Cyclosporine A Delays the Terminal Disease Stage in the Tfam KO Mitochondrial Myopathy Mouse Model Without Improving Mitochondrial Energy Production.

IF 2.8 3区医学 Q2 CLINICAL NEUROLOGY

Muscle & Nerve Pub Date : 2025-02-01 Epub Date: 2024-12-23 DOI:10.1002/mus.28315

Benjamin Chatel, Isabelle Varlet, Augustin C Ogier, Emilie Pecchi, Monique Bernard, Julien Gondin, Håkan Westerblad, David Bendahan, Charlotte Gineste

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Abstract

Introduction and aims: Mitochondrial myopathies are rare genetic disorders for which no effective treatment exists. We previously showed that the pharmacological cyclophilin inhibitor cyclosporine A (CsA) extends the lifespan of fast-twitch skeletal muscle-specific mitochondrial transcription factor A knockout (Tfam KO) mice, lacking the ability to transcribe mitochondrial DNA and displaying lethal mitochondrial myopathy. Our present aim was to assess whether the positive effect of CsA was associated with improved in vivo mitochondrial energy production.

Methods: Mice were treated with CsA for 4 weeks, beginning at 12 weeks (i.e., before the terminal disease phase). Hindlimb plantar flexor muscles were fatigued by 80 contractions (40 Hz, 1.5 s on, 6 s off) while measuring force and energy metabolism using phosphorus-31 magnetic resonance spectroscopy.

Results: Force decreased at similar rates in Tfam KO mice with and without the CsA treatment, reaching 50% of the baseline value after ~14 ± 1 contractions, which was faster than in control mice (25 ± 1 contractions). Phosphocreatine (PCr) decreased to ~10% of the control concentration in Tfam KO mice, independent of the treatment, which was larger than the ~20% observed in control mice. The time constant of PCr recovery was higher in untreated Tfam KO than that in control muscle (+100%) and similar in untreated and CsA-treated Tfam KO mice.

Discussion: The results do not support improved mitochondrial energy production as a mechanism underlying the prolonged lifespan of Tfam KO mitochondrial myopathy mice treated with CsA. Thus, other mechanisms must be involved, such as the previously observed CsA-mediated protection against excessive mitochondrial Ca²⁺ accumulation.

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环孢素A延缓Tfam KO线粒体肌病小鼠模型的终末期，但不改善线粒体能量产生

线粒体肌病是一种罕见的遗传性疾病，目前尚无有效的治疗方法。我们之前的研究表明，药物亲环素抑制剂环孢素A （CsA）可以延长快速抽搐骨骼肌特异性线粒体转录因子A敲除（Tfam KO）小鼠的寿命，这些小鼠缺乏转录线粒体DNA的能力，并表现出致命的线粒体肌病。我们目前的目的是评估CsA的积极作用是否与体内线粒体能量产生的改善有关。方法：小鼠从12周（即终末期前）开始接受CsA治疗4周。后肢足底屈肌经80次（40 Hz， 1.5 s开，6 s关）收缩疲劳后，采用磷-31磁共振波谱法测量力和能量代谢。结果：经CsA处理和不经CsA处理的Tfam KO小鼠的肌力下降速率相似，在~14±1次收缩后达到基线值的50%，比对照组（25±1次收缩）快。与治疗无关，Tfam KO小鼠的磷酸肌酸（PCr）浓度下降至对照的~10%，比对照小鼠的~20%大。未经处理的Tfam KO小鼠的PCr恢复时间常数高于对照肌（+100%），未经处理的Tfam KO小鼠与csa处理的Tfam KO小鼠相似。讨论：结果不支持线粒体能量产生的改善是CsA治疗Tfam KO线粒体肌病小鼠寿命延长的机制。因此，必须涉及其他机制，例如先前观察到的csa介导的防止过度线粒体Ca2+积累的保护。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Muscle & Nerve 医学-临床神经学

CiteScore

6.40

自引率

5.90%

发文量

287

审稿时长

3-6 weeks

期刊介绍： Muscle & Nerve is an international and interdisciplinary publication of original contributions, in both health and disease, concerning studies of the muscle, the neuromuscular junction, the peripheral motor, sensory and autonomic neurons, and the central nervous system where the behavior of the peripheral nervous system is clarified. Appearing monthly, Muscle & Nerve publishes clinical studies and clinically relevant research reports in the fields of anatomy, biochemistry, cell biology, electrophysiology and electrodiagnosis, epidemiology, genetics, immunology, pathology, pharmacology, physiology, toxicology, and virology. The Journal welcomes articles and reports on basic clinical electrophysiology and electrodiagnosis. We expedite some papers dealing with timely topics to keep up with the fast-moving pace of science, based on the referees'' recommendation.