Ren Mingqiang, Michaelson Luke P, Mungunsukh Ognoon, Bedocs Peter, Friel Liam, Cofer Kristen, Dartt Carolyn E, Sambuughin Nyamkhishig, O'Connor Francis G
Consortium for Health and Military Performance, Department of Military and Emergency Medicine, F. Edward Hébert School of Medicine, Uniformed Services University of the Health Sciences, Bethesda, MD 20814, USA.
Henry M. Jackson Foundation for the Advancement of Military Medicine, Inc., Bethesda, MD 20817, USA.
Genes (Basel). 2025 Aug 2;16(8):930. doi: 10.3390/genes16080930.
BACKGROUND/OBJECTIVE: Exertional rhabdomyolysis (ER) is primarily driven by mechanical stress on muscles during strenuous or unaccustomed exercise, often exacerbated by environmental factors like heat and dehydration. While the general cellular pathway involving energy depletion and calcium overload is understood in horse ER models, the underlying mechanisms specific to the ER are not universally known within humans. This study aimed to evaluate whether patients with ER exhibited transcriptional signatures that were significantly different from those of healthy individuals.
This study utilized RNA sequencing on skeletal muscle samples from 19 human patients with ER history, collected at a minimum of six months after the most recent ER event, and eight healthy controls to investigate the transcriptomic landscape of ER. To identify any alterations in biological processes between the case and control groups, functional pathway analyses were conducted.
Functional pathway enrichment analyses of differentially expressed genes revealed strong suppression of mitochondrial function. This suppression included the "aerobic electron transport chain" and "oxidative phosphorylation" pathways, indicating impaired energy production. Conversely, there was an upregulation of genes associated with adhesion and extracellular matrix-related pathways, indicating active restoration of muscle function in ER cases.
The study demonstrated that muscle tissue exhibited signs of suppressed mitochondrial function and increased extracellular matrix development. Both of these facilitate muscle recovery within several months after an ER episode.
背景/目的:运动性横纹肌溶解症(ER)主要由剧烈运动或不习惯的运动过程中肌肉受到的机械应力驱动,通常会因高温和脱水等环境因素而加剧。虽然在马ER模型中已经了解了涉及能量消耗和钙超载的一般细胞途径,但人类ER特有的潜在机制尚未得到普遍认知。本研究旨在评估ER患者是否表现出与健康个体显著不同的转录特征。
本研究对19名有ER病史的人类患者的骨骼肌样本进行了RNA测序,这些样本在最近一次ER事件至少六个月后采集,并与8名健康对照进行比较,以研究ER的转录组图谱。为了确定病例组和对照组之间生物过程的任何变化,进行了功能途径分析。
对差异表达基因的功能途径富集分析显示线粒体功能受到强烈抑制。这种抑制包括“有氧电子传递链”和“氧化磷酸化”途径,表明能量产生受损。相反,与黏附及细胞外基质相关途径相关的基因上调,表明ER病例中肌肉功能正在积极恢复。
该研究表明,肌肉组织表现出线粒体功能受抑制和细胞外基质发育增加的迹象。这两者都有助于ER发作后数月内的肌肉恢复。
