Molecular mechanisms of the cytotoxic effect of FGF2 in rastransformed cells

FGF2 (Fibroblast Growth Factor 2) is a classic peptide growth factor that activates intracellular molecular signaling pathways promoting the G0 → G1 transition and cell cycle commitment. Not surprisingly, its pro-tumor and angiogenic roles are well characterized and established in the literature. However, a growing body of evidence has indicated that FGF2 may also exert anti-tumor effects in vitro and in vivo in murine and human models. In this context, our group reported in 2008 that FGF2 exerts a selective antiproliferative effect in murine cells dependent on high activity of K-Ras and H-Ras. Ras genes make up the most frequently mutated oncogene family in human malignant tumors, reaching approximately 30% of all cases. The development of therapies against Ras-dependent tumors has failed despite intense efforts and investments since the discovery in 1982 of its activating mutations in multiple cancers. The objective of this work was to uncover the molecular mechanisms by which FGF2 irreversibly inhibits the proliferation of malignant cells dependent on Ras activity, using as experimental models the Y1 murine lineage of adrenocortical malignant cells and 4 human lineages derived from Ewing sarcomas. We showed that the cytotoxic effect of FGF2 did not involve novel cell cycle regulatory pathways; instead, this cytotoxic effect is a result of sustainedhyper mitogenic stimulation by FGF2. Activation of the KRas/MAPK pathway, the major intracellular mitogenic signaling, at high and sustained levels provokes mitogenic stress, which is propagated to S phase as replicative stress. In this situation, the cell dependence on the ATR protective signaling is enhanced, so that the combination of stimulation with FGF2 and inhibition of ATR was highly lethal for the Ras dependent malignant cells employed in this work. We also analyzed the molecular basis of FGF2 resistance exhibited by Y1 cells previously selected for resistance to FGF2. We found that the selective pressure of FGF2 had no effect on the expression of its receptors but promoted the elimination of one of the two marker chromosomes that carry the K-ras amplified copies, while the second chromosome was maintained because it is the only source of active ribosomal genes; however, its K-ras amplified copies were transcriptionally silenced. In addition, the Y1FRs sublines did not express the main RasGEF, GRP4, found in the parental Y1 cells, which might have played a role in the emergence of the FGF2-resistant phenotype. The resistant Y1FRs sublines showed a large reduction in chromosome numbers and increased frequency of fusions between non-homologous chromosomes in relation to parental cells. (AU)