运动结束后小鼠神经系统中运动诱导的MicroRNA调控得以维持。

Andrea Carvalho, Sonia Zanon, Guilherme Lucas
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引用次数: 1

摘要

背景:体育锻炼可以通过改变基因调控改善突触功能,保护神经系统免受多种疾病的侵袭。MicroRNAs (miRs)不仅在肌肉系统中,而且在大脑中作为基因表达和蛋白质合成的重要调节因子而出现。目的:本文研究运动诱导的miRs在神经和肌肉系统中的表达是活动依赖性的,还是在运动停止后仍然受到调节。方法:采用RT-PCR方法检测小鼠游泳训练5周后、游泳运动后再静坐4周后的背根神经节、脊髓背角和腹角、比目鱼肌中miR-1、-16和-206的表达谱。对照组小鼠在5周的训练期间每天天鹅30秒,另外4周恢复非游泳活动。结果:运动后,miR-1在所有组织中表达上调。然而,miR-1的上调在脊髓和比目鱼肌的两个方面都持续显著升高。miR-16和-206的表达谱仅在神经系统中升高。然而,运动中断后,miR-16在DRG和脊髓中持续上调,而miR-206仅在脊髓腹角中持续上调。结论:运动训练可以引起miRs表达的长期变化,而不依赖于运动维持。miRs的时空表达在一定程度上依赖于这种活性。这些数据提出了一个关于miRs生物发生的新概念假设,表明长期和系统的运动可能在活动停止后导致不可逆的miR调节。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Exercise-Induced MicroRNA Regulation in the Mice Nervous System is Maintained After Activity Cessation.

Background: Physical exercise can improve synaptic function and protect the nervous system against many diseases by altering gene regulation. MicroRNAs (miRs) have emerged as vital regulators of gene expression and protein synthesis not only in the muscular system, but also in the brain.

Objective: Here we investigated whether exercise-induced miRs expression in the nervous and muscular systems is activity-dependent or it remains regulated even after exercise cessation.

Methods: The expression profile of miR-1, -16, and -206 was monitored by RT-PCR in the dorsal root ganglion, in the spinal cord dorsal and ventral horn, and in the soleus muscle of mice after 5 weeks of swimming training and after swimming exercise followed by 4 weeks of sedentary conditions. Control animals consisted of mice that swan daily for 30s during the 5-weeks training period, returning to the non-swimming activity for additional 4 weeks.

Results: After exercise, miR-1 was upregulated in all tissues investigated. However, the upregulation of miR-1 continued significantly high in both aspects of the spinal cord and in the soleus muscle. The expression profiles of miR-16, and -206 were increased only in the nervous system. However, miR-16 upregulation persisted in the DRG and in the spinal cord after exercise interruption, whereas miR-206 continued upregulated only in the spinal cord ventral horn.

Conclusion: Exercise training can cause long-lasting changes in the expression of miRs independently of exercise maintenance. Spatial and temporal expression of miRs is to some extent dependent on this activity. The data raised a new conceptual hypothesis on the biogenesis of miRs, indicating that long-lasting and systematic exercise can potentially cause irreversible miR regulation after activity cessation.

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