Additive effects of the combined expression of soluble forms of GAS1 and PTEN inhibiting glioblastoma growth.

The overexpression of GAS1 (Growth Arrest Specific 1) in glioma cells induces cell cycle arrest and apoptosis. We previously demonstrated that the apoptotic process set off by GAS1 is caused by its capacity to inhibit the Glial cell-derived neurotrophic factor (GDNF)-mediated intracellular survival signaling pathway. Whereas on the other hand, PTEN is a tumor suppressor, inactive in many tumors, and both GAS1 and PTEN inhibit the PI3K/AKT pathway. Therefore, it is relevant to investigate the potential additive effect of the overexpression of GAS1 and PTEN on tumor growth. In particular, we employed secreted forms of both GAS1 (tGAS1) and PTEN (PTEN-LONG, or PTEN-L) and tested their combined effect on glioma cells. We observed that the co-expression of both the proteins inhibited the growth of U-87 MG human glioblastoma cells more effectively than when independently expressed, and decreased the activity of both AKT and ERK1/2. Interestingly, the combination of the soluble forms was always the most effective treatment. To improve the transfer of tGAS1 and PTEN-L, we employed a lentiviral vector with a p2A peptide-enabled dual expression system that allowed the generation of the two proteins using a single promoter (CMV), in equimolar amounts. The viral vector reduced the growth of U-87 MG cells in vitro and had a striking effect in inhibiting their proliferation after inoculating it into the immunosuppressed mice. The present results support a potential adjuvant role for the combined use of tGAS1 and PTEN-L in the treatment of glioblastoma.

Annexin A1, Annexin A2, and Dyrk 1B are upregulated during GAS1-induced cell cycle arrest.

GAS1 is a pleiotropic protein that has been investigated because of its ability to induce cell proliferation, cell arrest, and apoptosis, depending on the cellular or the physiological context in which it is expressed. At this point, we have information about the molecular mechanisms by which GAS1 induces proliferation and apoptosis; but very few studies have been focused on elucidating the mechanisms by which GAS1 induces cell arrest. With the aim of expanding our knowledge on this subject, we first focused our research on finding proteins that were preferentially expressed in cells arrested by serum deprivation. By using a proteomics approach and mass spectrometry analysis, we identified 17 proteins in the 2-DE protein profile of serum deprived NIH3T3 cells. Among them, Annexin A1 (Anxa1), Annexin A2 (Anxa2), dual specificity tyrosine-phosphorylation-regulated kinase 1B (Dyrk1B), and Eukaryotic translation initiation factor 3, F (eIf3f) were upregulated at transcriptional the level in proliferative NIH3T3 cells. Moreover, we demonstrated that Anxa1, Anxa2, and Dyrk1b are upregulated at both the transcriptional and translational levels by the overexpression of GAS1. Thus, our results suggest that the upregulation of Anxa1, Anxa2, and Dyrk1b could be related to the ability of GAS1 to induce cell arrest and maintain cell viability. Finally, we provided further evidence showing that GAS1 through Dyrk 1B leads not only to the arrest of NIH3T3 cells but also maintains cell viability.