Adipose tissue-derived stem cell secreted IGF-1 protects myoblasts from the negative effect of myostatin.
Sebastian GehmertCarina WenzelMarkus LoiblGero BrockhoffMichaela HuberWerner KrutschMichael NerlichMartin GosauSilvan KleinStephan SchremlLukas PrantlSanga GehmertPublished in: BioMed research international (2014)
Myostatin, a TGF-β family member, is associated with inhibition of muscle growth and differentiation and might interact with the IGF-1 signaling pathway. Since IGF-1 is secreted at a bioactive level by adipose tissue-derived mesenchymal stem cells (ASCs), these cells (ASCs) provide a therapeutic option for Duchenne Muscular Dystrophy (DMD). But the protective effect of stem cell secreted IGF-1 on myoblast under high level of myostatin remains unclear. In the present study murine myoblasts were exposed to myostatin under presence of ASCs conditioned medium and investigated for proliferation and apoptosis. The protective effect of IGF-1 was further examined by using IGF-1 neutralizing and receptor antibodies as well as gene silencing RNAi technology. MyoD expression was detected to identify impact of IGF-1 on myoblasts differentiation when exposed to myostatin. IGF-1 was accountable for 43.6% of the antiapoptotic impact and 48.8% for the proliferative effect of ASCs conditioned medium. Furthermore, IGF-1 restored mRNA and protein MyoD expression of myoblasts under risk. Beside fusion and transdifferentiation the beneficial effect of ASCs is mediated by paracrine secreted cytokines, particularly IGF-1. The present study underlines the potential of ASCs as a therapeutic option for Duchenne muscular dystrophy and other dystrophic muscle diseases.
Keyphrases
- binding protein
- pi k akt
- duchenne muscular dystrophy
- signaling pathway
- adipose tissue
- cell cycle arrest
- stem cells
- growth hormone
- poor prognosis
- induced apoptosis
- type diabetes
- skeletal muscle
- epithelial mesenchymal transition
- climate change
- mass spectrometry
- small molecule
- metabolic syndrome
- transforming growth factor
- atomic force microscopy
- protein protein