Ovarian cancer relies on the PDGFRß-fibronectin axis for tumorsphere formation and metastatic spread.

High-grade serous ovarian cancer (HGSOC) is the deadliest gynecological malignancy. The most common form of metastatic spread of HGSOC is transcoelomic dissemination. In this process, detached cells from the primary tumor aggregate as tumorspheres and promote the accumulation of peritoneal ascites. This represents an early event in HGSOC development and is indicative of poor prognosis. In this study, based on tumorspheres isolated from ascitic liquid samples from HGSOC patients, ovarian cancer spheroid 3D cultures, and in vivo models, we describe a key signal for tumorsphere formation in HGSOC. We report that platelet-derived growth factor receptor beta (PDGFRß) is essential for fibronectin-mediated cell clustering of ovarian cancer cells into tumorspheres. This effect is mediated by the kinase NUAK family SNF1-like kinase 1 (NUAK1) and blocked by PDGFRß pharmacological or genetic inhibition. In the absence of PDGFRß, ovarian cancer cells can be provided with fibronectin by cancer-associated fibroblasts to generate chimeric spheroids. This work provides new insights that uncover potential targets to prevent peritoneal dissemination, the main cause of advanced disease in HGSOC patients.

KRAS phosphorylation regulates cell polarization and tumorigenic properties in colorectal cancer.

Oncogenic mutations of KRAS are found in the most aggressive human tumors, including colorectal cancer. It has been suggested that oncogenic KRAS phosphorylation at Ser181 modulates its activity and favors cell transformation. Using nonphosphorylatable (S181A), phosphomimetic (S181D), and phospho-/dephosphorylatable (S181) oncogenic KRAS mutants, we analyzed the role of this phosphorylation to the maintenance of tumorigenic properties of colorectal cancer cells. Our data show that the presence of phospho-/dephosphorylatable oncogenic KRAS is required for preserving the epithelial organization of colorectal cancer cells in 3D cultures, and for supporting subcutaneous tumor growth in mice. Interestingly, gene expression differed according to the phosphorylation status of KRAS. In DLD-1 cells, CTNNA1 was only expressed in phospho-/dephosphorylatable oncogenic KRAS-expressing cells, correlating with cell polarization. Moreover, lack of oncogenic KRAS phosphorylation leads to changes in expression of genes related to cell invasion, such as SERPINE1, PRSS1,2,3, and NEO1, and expression of phosphomimetic oncogenic KRAS resulted in diminished expression of genes involved in enterocyte differentiation, such as HNF4G. Finally, the analysis, in a public data set of human colorectal cancer, of the gene expression signatures associated with phosphomimetic and nonphosphorylatable oncogenic KRAS suggests that this post-translational modification regulates tumor progression in patients.

SGK1 is a signalling hub that controls protein synthesis and proliferation in endothelial cells.

BMP9 is a cytokine involved in the maturation phase of the angiogenic process that signals through its serine/threonine receptor ALK1 and its coreceptor endoglin. In this paper, we explain how BMP9 directs the regulation of endothelial cell proliferation blockage while in turn stimulating protein synthesis. To achieve this, BMP9 promotes SGK1 synthesis and activation through mTORC2 in order to stimulate the mTORC1/S6K/S6 axis. Moreover, BMP9 blocks proliferation also through SGK1 by reducing the activity of the MEK/ERK signalling pathway. Inhibition of SGK1 activity is sufficient to prevent BMP9-mediated inhibition of ERK, leading to an increase in endothelial cell proliferation. Overall, our findings reveal that SGK1 is a key player during angiogenesis, mediating the pro-quiescent and maturation effects of BMP9/ALK1.