AbstractProstate cancer mortality is associated with the metastatic spread of tumour cells. A better understanding of the mechanisms which allow a locally advanced tumour to disseminate around the body will identify new therapeutic targets to block this process. One of set of genes implicated in metastasis are plexins, which can promote or suppress tumour progression depending on cancer type and cellular context. We have taken a mouse genetics approach to gain insight into the role of Plexin-B1 in prostate cancer progression in vivo.We show here that genetic deletion of Plexin-B1 in PbCre+Ptenfl/flKrasG12V and PbCre+Ptenfl/flp53fl/fl mouse prostate cancer models significantly decreased metastasis. High levels of prostate epithelial cell-specific expression of wild-type Plexin-B1 in knock-in mice with a PbCre+Ptenfl/flKrasG12V background also significantly decreased metastasis. In contrast, expression of a Plexin-B1 mutant (P1597L; identified from metastatic deposits in prostate cancer patients) in prostate epithelial cells in PbCre+Ptenfl/flKrasG12V and PbCre+Ptenfl/flp53fl/fl mice significantly increased metastasis, in particular metastasis to distant sites. In line with these findings, both deletion and overexpression of wild-type Plexin-B1 reduced invasion of tumour cells into the prostate stroma, while overexpression of mutant Plexin-B1 significantly increased invasion, suggesting that Plexin-B1 has a role in the initial stages of metastasis. Invasion and metastasis also correlated with phosphorylation of myosin light chain, suggesting that Plexin-B1 signals via the Rho/ROCK pathway to promote metastasis.Our results demonstrate that mutant Plexin-B1 promotes metastasis in prostate cancer and represents a new therapeutic target to suppress tumour spread.
From mouse genetics to targeting the Rag GTPase pathway
