Roodink Ilse, van der Laak Jeroen, Kusters Benno, Wesseling Pieter, Verrijp Kiek, de Waal Robert, Leenders William
Department of Pathology, Nijmegen Centre for Molecular Life Sciences, Radboud University Nijmegen Medical Centre, Nijmegen, The Netherlands.
Int J Cancer. 2006 Nov 1;119(9):2054-62. doi: 10.1002/ijc.22072.
Tumors arise initially as avascular masses in which central hypoxia induces expression of vascular endothelial growth factor-A (VEGF-A) and subsequently tumor vascularization. However, VEGF-A can also be constitutively expressed as a result of genetic events. VEGF-A is alternatively spliced to yield at least 6 different isoforms. Of these, VEGF-A(121) is freely diffusible whereas basically charged domains in the larger isoforms confer affinity for cell surface or extracellular matrix components. We previously reported that in a mouse brain metastasis model of human melanoma, VEGF-A(121) induced a qualitatively different tumor vascular phenotype than VEGF-A(165) and VEGF-A(189): in contrast to the latter ones, and VEGF-A(121) did not induce a neovascular bed but rather led to leakage and dilatation of preexistent brain vessels. Here, we correlate vascular phenotypes with spatial VEGF-A expression profiles in clinical brain tumors (low grade gliomas; n = 6, melanoma metastases; n = 4, adenocarcinoma metastases; n = 4, glioblastoma multiforme; n = 3, sarcoma metastasis; n = 1, renal cell carcinoma metastasis; n = 1). We show that tumors that constitutively express VEGF-A present with different vascular beds than tumors in which VEGF-A is expressed as a response to central hypoxia. This phenotypic difference is consistent with a model where in tumors with constitutive VEGF-A expression, all isoforms exert their effects on vasculature, resulting in a classical angiogenic phenotype. In tumors where only central parts express hypoxia-induced VEGF-A, the larger angiogenic isoforms are retained by extracellular matrix, leaving only freely diffusible VEGF-A(121) to exert its dilatation effects on distant vessels.
肿瘤最初表现为无血管肿块,其中央缺氧诱导血管内皮生长因子 -A(VEGF -A)表达,随后肿瘤发生血管化。然而,由于基因事件,VEGF -A也可组成性表达。VEGF -A可选择性剪接产生至少6种不同的异构体。其中,VEGF -A(121)可自由扩散,而较大异构体中的碱性结构域使其对细胞表面或细胞外基质成分具有亲和力。我们之前报道,在人黑色素瘤的小鼠脑转移模型中,VEGF -A(121)诱导的肿瘤血管表型与VEGF -A(165)和VEGF -A(189)在性质上不同:与后两者相反,VEGF -A(121)不诱导新生血管床,而是导致已存在的脑血管渗漏和扩张。在此,我们将血管表型与临床脑肿瘤(低级别胶质瘤;n = 6,黑色素瘤转移瘤;n = 4,腺癌转移瘤;n = 4,多形性胶质母细胞瘤;n = 3,肉瘤转移瘤;n = 1,肾细胞癌转移瘤;n = 1)中的VEGF -A空间表达谱相关联。我们发现,组成性表达VEGF -A的肿瘤与因中央缺氧而表达VEGF -A的肿瘤具有不同的血管床。这种表型差异与一种模型一致,即在组成性表达VEGF -A的肿瘤中,所有异构体均对脉管系统发挥作用,导致典型的血管生成表型。在仅中央部分表达缺氧诱导的VEGF -A的肿瘤中,较大的血管生成异构体被细胞外基质保留,仅留下可自由扩散的VEGF -A(1^21)对远处血管发挥扩张作用。
