与消耗相关的代谢物琥珀酸破坏肌肉生成并损害骨骼肌再生

Paige C. Arneson-Wissink, Kelly A. Hogan, Alexandra M. Ducharme, Adrienne Samani, Aminah Jatoi, Jason D. Doles
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引用次数: 8

摘要

背景:肌肉萎缩是影响大多数晚期癌症患者的一种衰弱的合并症。随着肌肉分解代谢的增强,肌肉修复/再生的缺陷会导致癌症相关的消瘦。抑制肌肉再生的因素包括干扰肌源性信号转导通路的细胞因子。对于其他与癌症/消耗相关的线索,如代谢物,是如何导致肌肉功能障碍的,我们了解得较少。本研究探讨代谢物琥珀酸盐如何影响肌肉发生和肌肉再生。方法:我们利用已建立的异位代谢物处理(细胞渗透性二甲基琥珀酸盐)策略来评估细胞内琥珀酸盐升高的能力,以(i)影响成肌细胞稳态(增殖和凋亡),(ii)破坏蛋白质动力学并诱导消耗相关的萎缩,以及(iii)调节体外肌生成。体内琥珀酸盐补充实验(2%琥珀酸盐和1%蔗糖载体)用于证实和扩展体外观察。然后进行代谢分析和功能代谢研究,以研究琥珀酸盐升高对线粒体功能的影响。结果体外添加琥珀酸盐可使细胞内琥珀酸盐升高约2倍,但对C2C12成肌细胞的增殖和凋亡没有影响。升高的琥珀酸盐对蛋白质稳态有轻微影响(o -丙炔-嘌呤霉素染色评估蛋白质合成减少约25%),对肌管萎缩无显著影响。琥珀酸盐升高干扰体外成肌细胞分化,其特征是肌生成晚期标志物显著减少,肌球蛋白重链阳性结构的细胞核减少(通过免疫荧光染色评估)。虽然口服琥珀酸盐的小鼠没有表现出整体组成或全肌肉重量的变化,但这些小鼠的肌肉肌纤维直径较小(与最小肌纤维直径分布直方图拟合的非线性回归曲线平均减少约6%),当氯化钡损伤诱导肌肉再生时,这种情况加剧。损伤后7天和28天,与最小足径分布直方图拟合的非线性回归曲线均值显著降低。损伤28天后,体外观察到支持分化缺陷的肌原素阳性细胞数量增加(增加三倍)。肌母细胞的代谢分析和功能代谢评估显示,琥珀酸盐升高引起广泛的代谢变化,并显著降低最大细胞呼吸(降低约35%)。该研究扩大了可直接调节肌肉祖细胞功能的肌肉萎缩相关因素的范围,并加强了代谢紊乱是肌肉再生受损的重要因素的假设,这是癌症相关肌肉萎缩的一个重要方面。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

The wasting-associated metabolite succinate disrupts myogenesis and impairs skeletal muscle regeneration

The wasting-associated metabolite succinate disrupts myogenesis and impairs skeletal muscle regeneration

Background

Muscle wasting is a debilitating co-morbidity affecting most advanced cancer patients. Alongside enhanced muscle catabolism, defects in muscle repair/regeneration contribute to cancer-associated wasting. Among the factors implicated in suppression of muscle regeneration are cytokines that interfere with myogenic signal transduction pathways. Less understood is how other cancer/wasting-associated cues, such as metabolites, contribute to muscle dysfunction. This study investigates how the metabolite succinate affects myogenesis and muscle regeneration.

Methods

We leveraged an established ectopic metabolite treatment (cell permeable dimethyl-succinate) strategy to evaluate the ability of intracellular succinate elevation to (i) affect myoblast homeostasis (proliferation and apoptosis), (ii) disrupt protein dynamics and induce wasting-associated atrophy, and (iii) modulate in vitro myogenesis. In vivo succinate supplementation experiments (2% succinate and 1% sucrose vehicle) were used to corroborate and extend in vitro observations. Metabolic profiling and functional metabolic studies were then performed to investigate the impact of succinate elevation on mitochondria function.

Results

We found that in vitro succinate supplementation elevated intracellular succinate about 2-fold and did not have an impact on proliferation or apoptosis of C2C12 myoblasts. Elevated succinate had minor effects on protein homeostasis (~25% decrease in protein synthesis assessed by O-propargyl-puromycin staining), and no significant effect on myotube atrophy. Succinate elevation interfered with in vitro myoblast differentiation, characterized by significant decreases in late markers of myogenesis and fewer nuclei per myosin heavy chain positive structure (assessed by immunofluorescence staining). While mice orally administered succinate did not exhibit changes in overall body composition or whole muscle weights, these mice displayed smaller muscle myofiber diameters (~6% decrease in the mean of non-linear regression curves fit to the histograms of minimum feret diameter distribution), which was exacerbated when muscle regeneration was induced with barium chloride injury. Significant decreases in the mean of non-linear regression curves fit to the histograms of minimum feret diameter distributions were observed 7 and 28 days post injury. Elevated numbers of myogenin positive cells (three-fold increase) supportive of the differentiation defects observed in vitro were observed 28 days post injury. Metabolic profiling and functional metabolic assessment of myoblasts revealed that succinate elevation caused both widespread metabolic changes and significantly lowered maximal cellular respiration (~35% decrease).

Conclusions

This study broadens the repertoire of wasting-associated factors that can directly modulate muscle progenitor cell function and strengthens the hypothesis that metabolic derangements are significant contributors to impaired muscle regeneration, an important aspect of cancer-associated muscle wasting.

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