The protein, called “Tissue Factor,” is present in various tissues—for example, walls of blood vessels. Earlier studies suggested that alternatively spliced Tissue Factor (asTF) may contribute to cancer growth, but the molecular events leading to this were previously unknown.
New research conducted through an international collaboration between the labs of Vladimir Bogdanov, PhD, of the University of Cincinnati Cancer Institute, and Henri Versteeg, PhD, of the Einthoven Laboratory for Experimental Vascular Medicine at the Leiden University Medical Center in Leiden, the Netherlands, articulates how asTF fuels growth and metastasis of solid cancers.
Using preclinical animal models, Bogdanov and Versteeg’s teams obtained the first scientifically validated evidence that asTF promotes the spread of pancreatic cancer and promotes primary growth of breast cancer tumors.
“We have demonstrated that targeting asTF with a novel monoclonal antibody—developed based on our 10 years of studying asTF—also stops the growth of breast cancer in an animal model, giving us a promising new target to fight certain forms of breast cancer,” says Bogdanov, who originally described asTF in 2003. UC filed a patent for this technology in January 2013.
Bogdanov and Versteeg will present their findings at the XXIV Congress of the International Society on Thrombosis and Haemostasis in Amsterdam, the Netherlands (held June 29-July 4, 2013).
“Many molecules on the surface of cells—including integrins—are important for the function of both normal and cancerous cells, so targeting integrins for stopping the growth of cancer is not a promising strategy. What is unique about asTF is that it binds to integrins on vessel-forming cells, activating them. We’ve shown that certain cancer cells share those same qualities, so if you target asTF—which is elevated in cancer—there is significant potential to spare the ‘good’ parts of the cellular system while removing the ‘bad’ cancer-specific protein from the game,” explains Bogdanov.
“Many routine therapies such as chemotherapy or radiation may not always be efficient. Targeting asTF in tumors using our monoclonal antibody may form a potent additional anticancer strategy in combination with conventional avenues”, says Versteeg.
This work was funded by National Institutes of Health/National Cancer Institute grant 1R21CA160293-01A1 and the Netherlands Organization for Scientific Research VIDI grant 91710329. Authors on both manuscripts have no conflicts of interest to report.
Collaborators in the International Journal of Cancer study include UC’s Dusten Unruh, Kevin Turner, DO, Ramprasad Srinivasan, PhD, Xiaoyang Qi, PhD, Zhengtao Chu, , David Plas, PhD, Catherine Gallo, Syed Ahmad, MD, and Fred Lucas, MD; Begum Kocaturk of Einthoven Laboratory for Experimental Vascular Medicine; Bruce Aronow, PhD, of Cincinnati Children’s Hospital Medical Center; Holger Kalthoff, PhD, of the Institute of Experimental Cancer Research (Germany); Daniel Krichhofer, PhD of Genentech (California); and Wolfram Ruf, MD, of the Scripps Research Institute (California).
Collaborators in the PNAS study include Kocaturk and Yascha Van den Berg, MD, PhD, Martijn van der Ent, PhD, Pieter Reitsma, PhD and Susanne Osanto, PhD, of Einthoven Laboratory for Experimental Vascular Medicine; Chris Tieken, PhD, J. Sven D. Mieog, PhD, Charla Engels, PhD, Peter Kuppen, PhD, Cornelis Van de Velde, PhD, and Gerrit-Jan Liefers, PhD, of Leiden University Medical Center; and Dr Ruf of the Scripps Research Institute.
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