Edwin L. Steele Laboratory for Tumor Biology, Department of Radiation Oncology, Massachusetts General Hospital and Harvard Medical School, Boston, Massachusetts, USA.
Physiol Rev. 2011 Jul;91(3):1071-121. doi: 10.1152/physrev.00038.2010.
New vessel formation (angiogenesis) is an essential physiological process for embryologic development, normal growth, and tissue repair. Angiogenesis is tightly regulated at the molecular level. Dysregulation of angiogenesis occurs in various pathologies and is one of the hallmarks of cancer. The imbalance of pro- and anti-angiogenic signaling within tumors creates an abnormal vascular network that is characterized by dilated, tortuous, and hyperpermeable vessels. The physiological consequences of these vascular abnormalities include temporal and spatial heterogeneity in tumor blood flow and oxygenation and increased tumor interstitial fluid pressure. These abnormalities and the resultant microenvironment fuel tumor progression, and also lead to a reduction in the efficacy of chemotherapy, radiotherapy, and immunotherapy. With the discovery of vascular endothelial growth factor (VEGF) as a major driver of tumor angiogenesis, efforts have focused on novel therapeutics aimed at inhibiting VEGF activity, with the goal of regressing tumors by starvation. Unfortunately, clinical trials of anti-VEGF monotherapy in patients with solid tumors have been largely negative. Intriguingly, the combination of anti-VEGF therapy with conventional chemotherapy has improved survival in cancer patients compared with chemotherapy alone. These seemingly paradoxical results could be explained by a "normalization" of the tumor vasculature by anti-VEGF therapy. Preclinical studies have shown that anti-VEGF therapy changes tumor vasculature towards a more "mature" or "normal" phenotype. This "vascular normalization" is characterized by attenuation of hyperpermeability, increased vascular pericyte coverage, a more normal basement membrane, and a resultant reduction in tumor hypoxia and interstitial fluid pressure. These in turn can lead to an improvement in the metabolic profile of the tumor microenvironment, the delivery and efficacy of exogenously administered therapeutics, the efficacy of radiotherapy and of effector immune cells, and a reduction in number of metastatic cells shed by tumors into circulation in mice. These findings are consistent with data from clinical trials of anti-VEGF agents in patients with various solid tumors. More recently, genetic and pharmacological approaches have begun to unravel some other key regulators of vascular normalization such as proteins that regulate tissue oxygen sensing (PHD2) and vessel maturation (PDGFRβ, RGS5, Ang1/2, TGF-β). Here, we review the pathophysiology of tumor angiogenesis, the molecular underpinnings and functional consequences of vascular normalization, and the implications for treatment of cancer and nonmalignant diseases.
新血管形成(血管生成)是胚胎发育、正常生长和组织修复所必需的生理过程。血管生成在分子水平上受到严格调控。血管生成失调发生在各种病理状态下,是癌症的标志之一。肿瘤内促血管生成和抗血管生成信号的失衡导致异常的血管网络形成,其特征为扩张、扭曲和高通透性的血管。这些血管异常的生理后果包括肿瘤血流和氧合的时空调制以及肿瘤间质液压力增加。这些异常以及由此产生的微环境促进肿瘤进展,并导致化疗、放疗和免疫治疗的疗效降低。随着血管内皮生长因子 (VEGF) 作为肿瘤血管生成的主要驱动因素被发现,人们致力于开发新型治疗方法以抑制 VEGF 活性,以期通过饥饿使肿瘤消退。不幸的是,在实体瘤患者中进行的抗 VEGF 单药治疗的临床试验结果大多为阴性。有趣的是,与单独化疗相比,抗 VEGF 治疗联合常规化疗提高了癌症患者的生存率。这些看似矛盾的结果可以通过抗 VEGF 治疗对肿瘤血管的“正常化”来解释。临床前研究表明,抗 VEGF 治疗可使肿瘤血管向更“成熟”或“正常”表型转变。这种“血管正常化”的特征为通透性降低、血管周细胞覆盖率增加、基底膜更正常,以及肿瘤缺氧和间质液压力降低。这反过来又可以改善肿瘤微环境的代谢特征、外源性治疗药物的递送和疗效、放疗和效应免疫细胞的疗效以及肿瘤脱落到循环中的转移细胞数量减少。这些发现与各种实体瘤患者的抗 VEGF 药物临床试验数据一致。最近,遗传和药理学方法开始揭示血管正常化的其他一些关键调节因子,如调节组织氧感知的蛋白(PHD2)和血管成熟的蛋白(PDGFRβ、RGS5、Ang1/2、TGF-β)。在这里,我们综述了肿瘤血管生成的病理生理学、血管正常化的分子基础和功能后果,以及其对癌症和非恶性疾病治疗的影响。