Muscle-specific SMN reduction reveals motor neuron–independent disease in spinal muscular atrophy models
Jeong-Ki Kim, Narendra N. Jha, Zhihua Feng, Michelle R. Faleiro, Claudia A. Chiriboga, Lan Wei-Lapierre, Robert T. Dirksen, Chien-Ping Ko, Umrao R. Monani
Jeong-Ki Kim, Narendra N. Jha, Zhihua Feng, Michelle R. Faleiro, Claudia A. Chiriboga, Lan Wei-Lapierre, Robert T. Dirksen, Chien-Ping Ko, Umrao R. Monani
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Research Article Neuroscience

Muscle-specific SMN reduction reveals motor neuron–independent disease in spinal muscular atrophy models

Abstract

Paucity of the survival motor neuron (SMN) protein triggers the oft-fatal infantile-onset motor neuron disorder, spinal muscular atrophy (SMA). Augmenting the protein is one means of treating SMA and recently led to FDA approval of an intrathecally delivered SMN-enhancing oligonucleotide currently in use. Notwithstanding the advent of this and other therapies for SMA, it is unclear whether the paralysis associated with the disease derives solely from dysfunctional motor neurons that may be efficiently targeted by restricted delivery of SMN-enhancing agents to the nervous system, or stems from broader defects of the motor unit, arguing for systemic SMN repletion. We investigated the disease-contributing effects of low SMN in one relevant peripheral organ — skeletal muscle — by selectively depleting the protein in only this tissue. We found that muscle deprived of SMN was profoundly damaged. Although a disease phenotype was not immediately obvious, persistent low levels of the protein eventually resulted in muscle fiber defects, neuromuscular junction abnormalities, compromised motor performance, and premature death. Importantly, restoring SMN after the onset of muscle pathology reversed disease. Our results provide the most compelling evidence yet for a direct contributing role of muscle in SMA and argue that an optimal therapy for the disease must be designed to treat this aspect of the dysfunctional motor unit.

Authors

Jeong-Ki Kim, Narendra N. Jha, Zhihua Feng, Michelle R. Faleiro, Claudia A. Chiriboga, Lan Wei-Lapierre, Robert T. Dirksen, Chien-Ping Ko, Umrao R. Monani

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Figure 3

NMJ defects in MyoD-iCre SmnF7/– mutants with 1 copy of the SMN2 gene.

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NMJ defects in MyoD-iCre SmnF7/– mutants with 1 copy of the SMN2 gene. (...
(A) Transverse sections of the lumbar (L1–L3) spinal cord of a P21 mutant and control. Scale bar: 25 μm. Quantified results of (B) spinal motor neuron counts (L1–L3, T7–T10, C5–C6); (C) SMN signal intensity in the motor neurons; (D) nuclear gem counts in the motor neurons of the mice. NS: P > 0.05, t test, n > 150 cells and n = 4 mice from each group. (E) A lumbar motor neuron from a mutant showing robust SMN signal and the presence of nuclear gems (arrows). Scale bar: 8 μm. (F) NMJs in the intercostal muscles of mutant and control mice. Included are high-magnification images of typical endplates from each animal illustrating reduced complexity and presence of terminal varicosities engorged with NF (arrows) in the mutant. Scale bars: 50 μm and 15 μm, respectively. Graphs of (G) NMJ complexity, (H) endplate size, and (I) NMJ morphology in P21 mutants and controls. **P < 0.01; ***P < 0.001, t test, n ≥ 100 NMJs from n ≥ 3 mice from each group. (J) Atrogene protein expression in mutants and controls showed little change in these markers of denervation. NS: P > 0.05, t test, n = 3 mice.