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长跑以性别特异性方式改变与代谢、体液平衡和肌球蛋白调节相关的外周 microRNAs。

Distance running alters peripheral microRNAs implicated in metabolism, fluid balance, and myosin regulation in a sex-specific manner.

机构信息

Department of Pediatrics, Penn State College of Medicine , Hershey, Pennsylvania.

Department of Biology, Marist College , Poughkeepsie, New York.

出版信息

Physiol Genomics. 2018 Aug 1;50(8):658-667. doi: 10.1152/physiolgenomics.00035.2018. Epub 2018 Jun 8.

DOI:10.1152/physiolgenomics.00035.2018
PMID:29883262
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7199223/
Abstract

Microribonucleic acids (miRNAs) mediate adaptive responses to exercise and may serve as biomarkers of exercise intensity/capacity. Expression of miRNAs is altered in skeletal muscle, plasma, and saliva following exertion. Women display unique physiologic responses to endurance exercise, and miRNAs respond to pathologic states in sex-specific patterns. However sex-specific miRNA responses to exercise remain unexplored. This study utilized high-throughput RNA sequencing to measure changes in salivary RNA expression among 25 collegiate runners following a single long-distance run. RNA concentrations in pre- and post-run saliva was assessed through alignment and quantification of 4,694 miRNAs and 27,687 mRNAs. Pair-wise Wilcoxon rank-sum test identified miRNAs with significant [false discovery rate (FDR) < 0.05] post-run changes. Associations between miRNA levels and predicted mRNA targets were explored with Pearson correlations. Differences in miRNA patterns between men ( n = 13) and women ( n = 12) were investigated with two-way analysis of variance. Results revealed 122 salivary miRNAs with post-run changes. The eight miRNAs with the largest changes were miR-3671, miR-5095 (downregulated); and miR-7154-3p, miR-200b-5p, miR-5582-3p, miR-6859-3p, miR-6751-5p, miR-4419a (upregulated). Predicted mRNA targets for these miRNAs represented 15 physiologic processes, including glycerophospholipid metabolism (FDR = 0.042), aldosterone-regulated sodium reabsorption (FDR = 0.049), and arrhythmogenic ventricular cardiomyopathy (FDR = 0.018). Twenty-six miRNA/mRNA pairs had associated changes in post-run levels. Three miRNAs (miR-4675, miR-6745, miR-6746-3p) demonstrated sex-specific responses to exercise. Numerous salivary miRNAs change in response to endurance running and target the expression of genes involved in metabolism, fluid balance, and musculoskeletal adaptations. A subset of miRNAs may differentiate the metabolic response to exercise in men and women.

摘要

微小 RNA(miRNAs)介导对运动的适应性反应,并且可以作为运动强度/能力的生物标志物。在运动后,骨骼肌、血浆和唾液中的 miRNA 表达发生改变。女性对耐力运动表现出独特的生理反应,并且 miRNA 以性别特异性模式对病理状态作出反应。然而,针对运动的性别特异性 miRNA 反应仍未得到探索。本研究利用高通量 RNA 测序技术,测量了 25 名大学生跑步者在单次长跑后的唾液 RNA 表达变化。通过对 4694 个 miRNA 和 27687 个 mRNA 的对齐和定量,评估了跑前和跑后唾液中的 RNA 浓度。配对 Wilcoxon 秩和检验确定了具有显著[错误发现率(FDR)<0.05]跑后变化的 miRNA。通过 Pearson 相关性探索了 miRNA 水平与预测 mRNA 靶标的关系。使用双向方差分析研究了男性(n=13)和女性(n=12)之间的 miRNA 模式差异。结果显示,有 122 个唾液 miRNA 在跑步后发生了变化。变化最大的 8 个 miRNA 是 miR-3671、miR-5095(下调)和 miR-200b-5p、miR-5582-3p、miR-6859-3p、miR-6751-5p、miR-4419a(上调)。这些 miRNA 的预测 mRNA 靶标代表了 15 种生理过程,包括甘油磷脂代谢(FDR=0.042)、醛固酮调节的钠重吸收(FDR=0.049)和致心律失常性右室心肌病(FDR=0.018)。在跑后水平上,有 26 个 miRNA/mRNA 对有相关变化。三个 miRNA(miR-4675、miR-6745、miR-6746-3p)表现出对运动的性别特异性反应。许多唾液 miRNA 会响应耐力运动而发生变化,并靶向代谢、体液平衡和肌肉骨骼适应相关基因的表达。亚组 miRNA 可能会区分男性和女性对运动的代谢反应。

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