Cardio-metabolic and cytoskeletal proteomic signatures differentiate stress hypersensitivity in dystrophin-deficient mdx mice

IF 2.8 2区生物学 Q2 BIOCHEMICAL RESEARCH METHODS

Journal of proteomics Pub Date : 2024-12-26 DOI:10.1016/j.jprot.2024.105371

Gretel S. Major , Craig W. Herbold , Flora Cheng , Albert Lee , Shuzhao Zhuang , Aaron P. Russell , Angus Lindsay

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Abstract

Extreme heterogeneity exists in the hypersensitive stress response exhibited by the dystrophin-deficient mdx mouse model of Duchenne muscular dystrophy. Because stress hypersensitivity can impact dystrophic phenotypes, this research aimed to understand the peripheral pathways driving this inter-individual variability. Male and female mdx mice were phenotypically stratified into “stress-resistant” or “stress-sensitive” groups based on their response to two laboratory stressors. Quantitative proteomics of striated muscle revealed that stress-resistant females were most dissimilar from all other groups, with over 250 proteins differentially regulated with stress hypersensitivity. Males showed less proteomic variation with stress hypersensitivity; however, these changes were associated with pathway enrichment. In the heart, stress-sensitive males had significant enrichment of pathways related to mitochondrial ATP synthesis, suggesting that increased cardio-metabolic capacity is associated with stress hypersensitivity in male mdx mice. In both sexes, stress hypersensitivity was associated with greater expression of beta-actin-like protein 2, indicative of altered cytoskeletal organisation. Despite identifying proteomic signatures associated with stress hypersensitivity, these did not correlate with differences in the serum metabolome acutely after a stressor. These data suggest that the heterogeneity in stress hypersensitivity in mdx mice is partially driven by cytoskeletal organisation, but that sex-specific cardio-metabolic reprogramming may also underpin this phenotype.

Significance

Duchenne muscular dystrophy (DMD) is a fatal muscle wasting disease which is associated with a premature loss of ambulation and neurocognitive dysfunction. The hypersensitive stress response in DMD is a heterogeneous phenotype which is poorly understood. This study provided the first investigation of the peripheral mechanisms regulating the hypersensitive stress response by undertaking multi-omics analysis of phenotypically stratified mdx mice. Variations in behaviour and the striated muscle proteomic profiles suggest that cardio-metabolic remodelling and cytoskeletal organisation may contribute to this phenotype. This research offers significant insights into understanding how peripheral dystrophin deficiency relates to the cognitive abnormalities seen in patients with DMD.

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心肌代谢和细胞骨骼蛋白质组学特征可区分肌营养不良蛋白缺陷mdx小鼠的应激超敏反应。

杜氏肌营养不良症mdx小鼠模型所表现出的超敏应激反应存在极端异质性。由于应激超敏反应可以影响营养不良表型，本研究旨在了解驱动这种个体间变异性的外周通路。根据雄性和雌性mdx小鼠对两种实验室压力源的反应，在表型上分为“抗压力”组和“压力敏感”组。横纹肌的定量蛋白质组学显示，抗应激雌性与所有其他组最不相同，超过250种蛋白质在应激超敏反应中差异调节。应激超敏男性的蛋白质组学变异较小；然而，这些变化与途径富集有关。在心脏中，应激敏感的雄性小鼠线粒体ATP合成相关通路显著富集，表明心脏代谢能力的增加与雄性mdx小鼠的应激超敏反应有关。在两性中，应激超敏反应与β -肌动蛋白样蛋白2的表达增加有关，这表明细胞骨架组织发生了改变。尽管确定了与应激超敏反应相关的蛋白质组学特征，但这些特征与应激源后血清代谢组的差异无关。这些数据表明，mdx小鼠应激超敏反应的异质性部分是由细胞骨架组织驱动的，但性别特异性心脏代谢重编程也可能是这种表型的基础。意义：杜氏肌营养不良症（DMD）是一种致命的肌肉萎缩疾病，与行动能力过早丧失和神经认知功能障碍有关。DMD的超敏应激反应是一种异质性表型，对其了解甚少。本研究通过对表型分层mdx小鼠进行多组学分析，首次对调节超敏应激反应的外周机制进行了研究。行为和横纹肌蛋白质组学的变化表明，心脏代谢重塑和细胞骨架组织可能有助于这种表型。这项研究为了解外周肌营养不良蛋白缺乏与DMD患者认知异常的关系提供了重要的见解。

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来源期刊

Journal of proteomics 生物-生化研究方法

CiteScore

7.10

自引率

3.00%

发文量

227

审稿时长

73 days

期刊介绍： Journal of Proteomics is aimed at protein scientists and analytical chemists in the field of proteomics, biomarker discovery, protein analytics, plant proteomics, microbial and animal proteomics, human studies, tissue imaging by mass spectrometry, non-conventional and non-model organism proteomics, and protein bioinformatics. The journal welcomes papers in new and upcoming areas such as metabolomics, genomics, systems biology, toxicogenomics, pharmacoproteomics. Journal of Proteomics unifies both fundamental scientists and clinicians, and includes translational research. Suggestions for reviews, webinars and thematic issues are welcome.