Endurance exercise attenuates juvenile irradiation-induced skeletal muscle functional decline and mitochondrial stress.

IF 5.3 2区 医学 Q2 CELL BIOLOGY Skeletal Muscle Pub Date : 2022-04-12 DOI:10.1186/s13395-022-00291-y
Thomas N O'Connor, Jacob G Kallenbach, Haley M Orciuoli, Nicole D Paris, John F Bachman, Carl J Johnston, Eric Hernady, Jacqueline P Williams, Robert T Dirksen, Joe V Chakkalakal
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Abstract

Background: Radiotherapy is commonly used to treat childhood cancers and can have adverse effects on muscle function, but the underlying mechanisms have yet to be fully elucidated. We hypothesized that endurance exercise following radiation treatment would improve skeletal muscle function.

Methods: We utilized the Small Animal Radiation Research Platform (SARRP) to irradiate juvenile male mice with a clinically relevant fractionated dose of 3× (every other day over 5 days) 8.2 Gy X-ray irradiation locally from the knee to footpad region of the right hindlimb. Mice were then singly housed for 1 month in cages equipped with either locked or free-spinning voluntary running wheels. Ex vivo muscle contractile function, RT-qPCR analyses, resting cytosolic and sarcoplasmic reticulum (SR) store Ca2+ levels, mitochondrial reactive oxygen species levels (MitoSOX), and immunohistochemical and biochemical analyses of muscle samples were conducted to assess the muscle pathology and the relative therapeutic impact of voluntary wheel running (VWR).

Results: Irradiation reduced fast-twitch extensor digitorum longus (EDL) muscle-specific force by 27% compared to that of non-irradiated mice, while VWR post-irradiation improved muscle-specific force by 37%. Radiation treatment similarly reduced slow-twitch soleus muscle-specific force by 14% compared to that of non-irradiated mice, while VWR post-irradiation improved specific force by 18%. We assessed intracellular Ca2+ regulation, oxidative stress, and mitochondrial homeostasis as potential mechanisms of radiation-induced pathology and exercise-mediated rescue. We found a significant reduction in resting cytosolic Ca2+ concentration following irradiation in sedentary mice. Intriguingly, however, SR Ca2+ store content was increased in myofibers from irradiated mice post-VWR compared to mice that remained sedentary. We observed a 73% elevation in the overall protein oxidization in muscle post-irradiation, while VWR reduced protein nitrosylation by 35% and mitochondrial reactive oxygen species (ROS) production by 50%. Finally, we found that VWR significantly increased the expression of PGC1α at both the transcript and protein levels, consistent with an exercise-dependent increase in mitochondrial biogenesis.

Conclusions: Juvenile irradiation stunted muscle development, disrupted proper Ca2+ handling, damaged mitochondria, and increased oxidative and nitrosative stress, paralleling significant deficits in muscle force production. Exercise mitigated aberrant Ca2+ handling, mitochondrial homeostasis, and increased oxidative and nitrosative stress in a manner that correlated with improved skeletal muscle function after radiation.

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耐力锻炼可减轻青少年辐照诱发的骨骼肌功能衰退和线粒体应激。
背景:放疗是治疗儿童癌症的常用方法,会对肌肉功能产生不良影响,但其潜在机制尚未完全阐明。我们假设放疗后进行耐力锻炼可改善骨骼肌功能:方法:我们利用小动物辐射研究平台(SARRP)对幼年雄性小鼠的右后肢膝盖至脚垫部位进行了3×(隔天一次,共5天)8.2 Gy X射线照射,照射剂量与临床相关。然后将小鼠单只饲养在装有锁定式或自由旋转式自主跑步轮的笼子中一个月。对肌肉样本进行体内外肌肉收缩功能、RT-qPCR分析、静息胞浆和肌质网(SR)贮存Ca2+水平、线粒体活性氧水平(MitoSOX)以及免疫组化和生化分析,以评估肌肉病理变化和自主跑步轮(VWR)的相对治疗效果:结果:与未接受辐照的小鼠相比,辐照使快肌腱伸肌(EDL)的肌肉特异性力量降低了27%,而辐照后的自愿车轮跑则使肌肉特异性力量提高了37%。与未接受放射治疗的小鼠相比,放射治疗同样使慢肌比目鱼肌特异性肌力降低了 14%,而接受放射治疗后的 VWR 则使特异性肌力提高了 18%。我们评估了细胞内 Ca2+ 调节、氧化应激和线粒体稳态作为辐射诱导的病理学和运动介导的拯救的潜在机制。我们发现,久坐不动的小鼠在接受辐照后,静息胞质 Ca2+ 浓度明显降低。然而,耐人寻味的是,与久坐不动的小鼠相比,辐照后小鼠VWR肌纤维中SR Ca2+储量增加。我们观察到,辐照后肌肉中的总体蛋白质氧化率提高了 73%,而 VWR 则使蛋白质亚硝基化减少了 35%,线粒体活性氧(ROS)产生减少了 50%。最后,我们发现 VWR 在转录本和蛋白质水平上都显著增加了 PGC1α 的表达,这与线粒体生物生成的运动依赖性增加是一致的:结论:幼年辐照阻碍了肌肉的发育,破坏了正常的 Ca2+ 处理,损伤了线粒体,增加了氧化和亚硝酸应激反应,同时导致肌肉力量生成明显不足。运动缓解了钙离子处理失常、线粒体平衡以及氧化和亚硝酸应激的增加,这与辐射后骨骼肌功能的改善相关。
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来源期刊
Skeletal Muscle
Skeletal Muscle CELL BIOLOGY-
CiteScore
9.10
自引率
0.00%
发文量
25
审稿时长
12 weeks
期刊介绍: The only open access journal in its field, Skeletal Muscle publishes novel, cutting-edge research and technological advancements that investigate the molecular mechanisms underlying the biology of skeletal muscle. Reflecting the breadth of research in this area, the journal welcomes manuscripts about the development, metabolism, the regulation of mass and function, aging, degeneration, dystrophy and regeneration of skeletal muscle, with an emphasis on understanding adult skeletal muscle, its maintenance, and its interactions with non-muscle cell types and regulatory modulators. Main areas of interest include: -differentiation of skeletal muscle- atrophy and hypertrophy of skeletal muscle- aging of skeletal muscle- regeneration and degeneration of skeletal muscle- biology of satellite and satellite-like cells- dystrophic degeneration of skeletal muscle- energy and glucose homeostasis in skeletal muscle- non-dystrophic genetic diseases of skeletal muscle, such as Spinal Muscular Atrophy and myopathies- maintenance of neuromuscular junctions- roles of ryanodine receptors and calcium signaling in skeletal muscle- roles of nuclear receptors in skeletal muscle- roles of GPCRs and GPCR signaling in skeletal muscle- other relevant aspects of skeletal muscle biology. In addition, articles on translational clinical studies that address molecular and cellular mechanisms of skeletal muscle will be published. Case reports are also encouraged for submission. Skeletal Muscle reflects the breadth of research on skeletal muscle and bridges gaps between diverse areas of science for example cardiac cell biology and neurobiology, which share common features with respect to cell differentiation, excitatory membranes, cell-cell communication, and maintenance. Suitable articles are model and mechanism-driven, and apply statistical principles where appropriate; purely descriptive studies are of lesser interest.
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