Hardee Justin P, Fix Dennis K, Koh Ho-Jin, Wang Xuewen, Goldsmith Edie C, Carson James A
Department of Exercise Science, University of South Carolina, Columbia, South Carolina.
Department of Cell Biology and Anatomy, University of South Carolina School of Medicine, Columbia, South Carolina.
J Appl Physiol (1985). 2020 Jun 1;128(6):1666-1676. doi: 10.1152/japplphysiol.00908.2019. Epub 2020 May 14.
Cancer-induced wasting is accompanied by disruptions to muscle oxidative metabolism and protein turnover that have been associated with systemic inflammation, whereas exercise and stimulated muscle contractions can positively regulate muscle protein synthesis and mitochondrial homeostasis. In preclinical cancer cachexia models, a single bout of eccentric contractions (ECCs) can induce protein synthesis and repeated ECC bouts prevent myofiber atrophy. The cellular mechanisms providing this protection from atrophy have not been resolved. Therefore, the purpose of this study was to determine whether repeated stimulated ECC bouts affect basal muscle oxidative metabolism and protein synthesis during cancer cachexia, and if these changes were associated with plasma IL-6 levels. Male (MIN; = 10) mice initiating cachexia and healthy C57BL/6 (B6; = 11) control mice performed repeated ECC bouts over 2 wk. MIN mice exhibited body weight loss and elevated plasma IL-6 before and during repeated ECC bouts. Control MIN muscle demonstrated disrupted signaling related to inflammation, oxidative capacity, and protein synthesis regulation, which were all improved by repeated ECC bouts. With cachexia, plasma IL-6 levels were negatively correlated with myofiber cross-sectional area, oxidative capacity, and protein synthesis. Interestingly, ECC improvements in these outcomes were positively correlated with plasma IL-6 levels in MIN mice. There was also a positive relationship between muscle oxidative capacity and protein synthesis after repeated ECC bouts in MIN mice. Collectively, repeated ECC bouts altered the cachectic muscle phenotype independent of systemic wasting, and there was a strong association between muscle oxidative capacity and protein synthesis in this adaptive response. Cancer-induced muscle wasting is accompanied by disruptions to muscle oxidative metabolism and protein turnover regulation, whereas exercise is a potent stimulator of muscle protein synthesis and mitochondrial homeostasis. In a preclinical model of cancer cachexia, we report that cachectic muscle retains anabolic and metabolic plasticity to repeated eccentric contraction bouts despite an overall systemic wasting environment. The attenuation of muscle atrophy is linked to improved oxidative capacity and protein synthesis during cancer cachexia progression.
癌症引起的消瘦伴随着肌肉氧化代谢和蛋白质周转的紊乱,这些紊乱与全身炎症有关,而运动和刺激肌肉收缩可以积极调节肌肉蛋白质合成和线粒体稳态。在临床前癌症恶病质模型中,单次离心收缩(ECC)可诱导蛋白质合成,重复进行ECC可防止肌纤维萎缩。提供这种抗萎缩保护的细胞机制尚未明确。因此,本研究的目的是确定重复刺激的ECC是否会影响癌症恶病质期间的基础肌肉氧化代谢和蛋白质合成,以及这些变化是否与血浆IL-6水平相关。开始出现恶病质的雄性MIN小鼠(n = 10)和健康的C57BL/6(B6)对照小鼠(n = 11)在2周内进行了重复的ECC。MIN小鼠在重复ECC之前和期间体重减轻,血浆IL-6升高。对照MIN小鼠的肌肉显示出与炎症、氧化能力和蛋白质合成调节相关的信号传导紊乱,而重复ECC可改善所有这些情况。在恶病质状态下,血浆IL-6水平与肌纤维横截面积、氧化能力和蛋白质合成呈负相关。有趣的是,MIN小鼠中ECC对这些结果的改善与血浆IL-6水平呈正相关。MIN小鼠重复ECC后,肌肉氧化能力与蛋白质合成之间也存在正相关关系。总体而言,重复ECC改变了恶病质肌肉表型,与全身消瘦无关,并且在这种适应性反应中,肌肉氧化能力与蛋白质合成之间存在很强的关联。癌症引起的肌肉消瘦伴随着肌肉氧化代谢和蛋白质周转调节的紊乱,而运动是肌肉蛋白质合成和线粒体稳态的有效刺激因素。在癌症恶病质的临床前模型中,我们报告尽管存在整体全身消瘦环境,但恶病质肌肉对重复的离心收缩仍保留合成代谢和代谢可塑性。在癌症恶病质进展过程中,肌肉萎缩的减轻与氧化能力和蛋白质合成的改善有关。
