.
AB - Physiological modifications in near weightlessness, as experienced by astronauts during space flight, have been the subject of numerous studies. Various animal models have been used on space missions or in microgravity simulation on ground to understand the effects of gravity on living animals. Here, we used the zebrafish larvae as a model to study the effect of microgravity simulation on bone formation and whole genome gene expression. To simulate microgravity (sim-μg), we used two-dimensional (2D) clinorotation starting at 5 days post fertilization to assess skeletal formation after 5 days of treatment. To assess early, regulatory effects on gene expression, a single day clinorotation was performed. Clinorotation for 5 days caused a significant decrease of bone formation, as shown by staining for cartilage and bone structures. This effect was not due to stress, as assessed by measuring cortisol levels in treated larvae. Gene expression results indicate that 1-day simulated microgravity affected musculoskeletal, cardiovascular, and nuclear receptor systems. With free-swimming model organisms such as zebrafish larvae, the 2D clinorotation setup appears to be a very appropriate approach to sim-μg. We provide evidence for alterations in bone formation and other important biological functions; in addition several affected genes and pathways involved in bone, muscle or cardiovascular development are identified.
U2 - https://doi.org/10.1038/npjmgrav.2016.10
DO - https://doi.org/10.1038/npjmgrav.2016.10
M3 - Article
C2 - 28725727
SN - 2373-8065
VL - 2
SP - 8
JO - NPJ microgravity
JF - NPJ microgravity
M1 - 16010
ER -