Published 2018-12-30
Keywords
- Rapamycin,
- mTOR,
- stem cells,
- neuronal differentiation,
- transmission electron microscopy
How to Cite
Abstract
Glioblastoma multiforme (GBM; grade IV glioma) is the most common and highly malig- nant primary brain tumor [1]. GBM cells feature mammalian target of rapamycin (mTOR) up-regulation which relates to biological properties of normal stem cells, such as self-renew- al, pluripotency and marked proliferation. Thus, they are key in tumor initiation, relapse and resistance to standard treatments [2-4].
Therefore, in the present study we show the effects of different doses of rapamycin on (i) the phenotype of different GBM cell lines; (ii) the number and the ultrastructural morphology of mitochondria. By means of genetic, immunoblotting and morphological analysis at light and electron microscopy, we demonstrate that rapamycin reduces the stem-like phenotype, pro- motes the neuronal differentiation of GBM cells, and increases the amount of mitochondria by enhancing the mitochondrial fission and mitochondriogenesis. This induced a marked reduc- tion of the stemness marker Nestin, while stimulating gene transcription related to neuronal differentiation, namely the early (beta-III tubulin) and late (NeuN) neuronal markers. No effects were produced for GFAP glial marker. Remarkably, in these experimental conditions, cell phe- notype shifts towards a pyramidal neuron-like shape owing long branches.