Background: Expression of polyomavirus middle T antigen (PymT) rapidly induces endothelial tumors (hemangiomas) in mice, with an apparent single rate-limiting step. Because activation of Src-like kinases is thought to be an important component of PymT-induced transformation, we have analyzed the functional requirement for individual kinases in this process. This type of analysis has only recently become possible, with the generation of 'gene knock-out' mice lacking each of the kinase genes src, fyn and yes.
Results: Hemangiomas develop efficiently in newborn mice lacking either src, fyn or yes after inoculation with a PymT-transducing retrovirus. In src- and fyn-deficient mice, the kinetics of induction and the histological properties of the tumors were indistinguishable from those in wild-type mice. In contrast, a reduced number of tumors arose in yes-deficient mice, with a significantly longer latency period. Transformed endothelial cell lines derived from the induced hemangiomas, however, did not differ in their morphological and tumorigenic properties from cell lines established previously from wild-type mice. Biochemical analysis of complexes between PymT and the Src-related kinases in these cell lines suggests that the Yes kinase is responsible for a significant amount of the PymT-associated kinase activity in transformed endothelial cells.
Conclusion: We have demonstrated that inactivation of a single tyrosine kinase of the Src family in endothelial cells does not abrogate PymT-induced hemangioma formation. As the remaining kinases do not compensate for the absence of a family member by elevated kinase activity, the loss--which affects the transformation process to varying degrees--can be studied in this model system. Our studies suggest that the PymT-Yes kinase complex plays a major role in the tumor-initiating action of PymT.