1 Center for Molecular Medicine Cologne (CMMC), Institute of Neurophysiology, University of Cologne , Cologne, Germany .
2 German Aerospace Center, Institute of Aerospace Medicine , Gravitational Biology, Cologne, Germany .
Stem Cells Dev. 2018 Jun 15;27(12):838-847. doi: 10.1089/scd.2017.0294. Epub 2018 Apr 9.
Embryonic developmental studies under microgravity conditions in space are very limited. To study the effects of short-term altered gravity on embryonic development processes, we exposed mouse embryonic stem cells (mESCs) to phases of hypergravity and microgravity and studied the differentiation potential of the cells using wide-genome microarray analysis. During the 64th European Space Agency's parabolic flight campaign, mESCs were exposed to 31 parabolas. Each parabola comprised phases lasting 22 s of hypergravity, microgravity, and a repeat of hypergravity. On different parabolas, RNA was isolated for microarray analysis. After exposure to 31 parabolas, mESCs (P31 mESCs) were further differentiated under normal gravity (1 g) conditions for 12 days, producing P31 12-day embryoid bodies (EBs). After analysis of the microarrays, the differentially expressed genes were analyzed using different bioinformatic tools to identify developmental and nondevelopmental biological processes affected by conditions on the parabolic flight experiment. Our results demonstrated that several genes belonging to GOs associated with cell cycle and proliferation were downregulated in undifferentiated mESCs exposed to gravity changes. However, several genes belonging to developmental processes, such as vasculature development, kidney development, skin development, and to the TGF-β signaling pathway, were upregulated. Interestingly, similar enriched and suppressed GOs were obtained in P31 12-day EBs compared with ground control 12-day EBs. Our results show that undifferentiated mESCs exposed to alternate hypergravity and microgravity phases expressed several genes associated with developmental/differentiation and cell cycle processes, suggesting a transition from the undifferentiated pluripotent to a more differentiated stage of mESCs.
胚胎在微重力条件下的发育研究在空间中非常有限。为了研究短期改变重力对胚胎发育过程的影响,我们将小鼠胚胎干细胞(mESCs)暴露于超重力和微重力阶段,并使用全基因组微阵列分析研究细胞的分化潜力。在第 64 届欧洲航天局的抛物线飞行任务中,mESCs 经历了 31 次抛物线飞行。每个抛物线飞行都包括持续 22 秒的超重力、微重力和超重力重复阶段。在不同的抛物线上,分离 RNA 进行微阵列分析。在经历 31 次抛物线飞行后,mESCs(P31 mESCs)在正常重力(1g)条件下进一步分化 12 天,产生 P31 12 天类胚体(EBs)。在分析微阵列后,使用不同的生物信息学工具分析差异表达的基因,以鉴定受抛物线飞行实验条件影响的发育和非发育生物学过程。我们的结果表明,在经历重力变化的未分化 mESCs 中,属于与细胞周期和增殖相关的 GO 相关的几个基因下调。然而,属于发育过程的几个基因上调,例如血管发育、肾脏发育、皮肤发育和 TGF-β信号通路。有趣的是,与地面对照 12 天 EB 相比,P31 12 天 EB 中获得了相似的富集和抑制的 GO。我们的结果表明,暴露于交替超重力和微重力阶段的未分化 mESCs 表达了与发育/分化和细胞周期过程相关的几个基因,表明 mESCs 从未分化的多能状态向更分化的状态过渡。
