Abstract
Epithelial ovarian cancer (EOC) is a highly heterogeneous disease with a high death rate mainly due to the metastatic spread. The expression of MDM4, a well-known p53-inhibitor, is positively associated with chemotherapy response and overall survival (OS) in EOC. However, the basis of this association remains elusive. We show that in vivo MDM4 reduces intraperitoneal dissemination of EOC cells, independently of p53 and an immune-competent background. By 2D and 3D assays, MDM4 impairs the early steps of the metastatic process. A 3D-bioprinting system, ad hoc developed by co-culturing EOC spheroids and endothelial cells, showed reduced dissemination and intravasation into vessel-like structures of MDM4-expressing cells. Consistent with these data, high MDM4 levels protect mice from ovarian cancer-related death and, importantly, correlate with increased 15 y OS probability in large data set analysis of 1656 patients. Proteomic analysis of EOC 3D-spheroids revealed decreased protein synthesis and mTOR signaling, upon MDM4 expression. Accordingly, MDM4 does not further inhibit cell migration when its activity towards mTOR is blocked by genetic or pharmacological approaches. Importantly, high levels of MDM4 reduced the efficacy of mTOR inhibitors in constraining cell migration. Overall, these data demonstrate that MDM4 impairs EOC metastatic process by inhibiting mTOR activity and suggest the usefulness of MDM4 assessment for the tailored application of mTOR-targeted therapy.
Highlights
Epithelial ovarian carcinoma (EOC) is the gynecological tumor with the highest death rate[1,2]
MDM4 reduces EOC cell dissemination To ascertain the function of MDM4 in EOC progression, we analyzed the dissemination of EOC cells by IP injection of the human ovarian cancer cell line SK-OV-3
SK-OV-3 cells metastasize through both routes in murine models[5] To test the effects of MDM4 on intravasation ability of EOC cells, we developed an ad hoc 3D-bioprinting assay composed of SK-OV-3 cells in co-culture with HUVEC
Summary
Epithelial ovarian carcinoma (EOC) is the gynecological tumor with the highest death rate[1,2]. One important factor concurring with this aggressiveness is the rapid and silent dissemination of ovarian cancer cells to the peritoneal cavity, with up to 75% of patients showing transcoelomic metastasis at presentation[2]. Despite the recognition of different histotypes and subgroups, a signature predictive of EOC tumor progression has not yet been identified. This is attributed to the high heterogeneity of the disease with at least 15 oncogenes and 168 epigenetic alterations implicated, making targeted therapy for ovarian cancer highly challenging[2,7,8].
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