Space Biology Group, ETH Zürich, Zürich, Switzerland.
FASEB J. 2013 May;27(5):2045-54. doi: 10.1096/fj.12-218693. Epub 2013 Jan 30.
Of all our mechanosensitive tissues, skeletal muscle is the most developmentally responsive to physical activity. Conversely, restricted mobility due to injury or disease results in muscle atrophy. Gravitational force is another form of mechanical input with profound developmental consequences. The mechanical unloading resulting from the reduced gravitational force experienced during spaceflight results in oxidative muscle loss. We examined the early stages of myogenesis under conditions of simulated microgravity (SM). C2C12 mouse myoblasts in SM proliferated more slowly (2.23× less) as a result of their being retained longer within the G2/M phase of the cell cycle (2.10× more) relative to control myoblasts at terrestrial gravity. Blocking calcium entry via TRP channels with SKF-96365 (10-20 μM) accumulated myoblasts within the G2/M phase of the cell cycle and retarded their proliferation. On the genetic level, SM resulted in the reduced expression of TRPC1 and IGF-1 isoforms, transcriptional events regulated by calcium downstream of mechanical input. A decrease in TRPC1-mediated calcium entry thus appears to be a pivotal event in the muscle atrophy brought on by gravitational mechanical unloading. Hence, relieving the constant force of gravity on cells might prove one valid experimental approach to expose the underlying mechanisms modulating mechanically regulated developmental programs.
在我们所有的机械敏感组织中,骨骼肌对身体活动的反应最具发育性。相反,由于受伤或疾病导致的活动受限会导致肌肉萎缩。重力是另一种机械输入形式,对发育有深远的影响。由于在太空飞行中经历的重力减少,导致了机械卸载,从而导致氧化肌肉损失。我们研究了模拟微重力(SM)条件下的成肌细胞早期阶段。与在地球重力下的对照成肌细胞相比,SM 中的 C2C12 小鼠成肌细胞在细胞周期的 G2/M 期停留时间更长(2.10 倍),因此增殖速度更慢(慢 2.23 倍)。使用 TRP 通道阻滞剂 SKF-96365(10-20 μM)阻断钙进入,可使成肌细胞在细胞周期的 G2/M 期积累,并延缓其增殖。在遗传水平上,SM 导致 TRPC1 和 IGF-1 亚型的表达减少,这些转录事件受机械输入下游钙的调节。因此,TRPC1 介导的钙进入减少似乎是由重力机械卸载引起的肌肉萎缩的关键事件。因此,减轻细胞的持续重力可能被证明是一种有效的实验方法,可以揭示调节机械调节发育程序的潜在机制。
