Abstract
Duchenne muscular dystrophy is a deadly muscle-wasting disorder caused by loss of dystrophin protein. Studies suggest that metabolic alterations are important to disease pathogenesis. Because muscle accounts for ~40% of body mass, we hypothesized that dystrophy-mediated metabolic changes would be measurable in biofluids and that a metabolomic analysis of urine would provide insight into the metabolic status of dystrophic muscle. Using the mdx mouse model, we performed a large-scale metabolomic screen at 1 and 3months. While 10% of metabolites were altered at age 1month, 40% were changed at 3months. Principal component analysis distinguished wild-type from mdx animals, with the greatest separation at 3months. A critical distinguishing pathway was Krebs cycle metabolite depletion in mdx urine. Five of seven detected Krebs cycle metabolites were depleted in mdx urine, with succinate being the most robustly affected metabolite. Using selected reaction monitoring mass spectrometry, we demonstrated that muscle-specific dystrophin expression corrects mdx succinate depletion. When subjected to downhill treadmill running, wild-type and mdx mice expressing recombinant dystrophin in skeletal muscle displayed significant increases in urinary succinate levels. However, mdx succinate levels were unchanged, suggesting urinary succinate depletion may reflect an inability to upregulate the Krebs cycle following exercise. Finally, we show that supplementing the Krebs cycle in an ex vivo fatigue/recovery assay significantly impacts mdx muscle performance but has no effect on wild-type muscle. Our results suggest that global metabolic impairment is associated with mdx disease progression and that Krebs cycle deficiencies are a downstream consequence of dystrophin loss.
Highlights
Duchenne muscular dystrophy (DMD) is a deadly musclewasting disorder that affects approximately 1 in every 5000 newborn males [1]
Using a selected reaction monitoring (SRM) mass spectrometric assay, we demonstrate that succinate is depleted in quadriceps and heart of mdx mice while urinary succinate levels are normalized in transgenic mdx mice expressing nearly full-length recombinant dystrophin
We demonstrate that moderate treadmill exercise induced significant increases in urinary succinate in wild-type and mdx/D71–78 mice, but not in mdx mice, suggesting that Krebs-Ringer bicarbonate (Krebs) cycle depletion is due to decreased flux through the Krebs cycle in response to exercise in mdx mice
Summary
Duchenne muscular dystrophy (DMD) is a deadly musclewasting disorder that affects approximately 1 in every 5000 newborn males [1]. Human Molecular Genetics, 2019, Vol 28, No 6 943 to subsarcolemmal protein complexes called costameres where, via interactions with cortical actin filaments and the dystrophin glycoprotein complex, it links the intracellular cytoskeleton to the extracellular matrix [5,6]. These interactions are critical for the maintenance of sarcolemmal integrity during muscle contraction. While the full consequences of the dystrophin/ microtubule interaction remain to be determined, it appears that disruption may be involved in sensitivity to eccentric contractions [11,13], increased reactive oxygen species and aberrant calcium regulation [7,14]
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