Requirement of enhanced Survival Motoneuron protein imposed during neuromuscular junction maturation
Shingo Kariya, … , Shunichi Homma, Umrao R. Monani
Shingo Kariya, … , Shunichi Homma, Umrao R. Monani
Published January 27, 2014
Citation Information: J Clin Invest. 2014;124(2):785-800. https://doi.org/10.1172/JCI72017.
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Requirement of enhanced Survival Motoneuron protein imposed during neuromuscular junction maturation

Abstract

Spinal muscular atrophy is a common motor neuron disease caused by low survival motoneuron (SMN), a key protein in the proper splicing of genes. Restoring the protein is therefore a promising therapeutic strategy. Implementation of this strategy, however, depends on defining the temporal requirements for SMN. Here, we used controlled knockdown of SMN in transgenic mice to determine the precise postnatal stage requirements for this protein. Reducing SMN in neonatal mice resulted in a classic SMA-like phenotype. Unexpectedly, depletion of SMN in adults had relatively little effect. Insensitivity to low SMN emerged abruptly at postnatal day 17, which coincided with establishment of the fully mature neuromuscular junction (NMJ). Mature animals depleted of SMN eventually exhibited evidence of selective neuromuscular pathology that was made worse by traumatic injury. The ability to regenerate the mature NMJ in aged or injured SMN-depleted mice was grossly impaired, a likely consequence of the inability to meet the surge in demand for motoneuronal SMN that was seen in controls. Our results demonstrate that relative maturity of the NMJ determines the temporal requirement for the SMN protein. These observations suggest that the use of potent but potentially deleterious SMN-enhancing agents could be tapered in human patients once the neuromuscular system matures and reintroduced as needed to enhance SMN for remodeling aged or injured NMJs.

Authors

Shingo Kariya, Teresa Obis, Caterina Garone, Turgay Akay, Fusako Sera, Shinichi Iwata, Shunichi Homma, Umrao R. Monani

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Figure 5

An elevated demand for motor neuronal SMN as disrupted NMJs remodel and mature.

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An elevated demand for motor neuronal SMN as disrupted NMJs remodel and ...
(A) Immunostains of spinal cord sections from TM-treated 2-copy SMN2;SmnF7/– mice with or without the CreER transgene 30 days following nerve crush. An elevation in the number of gems (arrows) and cytoplasmic SMN is evident in ipsilateral motor neurons of the CreER spinal cord. Scale bars: 240 μm; 30 μm (detail). (B) Quantification of motor neurons in the cords of the mice failed to reveal evidence of cell loss. n ≥ 3 mice of each genotype, t tests. However, (C) cytoplasmic SMN levels and (D) nuclear gems of the ipsilateral motor neurons rose following the nerve crush. Especially evident is the increase which peaks at day 30 after the crush in the CreER-negative animals. Cytoplasmic SMN staining in at least 150 motor neurons from 3 mice of each cohort was assessed; ≥ 300 nuclei were examined for gems. **P < 0.01; ***P < 0.001, 1-way ANOVA for the analyses.