Åstrand Laboratory, Swedish School of Sport and Health Sciences, Stockholm, SWEDEN.
Department of Physiology and Pharmacology, Karolinska Institutet, Stockholm, SWEDEN.
Med Sci Sports Exerc. 2020 Aug;52(8):1679-1690. doi: 10.1249/MSS.0000000000002310.
Human skeletal muscle is thought to have heightened sensitivity to exercise stimulus when it has been previously trained (i.e., it possesses "muscle memory"). We investigated whether basal and acute resistance exercise-induced gene expression and cell signaling events are influenced by previous strength training history.
Accordingly, 19 training naïve women and men completed 10 wk of unilateral leg strength training, followed by 20 wk of detraining. Subsequently, an acute resistance exercise session was performed for both legs, with vastus lateralis biopsies taken at rest and 1 h after exercise in both legs (memory and control).
The phosphorylation of AMPK and eEF2 was higher in the memory leg than that in the control leg at both time points. The postexercise phosphorylation of 4E-BP1 was higher in the memory leg than that in the control leg. The memory leg had lower basal mRNA levels of total PGC1α and, unlike the control leg, exhibited increases in PGC1α-ex1a transcripts after exercise. In the genes related to myogenesis (SETD3, MYOD1, and MYOG), mRNA levels differed between the memory and the untrained leg; these effects were evident primarily in the male subjects. Expression of the novel gene SPRYD7 was lower in the memory leg at rest and decreased after exercise only in the control leg, but SPRYD7 protein levels were higher in the memory leg.
In conclusion, several key regulatory genes and proteins involved in muscular adaptations to resistance exercise are influenced by previous training history. Although the relevance and mechanistic explanation for these findings need further investigation, they support the view of a molecular muscle memory in response to training.
人们认为,经过先前的训练(即拥有“肌肉记忆”)后,人体骨骼肌对运动刺激的敏感性会提高。我们研究了以前的力量训练史是否会影响基础和急性抗阻运动诱导的基因表达和细胞信号事件。
因此,19 名未经训练的女性和男性完成了 10 周的单侧腿部力量训练,随后进行了 20 周的停训。随后,对两条腿进行了一次急性抗阻运动,在两条腿的休息和运动后 1 小时分别采集股外侧肌活检(记忆腿和对照腿)。
在两个时间点,记忆腿的 AMPK 和 eEF2 磷酸化均高于对照腿。运动后 4E-BP1 的磷酸化在记忆腿中高于对照腿。记忆腿的总 PGC1α 的基础 mRNA 水平较低,与对照腿不同,运动后 PGC1α-ex1a 转录本增加。在与肌生成相关的基因(SETD3、MYOD1 和 MYOG)中,记忆腿和未经训练的腿之间的 mRNA 水平不同;这些影响主要在男性受试者中表现出来。在休息时,记忆腿中的 SPRYD7 基因表达较低,仅在对照腿中,运动后其表达降低,但记忆腿中的 SPRYD7 蛋白水平较高。
总之,一些与抗阻运动引起的肌肉适应相关的关键调节基因和蛋白受到以前训练史的影响。尽管这些发现的相关性和机制解释需要进一步研究,但它们支持了训练引起的分子肌肉记忆的观点。
