As primary tumor progression to metastasis dramatically increases mortality in patients with cancer, strategies to limit tumor cell growth and spread are of great interest. The orphan receptor tyrosine kinase Tie1 is highly expressed in intratumoral vasculature; however, the contribution of this receptor to tumor progression has not been defined. In this episode, Hellmut Augustin and Silvia La Porta, aided by original artwork by Carleen Spegg, discuss their work, which shows that loss of Tie1 in endothelial cells reduces primary tumor progression and limits metastasis. The results of this study indicate that Tie1 should be further explored as a therapeutic target for limiting cancer progression.
The endothelial tyrosine kinase receptor Tie1 remains poorly characterized, largely owing to its orphan receptor status. Global Tie1 inactivation causes late embryonic lethality, thereby reflecting its importance during development. Tie1 also plays pivotal roles during pathologies such as atherosclerosis and tumorigenesis. In order to study the contribution of Tie1 to tumor progression and metastasis, we conditionally deleted Tie1 in endothelial cells at different stages of tumor growth and metastatic dissemination. Tie1 deletion during primary tumor growth in mice led to a decrease in microvessel density and an increase in mural cell coverage with improved vessel perfusion. Reduced angiogenesis and enhanced vascular normalization resulted in a progressive increase of intratumoral necrosis that caused a growth delay only at later stages of tumor progression. Concomitantly, surgical removal of the primary tumor decreased the number of circulating tumor cells, reduced metastasis, and prolonged overall survival. Additionally, Tie1 deletion in experimental murine metastasis models prevented extravasation of tumor cells into the lungs and reduced metastatic foci. Taken together, the data support Tie1 as a therapeutic target by defining its regulatory functions during angiogenesis and vascular abnormalization and identifying its role during metastasis.
Silvia La Porta, Lise Roth, Mahak Singhal, Carolin Mogler, Carleen Spegg, Benjamin Schieb, Xianghu Qu, Ralf H. Adams, H. Scott Baldwin, Soniya Savant, Hellmut G. Augustin