Expression of tumor endothelial markers (TEMs) in vitro in a canine hemangiosarcoma model of malignant angiogenesis.

Abstract

e21145 Background: Expression of tumor endothelial markers (TEMs) in tumor-associated blood vessels presents opportunities for targeted therapy. TEM7 and TEM8 are selectively expressed and are associated with a worse prognosis in cancer patients. TEM expression is conserved across species, however species differences do exist as TEM7 is undetectable in murine tumor endothelium. Thus, further investigation of the role of TEMs in malignant angiogenesis is hindered by the lack of optimal animal tumor models. Canine hemangiosarcoma is relevant spontaneous model of malignant angiogenesis based on archetypal cell markers, endothelial functionality, growth factor/receptor expression, and angiogenic gene expression. The aims of this study were to characterize the in vitro expression of TEM7 and TEM8 in canine hemangiosarcoma as a novel model of malignant angiogenesis. Methods: Two canine hemangiosarcoma cell lines were assessed (Den and Fitz). Total RNA was isolated using standard technique, reverse transcribed to cDNA, and amplified by polymerase chain reaction (PCR) reaction using degenerate primers specific for human and murine TEM7 transcripts with forward and reverse primers. Protein expression of TEM7 and TEM8 in cell lysates was evaluated via Western blotting and cell surface expression was analyzed by flow cytometry. Polyclonal anti-TEM7 and anti-TEM8 antibodies (Sigma-Aldrich) were used with positive and negative controls. Results: Basal in vitro expression of TEM7 mRNA was confirmed in canine hemangiosarcoma, as well as in vitro protein expression of TEM7 and TEM8 via Western blotting and flow cytometry. Conclusions: The validation of TEM expression in canine hemangiosarcoma establishes TEM7 and TEM8 as promising targets for further evaluation in this novel model of malignant angiogenesis, and investigation of TEM-targeting is ongoing. This may represent a novel spontaneous animal tumor model for investigation of tumor vascular targeting.