The role of mitochondrial dynamics and mitophagy in skeletal muscle atrophy: from molecular mechanisms to therapeutic insights

Aging-related muscle atrophy and weakness contribute to loss of mobility, falls and disability. Mitochondrial dysfunction is widely considered a key contributing mechanism to muscle aging. However, mounting evidence position physical activity as a confounding factor, making unclear whether muscle mitochondria accumulate bona fide defects with aging. To disentangle aging from physical activity-related mitochondrial adaptations, we functionally profiled skeletal muscle mitochondria in 51 inactive and 88 active men aged 20-93. Physical activity status conferred partial protection against age-related decline in physical performance. A trend for reduced muscle mitochondrial respiration with aging was observed in inactive but not in active participants, indicating that agingper sedoes not alter mitochondrial respiratory capacity. Mitochondrial reactive oxygen species (ROS) production was unaffected by aging and active participants displayed higher ROS production. In contrast, mitochondrial calcium retention capacity decreased with aging regardless of physical activity status and correlated with muscle mass, performance and the stress-responsive metabokine GDF15. Targeting mitochondrial calcium handling may hold promise for treating aging-related muscle impairments.

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Mitophagy modulation rescues single large-scale mitochondrial DNA deletion (SLSMD) disease symptoms in theC. elegans uaDf5animal model

Mendel,

Matsuno,

et al. 2024

Preprint

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Single large scale mitochondrial DNA (mtDNA) deletions (SLSMD) underlie a range of sporadic or maternally inherited primary mitochondrial diseases having significant morbidity and mortality, including Pearson syndrome, Kearns-Sayre Syndrome, or Chronic Progressive External Ophthalmoplegia. Therapeutic development has been hindered by limited existing knowledge on mtDNA quality control and a lack of SLSMD animal models. To address this challenge, we utilized the C. elegans heteroplasmic SLSMD strain, uaDf5, to objectively screen for potential therapies. As mitophagy modulation has been implicated in mtDNA homeostasis, we screened a library of mitophagy modulating compounds to determine their comparative effects to rescue mitochondrial unfolded protein (UPRmt) stress induction in in uaDf5 SLSMD worms. Interestingly, Thiamine was discovered to be an effective positive control, significantly reducing mitochondrial stress in this model. Two lead therapeutic candidates from the mitophagy library screen were Hemin and Celastrol (Tripterin). Celastrol is a mitophagy activating anti-inflammatory and metabolic modifying natural product derived compound, that rescued multiple fitness outcomes (thrashing, development, survival) and reduced the mitochondrial stress in uaDf5 animals in a mitophagy-dependent fashion. This study highlights the utility of the uaDf5 worm model to enable preclinical identification of therapeutic candidate leads for SLSMD-based heteroplasmic mtDNA diseases and identifies possible therapeutic candidates that serve as mitophagy modulators to improve health and specifically reduce heteroplasmy levels in SLSMD diseases.

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The role of mitochondrial dynamics and mitophagy in skeletal muscle atrophy: from molecular mechanisms to therapeutic insights

Cited by 3 publications

References 176 publications

Rotenone exposure causes features of Parkinson`s disease pathology linked with muscle atrophy in developing zebrafish embryo

Rotenone exposure causes features of Parkinson`s disease pathology linked with muscle atrophy in developing zebrafish embryo

The impact of physical activity on physical performance, mitochondrial bioenergetics, ROS production and calcium handling across the human adult lifespan

Mitophagy modulation rescues single large-scale mitochondrial DNA deletion (SLSMD) disease symptoms in theC. elegans uaDf5animal model

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