Pranav Iyer, Diana M Asante, Sagar Vyavahare, Lee Tae Jin, Pankaj Ahluwalia, Ravindra Kolhe, Hari Kashyap, Carlos Isales, Sadanand Fulzele
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引用次数: 0
Abstract
Background: Aerobic exercise induces a range of complex molecular adaptations in skeletal muscle. However, a complete understanding of the specific transcriptional changes following exercise warrants further research. Methods: This study aimed to identify gene expression patterns following acute aerobic exercise by analyzing Gene Expression Omnibus (GEO) datasets. We performed a comparative analysis of transcriptional profiles of related genes in two independent studies, focusing on both established and novel genes involved in muscle physiology. Results: Our analysis revealed ten consistently upregulated and eight downregulated genes across both datasets. The upregulated genes were predominantly associated with mitochondrial function and cellular respiration, including MDH1, ATP5MC1, ATP5IB, and ATP5F1A. Conversely, downregulated genes such as YTHDC1, CDK5RAP2, and PALS2 were implicated in vascular structure and cellular organization. Importantly, our findings also revealed novel exercise-responsive genes not previously characterized in this context. Among these, MRPL41 and VEGF were significantly upregulated and are associated with p53-mediated apoptotic signaling and fatty acid metabolism, respectively. Novel downregulated genes included LIMCH1, CMYA5, and FOXJ3, which are putatively involved in cytoskeletal dynamics and muscle fiber type specification. Conclusions: These findings enhance our understanding of the transcriptional landscape of skeletal muscle following acute aerobic exercise and identify novel molecular targets for further investigation in the fields of exercise physiology and metabolic health.
背景:有氧运动诱导骨骼肌一系列复杂的分子适应。然而,完全了解运动后具体的转录变化需要进一步的研究。方法:本研究旨在通过分析gene expression Omnibus (GEO)数据集,确定急性有氧运动后的基因表达模式。我们在两个独立的研究中对相关基因的转录谱进行了比较分析,重点研究了与肌肉生理学有关的已建立的和新的基因。结果:我们的分析显示,在两个数据集中,有10个基因持续上调,8个基因持续下调。上调的基因主要与线粒体功能和细胞呼吸相关,包括MDH1、ATP5MC1、ATP5IB和ATP5F1A。相反,下调的基因如YTHDC1、CDK5RAP2和PALS2与血管结构和细胞组织有关。重要的是,我们的研究结果还揭示了以前未在此背景下表征的新型运动反应基因。其中,MRPL41和VEGF显著上调,分别与p53介导的凋亡信号和脂肪酸代谢相关。新的下调基因包括LIMCH1、CMYA5和FOXJ3,这些基因被认为与细胞骨架动力学和肌纤维类型规范有关。结论:这些发现增强了我们对急性有氧运动后骨骼肌转录格局的理解,并为运动生理学和代谢健康领域的进一步研究确定了新的分子靶点。
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