The Smn-Independent Beneficial Effects of Trichostatin A on an Intermediate Mouse Model of Spinal Muscular Atrophy

Trichostatin A (TSA) is a histone deacetylase inhibitor with beneficial effects in spinal muscular atrophy mouse models that carry the human SMN2 transgene. Whether TSA specifically targets the upregulation of the SMN2 gene or whether other genes respond to TSA and in turn provide neuroprotection in...

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Bibliographic Details
Main Author: Yazdani, Armin A.
Other Authors: Kothary, Rashmi
Language:en
Published: Université d'Ottawa / University of Ottawa 2014
Subjects:
Online Access:http://hdl.handle.net/10393/30703
http://dx.doi.org/10.20381/ruor-3597
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Summary:Trichostatin A (TSA) is a histone deacetylase inhibitor with beneficial effects in spinal muscular atrophy mouse models that carry the human SMN2 transgene. Whether TSA specifically targets the upregulation of the SMN2 gene or whether other genes respond to TSA and in turn provide neuroprotection in SMA mice is unclear. We have taken advantage of the Smn2B/- mouse model that does not harbor the human SMN2 transgene, to test the hypothesis that TSA has its beneficial effects through a non-Smn mediated pathway. Daily intraperitoneal injection of TSA from postnatal day 12 to 25 was performed in the Smn2B/- mice and littermate controls. Previous work from our laboratory demonstrated that treatment with TSA increased the median lifespan of Smn2B/- mice from twenty days to eight weeks. As well, there was a significant attenuation of weight loss and improved motor behavior. Pen test and righting reflex both showed significant improvement, and motor neurons in the spinal cord of Smn2B/-mice were protected from degeneration. Both the size and maturity of neuromuscular junctions were significantly improved in TSA treated Smn2B/- mice. Here, we have shown that TSA treatment does not increase the levels of Smn protein in mouse embryonic fibroblasts or myoblasts obtained from the Smn2B/- mice. Further, qPCR analysis revealed no changes in the level of Smn transcripts in the brain or spinal cord of TSA-treated SMA mice. Similarly, western blot analysis revealed no significant increase in Smn protein levels in the brain, spinal cord, hind limb muscle, heart muscle, or the liver of TSA treated Smn2B/- mice. However, TSA has beneficial effects in the muscles of Smn2B/- mice and improves motor behavior and myofiber size. TSA improves muscle development by enhancing the activity of myogenic regulatory factors independent of the Smn gene. The beneficial effect of TSA is therefore likely through an Smn-independent manner. Identification of these protective pathways will be of therapeutic value for the treatment of SMA.