Spinal muscular atrophy (SMA) is a debilitating neuromuscular disorder caused by a mutation in the survival motor neuron 1 (SMN1) gene and it is the leading genetic cause of infant mortality. Recently approved genetic therapies designed to augment full length SMN protein in the central nervous system fail to ameliorate abnormal skeletal muscle features, which strongly suggests an important role for SMN protein in skeletal muscle homeostasis. This study aimed to characterize key modifiers of skeletal muscle mitochondrial turnover and dynamics during disease progression in a pre‐clinical murine model of SMA in vivo. Additionally, we investigated the effects of a single dose of exercise on these mitochondrial biology‐regulating pathways in the skeletal muscle of SMA mice. Muscle samples were collected from wild‐type (WT) and Smn2B/‐ (SMA) mice at postnatal day 9 (P9), P13, and P21 to examine skeletal muscle‐specific disease progression. Mitochondrial content did not differ between genotypes at all timepoints as evident by similar levels of mitochondrial oxidative phosphorylation proteins, succinate dehydrogenase staining, and citrate synthase content. However, mRNA content of key genes responsible for regulating mitochondrial quality such as nuclear respiratory factor 2, mitochondrial transcription factor A, and p53 were significantly higher in SMA mice versus WT at P21. Additionally, we observed elevated mitochondrial fission activity as indicated by a 2‐fold increase (p < 0.05) in dynamin related protein 1 (DRP1) activation. Concomitantly, the expression of several mitophagy proteins including BLC2 interacting protein 3, parkin, and PTEN‐induced kinase 1 were significantly increased by 2.9‐, 2.7‐, and 2‐fold, respectively, compared to WT animals at P21. Interestingly, we observed blunted (p < 0.05) inclusion of optic atrophy 1 exon 4b, a key exon in mitochondrial biogenesis, between WT and SMA mice at P21. Acute exercise significantly increased the inhibition of DRP1‐mediated mitochondrial fission activity in the muscles of SMA mice relative to sedentary SMA mice. However, a single exercise dose failed to alter the expression of mitophagy proteins up to three hours after running. Our data demonstrate that skeletal muscle mitochondrial health is compromised in SMA mice due to elevated fission and mitophagy processes. Furthermore, SMA mice display aberrant alternative splicing of Opa1 transcripts that may in turn hinder mitochondrial biogenesis in later disease stages. We also highlight that an acute bout of treadmill running elicits pro‐fusion signaling to potentially improve the mitochondrial reticulum. Collectively, this study is the first to reveal mitochondrial dysfunction in SMA skeletal muscle and outlines signalling associated with mitochondrial plasticity following a single dose of exercise.
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