Antitumor activity of pazopanib (P) and trametinib (T) in preclinical models of osteosarcoma (OS).

Abstract

e22509 Background: Receptor tyrosine kinases (RTKs) and their signal transducers are suitable targets for the treatment of advanced OS. We evaluated the antitumor activity of the RTK inhibitor P and the MEK inhibitor T and deeply investigated molecular mechanisms behind their activity and potential escape. Methods: Flow cytometry and western blot analyses were carried out in 7 OS cell lines to study the expression of RTK P targets and the activation of their pathways, respectively. Cell viability and colony growth were evaluated after 72h and 7-day treatment respectively, with scalar doses of both single agents and their constant combination. Cell cycle distribution and apoptosis were evaluated by flow cytometry after 72h. In vivo antitumor activity was studied in NOD/SCID mice bearing MNNG-HOS xenografts after 3 weeks of treatment. Cell migration was studied by scratch assays. The involvement of MAPK-PI3K pathway key transducers was explored by Vantage 3D RNA Panel and Nanostring technology, validated by western blot and confirmed by silencing experiments. Results: P targets are expressed on OS cell lines and their pathways are activated. P+T have synergistic antitumor activity (combination index < 1) in OS cell lines by inducing apoptosis (6/7) and inhibiting both ERK1/2(7/7) and AKT (7/7). Furthermore, in vivo antitumor activity was shown in OS bearing mice (tumor volume: P+T/untreated = 0.036, p = 0.002). P+T significantly down-modulated RTK EphaA2 (mean log2 fold change RNA P+T/untreated = -2.02±0.50) and induced Janus kinase MEK6 (mean log2 fold change RNA P+T/untreated = 2.9±0.51). EphA2 silencing reduced cellular proliferation and migration of OS cells. Impeding MEK6-up-regulation in P+T treated cells significantly increased the antitumor effect (51.5±14.3%) of the studied drugs. Conclusions: P+T exert antitumor activity in OS preclinical models through ERK and AKT inhibition and EphA2 downmodulation. MEK6-upregulation after P+T is likely implied in escape mechanism.