Dynamics of vascular normalization during anti-angiogenic therapy : implications for combination therapy

摘要

Solid tumors require blood vessels for growth, and the goal of anti-angiogenic therapy is to destroy the tumor vasculature. Recent findings suggest that anti-angiogenic therapy enhances radiation and chemotherapy responses. These findings seem paradoxical, since anti-angiogenic therapy prunes tumor vasculature while chemotherapy and radiation therapy rely on the vasculature to transport cancer drugs and oxygen, respectively, to cancer cells. To resolve this paradox, we propose that anti-angiogenic therapy can "normalize" the tumor vasculature transiently, resulting in a more efficient delivery of drugs and oxygen to cancer cells. We first show that DC101, a monoclonal antibody targeting Vascular Endothelial Growth Factor Receptor 2 (VEGFR2), prunes immature blood vessels, reduces vascular diameter and improves pericyte and basement membrane coverages. Functionally, the vascular permeability to macromolecules and interstitial fluid pressure are reduced. By lowering interstitial fluid pressure while maintaining microvascular pressure, DC101 induces a hydrostatic pressure gradient across the vascular wall, which leads to enhanced penetration of macromolecules in tumors. Tumor hypoxia is also reduced, and it is associated with the increased red blood cell velocity after DC101 treatment. Using gene array, real time PCR and Western blot analyses, changes in angiopoietin-2 level during DC101 treatment are identified. To test if similar effects happen in clinical setting, we obtained tumor biopsy samples from rectal adenocarcinoma patients treated with bevacizumab, an anti-VEGF monoclonal antibody.