Selective ablation of immature blood vessels in established human tumors follows vascular endothelial growth factor withdrawal

Features that distinguish tumor vasculatures from normal blood vessels are sought to enable the destruction of preformed tumor vessels. We show that blood vessels in both a xenografted tumor and primary human tumors contain a sizable fraction of immature blood vessels that have not yet recruited periendothelial cells. These immature vessels are selectively obliterated as a consequence of vascular endothelial growth factor (VEGF) withdrawal. In a xenografted glioma, the selective vulnerability of immature vessels to VEGF loss was demonstrated by downregulating VEGF transgene expression using a tetracycline-regulated expression system. In human prostate cancer, the constitutive production of VEGF by the glandular epithelium was suppressed as a consequence of androgen-ablation therapy. VEGF loss led, in turn, to selective apoptosis of endothelial cells in vessels devoid of periendothelial cells. These results suggest that the unique dependence on VEGF of blood vessels lacking periendothelial cells can be exploited to reduce an existing tumor vasculature.     

Expression of the vascular endothelial growth factor (VEGF) family in human endometrial blood vessels

Endometrial regrowth is associated with intense angiogenesis, for which vascular endothelial growth factor-A (VEGF-A) is an important regulator. However, the expression of other members of the VEGF family is less well documented. The aim of this study was to localize members of the VEGF family (VEGF-A,-B and-C), and their receptors (VEGFR1, 2 and 3) in human endometrial blood vessels. Endometrial biopsies collected from four healthy and fertile women were used for immunohistochemistry assessments. Co-localization of VEGF-family proteins with CD34 stained endothelial structures was determined by image analysis. We demonstrate here the marked expression of VEGF-A as well as VEGFR2 and 3 in capillaries. Arterioles expressed VEGF-B, VEGFR1, 2, and 3 moderately and VEGF-A variably. Venules expressed only VEGFR3 markedly. In contrast, VEGF-C was not expressed in the arterioles, but moderately in the capillaries and weakly in the venules. VEGF-B was expressed in all blood vessels; however, VEGF-B was weakly expressed in capillaries and arterioles and moderately expressed in venules and arterioles. Thus, expression of VEGF-A, B and C and VEGF receptors 1-3 in endometrial blood vessels indicates a highly structured involvement of VEGF in the regulation of angiogenesis in the human endometrium.     

Expression of the vascular endothelial growth factor (VEGF) family in human endometrial blood vessels

Endometrial regrowth is associated with intense angiogenesis, for which vascular endothelial growth factor-A (VEGF-A) is an important regulator. However, the expression of other members of the VEGF family is less well documented. The aim of this study was to localize members of the VEGF family (VEGF-A, -B and -C), and their receptors (VEGFR1, 2 and 3) in human endometrial blood vessels. Endometrial biopsies collected from four healthy and fertile women were used for immunohistochemistry assessments. Co-localization of VEGF-family proteins with CD34 stained endothelial structures was determined by image analysis. We demonstrate here the marked expression of VEGF-A as well as VEGFR2 and 3 in capillaries. Arterioles expressed VEGF-B, VEGFR1, 2, and 3 moderately and VEGF-A variably. Venules expressed only VEGFR3 markedly. In contrast, VEGF-C was not expressed in the arterioles, but moderately in the capillaries and weakly in the venules. VEGF-B was expressed in all blood vessels; however, VEGF-B was weakly expressed in capillaries and arterioles and moderately expressed in venules and arterioles. Thus, expression of VEGF-A. B and C and VEGF receptors 1-3 in endometrial blood vessels indicates a highly structured involvement of VEGF in the regulation of angiogenesis in the human endometrium.     

Overexpression of vascular permeability factor/vascular endothelial growth factor and its receptors in psoriasis

Psoriatic skin is characterized by microvascular hyperpermeability and angioproliferation, but the mechanisms responsible are unknown. We report here that the hyperplastic epidermis of psoriatic skin expresses strikingly increased amounts of vascular permeability factor (VPF; vascular endothelial growth factor), a selective endothelial cell mitogen that enhances microvascular permeability. Moreover, two VPF receptors, kdr and flt-1, are overexpressed by papillary dermal microvascular endothelial cells. Transforming growth factor alpha (TGF- alpha), a cytokine that is also overexpressed in psoriatic epidermis, induced VPF gene expression by cultured epidermal keratinocytes. VPF secreted by TGF-alpha-stimulated keratinocytes was bioactive, as demonstrated by its mitogenic effect on dermal microvascular endothelial cells in vitro. Together, these findings suggest that TGF- alpha regulates VPF expression in psoriasis by an autocrine mechanism, leading to vascular hyperpermeability and angiogenesis. Similar mechanisms may operate in tumors and in healing skin wounds which also commonly express both VPF and TGF-alpha.     

卵巢肿瘤的血管内皮生长因子表达和肿瘤微血管密度计数的意义

目的探讨血管内皮生长因子(VEGF)蛋白表达和肿瘤微血管密度(MVD)与卵巢恶性肿瘤预后的关系。方法采用免疫组织化学染色的方法检测94例卵巢上皮性肿瘤患者(其中良性上皮性肿瘤患者17例,交界性上皮性肿瘤患者13例,上皮性卵巢癌患者64例)中VEGF表达情况及MVD计数。结果在上皮性卵巢癌、交界性上皮肿瘤、良性卵巢肿瘤中VEGF阴性分别为:2例(3%)、4例(31%)、16例(94%);VEGF低度表达分别为:31例(48%)、7例(54%)、1例(6%);VEGF高度表达分别为:31例(48%)、2例(15%)、0例。VEGF蛋白高度表达与肿瘤的临床分期、细胞分化程度及患者预后有明显的相关性。MVD与肿瘤的临床病理特征无明显的相关性。VEGF蛋白高度表达者的生存率比VEGF无或低度表达者差。结论VEGF蛋白表达的测定可以帮助判断卵巢上皮癌患者的预后,在指导临床治疗方面有重要意义。     

Tumor vascular permeability factor stimulates endothelial cell growth and angiogenesis.

Vascular permeability factor (VPF) is an Mr 40-kD protein that has been purified from the conditioned medium of guinea pig line 10 tumor cells grown in vitro, and increases fluid permeability from blood vessels when injected intradermally. Addition of VPF to cultures of vascular endothelial cells in vitro unexpectedly stimulated cellular proliferation. VPF promoted the growth of new blood vessels when administered into healing rabbit bone grafts or rat corneas. The identity of the growth factor activity with VPF was established in four ways: (a) the molecular weight of the activity in preparative SDS-PAGE was the same as VPF (Mr approximately 40 kD); (b) multiple isoforms (pI greater than or equal to 8) for both VPF and the growth-promoting activity were observed; (c) a single, unique NH2-terminal amino acid sequence was obtained; (d) both growth factor and permeability-enhancing activities were immunoadsorbed using antipeptide IgG that recognized the amino terminus of VPF. Furthermore, 125I-VPF was shown to bind specifically and with high affinity to endothelial cells in vitro and could be chemically cross-linked to a high-molecular weight cell surface receptor, thus demonstrating a mechanism whereby VPF can interact directly with endothelial cells. Unlike other endothelial cell growth factors, VPF did not stimulate [3H]thymidine incorporation or promote growth of other cell types including mouse 3T3 fibroblasts or bovine smooth muscle cells. VPF, therefore, appears to be unique in its ability to specifically promote increased vascular permeability, endothelial cell growth, and angio-genesis.     

Soluble vascular endothelial growth factor in various blood transfusion components

BACKGROUND: Blood transfusion may reduce survival after curative surgery for solid tumors. This may be related to extracellular content of cancer growth factors present in transfusion components. Vascular endothelial growth factor (VEGF) is a potent stimulator of angiogenesis in solid tumors. The potential content of VEGF in various blood components for transfusion was evaluated. STUDY DESIGN AND METHODS: Soluble VEGF (sVEGF, isotype 165) was determined by an enzyme-linked immunosorbent assay (EIA) in serum and plasma samples and in lysed cells from healthy volunteers. Subsequently, total content of sVEGF was determined in nonfiltered and prestorage white cell-reduced whole blood (WB), buffy coat-depleted saline-adenine-glucose-mannitol (SAGM) blood, platelet-rich plasma (PRP), and buffy coat-derived platelet (BCP) pools obtained from volunteer, healthy blood donors. As a control, total content of platelet-derived soluble plasminogen activator inhibitor type 1 (sPAI-1) was determined by an EIA in the same samples. Finally, the extracellular accumulation of sVEGF was determined in nonfiltered WB and SAGM blood during storage for 35 days and in BCP pools during storage for 7 days. RESULTS: In the healthy volunteers, median total sVEGF content was 97 (range, 20-303) pg per mL in serum and 19 (13-37) pg per mL in plasma (n = 12, p < 0.002) and 445 (280-990) pg per mL in lysed cells. Median total sPAI-1 content was 94 (64-127) ng per mL in serum, 8 (6-11) ng per mL in citrated plasma, and 95 (78-123) ng per mL in lysed cells. In SAGM blood, the median total sVEGF content was 25.3 (3.3-48.4) ng per unit in nonfiltered units and undetectable in white cell-reduced units. Median total sVEGF content was 29.2 (24.8-124.9) ng per unit in nonfiltered PRP and 28.7 (24.5-118.6) ng per unit in white cell-reduced PRP. The sVEGF accumulated significantly in WB, SAGM blood, and BCP pools, depending on the storage time. CONCLUSION: The sVEGF (isotype 165) appears to be present in various blood transfusion components, depending on storage time.     

血管内皮生长因子及其受体在胃肠间质瘤中的表达

1983年Mazur[1]首次提出胃肠道间质瘤(gastrointestinalstromal tumors,GISTs)的诊断以后,作为一种独立的消化道疾病一直是研究热点。GIST可发生自食管至肛门的胃肠道全长范围,瘤细胞显示CD117及CD34有较高的阳性表达率[2,3]。血管内皮生长因子(VEGF)及其受体(VEGFR-2)被认为是     

Expression of the vascular permeability factor/vascular endothelial growth factor gene in central nervous system neoplasms.

Expression of the vascular permeability factor/vascular endothelial growth factor (VEGPF) gene was investigated in human central nervous system (CNS) neoplasms and normal brain. Adsorption of capillary permeability activity from human glioblastoma multiforme (GBM) cell conditioned medium and GBM cyst fluids by anti-VEGPF antibodies demonstrated that VEGPF is secreted by GBM cells and is present in sufficient quantities in vivo to induce vascular permeability. Cloning and sequencing of polymerase chain reaction-amplified GBM and normal brain cDNA demonstrated three forms of the VEGPF coding region (567, 495, and 363 nucleotides), corresponding to mature polypeptides of 189, 165, and 121 amino acids, respectively. VEGPF mRNA levels in CNS tumors vs. normal brain were investigated by the RNase protection assay. Significant elevation of VEGPF gene expression was observed in 81% (22/27) of the highly vascular and edema-associated CNS neoplasms (6/8 GBM, 8/8 capillary hemangioblastomas, 6/7 meningiomas, and 2/4 cerebral metastases). In contrast, only 13% (2/15) of those CNS tumors that are not commonly associated with significant neovascularity or cerebral edema (2/10 pituitary adenomas and 0/5 nonastrocytic gliomas) had significantly increased levels of VEGPF mRNA. The relative abundance of the forms of VEGPF mRNA was consistent in tumor and normal brain: VEGPF495 > VEGPF363 > VEGPF567. In situ hybridization confirmed the presence of VEGPF mRNA in tumor cells and its increased abundance in capillary hemangioblastomas. Our results suggest a significant role for VEGPF in the development of CNS tumor neovascularity and peritumoral edema.     

Vascular permeability factor/vascular endothelial growth factor induces lymphangiogenesis as well as angiogenesis

Vascular permeability factor/vascular endothelial growth factor (VPF/VEGF, VEGF-A) is a multifunctional cytokine with important roles in pathological angiogenesis. Using an adenoviral vector engineered to express murine VEGF-A(164), we previously investigated the steps and mechanisms by which this cytokine induced the formation of new blood vessels in adult immunodeficient mice and demonstrated that the newly formed blood vessels closely resembled those found in VEGF-A-expressing tumors. We now report that, in addition to inducing angiogenesis, VEGF-A(164) also induces a strong lymphangiogenic response. This finding was unanticipated because lymphangiogenesis has been thought to be mediated by other members of the VPF/VEGF family, namely, VEGF-C and VEGF-D. The new "giant" lymphatics generated by VEGF-A(164) were structurally and functionally abnormal: greatly enlarged with incompetent valves, sluggish flow, and delayed lymph clearance. They closely resembled the large lymphatics found in lymphangiomas/lymphatic malformations, perhaps implicating VEGF-A in the pathogenesis of these lesions. Whereas the angiogenic response was maintained only as long as VEGF-A was expressed, giant lymphatics, once formed, became VEGF-A independent and persisted indefinitely, long after VEGF-A expression ceased. These findings raise the possibility that similar, abnormal lymphatics develop in other pathologies in which VEGF-A is overexpressed, e.g., malignant tumors and chronic inflammation.     

血管内皮细胞生长因子和碱性成纤维细胞生长因子体外联合诱导外周血单个核细胞定向分化为血管内皮细胞

目的:在体外培养的条件下,应用血管内皮细胞生长因子和碱性成纤维细胞生长因子联合诱导人外周血单个核细胞向血管内皮细胞分化,解决组织工程血管化的种子细胞来源问题。方法:实验于2005-11/2006-05在安徽省立医院中心实验室完成。①血管内皮细胞生长因子(Pepro Tech公司,批号090310);碱性成纤维细胞生长因子(Pepro Tech公司,批号0704CY081);人淋巴细胞分离液Ficoll-paque(天津灏洋生物制品科技有限公司);PE标记的CD31,鼠抗人vWF单克隆抗体(BD Biosciences公司);FITC标记的兔抗鼠IgG(北京中杉金桥公司)。②无菌条件下取健康人外周血20mL,肝素抗凝,Hanks液双倍稀释,按1∶2置于淋巴细胞分离液上层,离心后提取分液层与上层交界部位呈混浊的灰白色层,即为单个核细胞层。③取离心后的细胞,向DMEM-F12培养基中分别加入含体积分数为0.2的胎牛血清、10μg/L血管内皮细胞生长因子、10μg/L碱性成纤维细胞生长因子。以不含血管内皮细胞生长因子和碱性成纤维细胞生长因子诱导剂的DMEM-F12培养基作为空白对照。吹打均匀并计数,按1×1010L-1接种于25cm2培养瓶中,于37℃、体积分数为0.05的CO2饱和湿度培养箱中培养,第3天更换培养基,去除未贴壁的细胞,以后每2d换液1次。④倒置相差显微镜下观察细胞单层排列是否呈"铺路石"样结构。运用流式细胞术检测诱导后的细胞表达CD31和vWF情况。透射电镜观察细胞的超微结构。结果:①诱导分化后细胞形态学变化:经血管内皮细胞生长因子和碱性成纤维细胞生长因子诱导后的细胞形态上呈典型的"铺路石"样外观,经历从小圆→梭形→扁平细胞的过程,符合内皮细胞的演变过程。②诱导分化后细胞的表面标志鉴定:诱导分化20d,贴壁细胞中62.5%表达CD31,58.2%表达vWF,54.3%表达CD31/vWF。③培养细胞的超微结构观察:透射电镜下细胞胞浆内可见特征性W-P小体。结论:外周血单个核细胞在血管内皮细胞生长因子和碱性成纤维细胞生长因子体外联合诱导下,可分化为血管内皮细胞。     

Determination of vascular endothelial growth factor (VEGF) in circulating blood: significance of VEGF in various leucocytes and platelets

Aim : The sources of increased vascular endothelial growth factor (VEGF) concentrations in peripheral blood from cancer patients are not known in detail. The aim of the present study was to evaluate correlations between the VEGF content in isolated leucocyte subpopulations and VEGF concentrations in plasma, serum and lysed whole blood. Methods : In 51 colorectal cancer (CRC) patients, circulating T-lymphocytes, B-lymphocytes, monocytes, and granulocytes were isolated by means of immunomagnetic separation. Subsequently, the isolated cells were lysed and VEGF contents in the lysates were determined. In corresponding blood samples, automated complete blood count was performed, and the number of each cell type was correlated to VEGF concentrations in plasma, serum and lysed whole blood. Finally, the impact of increasing clotting time on the release of VEGF to serum was analysed. Results : Isolated neutrophils contained considerable amounts of VEGF. In isolated lymphocytes and monocytes, VEGF was not present in measurable amounts. The number of neutrophils was significantly (p<0.0001) correlated to VEGF concentrations in lysed whole blood, but not to VEGF concentrations in plasma or serum. The number of platelets was significantly correlated to VEGF concentrations in serum and lysed whole blood (p= 0.002 and p= 0.02, respectively) but not to VEGF concentrations in plasma. Finally, in serum, VEGF concentrations increased with increasing clotting time. However, a plateau was reached between 2 and 6 h of in vitro clotting. Conclusion : Circulating neutrophils contain considerable amounts of VEGF that contribute to high VEGF levels in lysed whole blood. VEGF in circulating platelets contributes to high VEGF levels in serum and lysed whole blood. Allowing whole blood samples to clot for between 2 and 6 h before serum is collected reduces time-dependent, non-uniform release of VEGF.     

Determination of vascular endothelial growth factor (VEGF) in circulating blood: significance of VEGF in various leucocytes and platelets

AIM: The sources of increased vascular endothelial growth factor (VEGF) concentrations in peripheral blood from cancer patients are not known in detail. The aim of the present study was to evaluate correlations between the VEGF content in isolated leucocyte subpopulations and VEGF concentrations in plasma, serum and lysed whole blood. METHODS: In 51 colorectal cancer (CRC) patients, circulating T-lymphocytes, B-lymphocytes, monocytes, and granulocytes were isolated by means of immunomagnetic separation. Subsequently, the isolated cells were lysed and VEGF contents in the lysates were determined. In corresponding blood samples, automated complete blood count was performed, and the number of each cell type was correlated to VEGF concentrations in plasma, serum and lysed whole blood. Finally, the impact of increasing clotting time on the release of VEGF to serum was analysed. RESULTS: Isolated neutrophils contained considerable amounts of VEGF. In isolated lymphocytes and monocytes, VEGF was not present in measurable amounts. The number of neutrophils was significantly (p<0.0001) correlated to VEGF concentrations in lysed whole blood, but not to VEGF concentrations in plasma or serum. The number of platelets was significantly correlated to VEGF concentrations in serum and lysed whole blood (p=0.002 and p=0.02, respectively) but not to VEGF concentrations in plasma. Finally, in serum, VEGF concentrations increased with increasing clotting time. However, a plateau was reached between 2 and 6 h of in vitro clotting. CONCLUSION: Circulating neutrophils contain considerable amounts of VEGF that contribute to high VEGF levels in lysed whole blood. VEGF in circulating platelets contributes to high VEGF levels in serum and lysed whole blood. Allowing whole blood samples to clot for between 2 and 6 h before serum is collected reduces time-dependent, non-uniform release of VEGF.     

血管内皮生长因子及血管内皮生长因子受体-2在肾脏疾病中的研究新进展

血管内皮生长因子(VEGF)是一种内皮细胞的特殊生长因子,可以促进内皮细胞的增生、分化和生存,还可以提高血管的通透性,促进血管的形成。血管内皮生长因子受体-2(VEGFR-2),是VEGF的特异性受体,VEGF/VEGFR-2信号系统的激活是刺激血管内皮细胞的主要机制。本文首先对VEGF及VEGFR进行概述,其次介绍VEGF/VEGFR-2肾脏的旁分泌和自分泌机制。最后,对VEGF/VEGFR-2在各种肾脏疾病中的表达及其作用以及靶向VEGF/VEGFR-2信号通路对新药的研发和临床应用进行综述。     

Role of vascular endothelial growth factor receptor 1 and vascular endothelial growth factor receptor 2 in the vasodilator response to vascular endothelial growth factor in the neonatal piglet lung

OBJECTIVE: Vascular endothelial growth factor (VEGF) regulates vascular proliferation and causes vasodilation. In the pulmonary circulation, the vasorelaxing effect of VEGF has been attributed to nitric oxide, whereas in other vascular beds, prostacyclin and other mechanisms are also involved. This vascular effect follows binding to two receptors, VEGF receptor 1 (VEGFR1) and VEGF receptor 2 (VEGFR2), the latter of which is thought to be the main receptor responsible for the vasorelaxing effect of VEGF. The role of VEGFR1 in the neonatal pulmonary vasculature remains to be determined. DESIGN: Prospective randomized laboratory investigation. SETTING: Animal laboratory. SUBJECTS: Newborn Yorkshire-Landrace piglets. INTERVENTIONS: To determine the mechanisms of action of VEGF in the neonatal pulmonary vasculature, the effect of VEGF (10-10 M) was tested in isolated perfused piglet lungs, alone and in the presence of a VEGFR2 kinase inhibitor, N-nitro-l-arginine (L-NNA), indomethacin (Indo), L-NNA + Indo, and GF109203X, a protein kinase C inhibitor. The effect of a VEGFR1 agonist, placenta growth factor (PlGF), was also studied with or without L-NNA. Perfusate was collected, and cyclic guanosine monophosphate (cGMP), as well as 6-keto prostaglandin F1alpha and thromboxane B2, the stable metabolites of prostacyclin and thromboxane, respectively, was measured. MEASUREMENTS AND MAIN RESULTS: VEGF caused vasorelaxation with a concomitant increase in cGMP. PlGF also decreased vascular tone and increased cGMP. VEGFR2 kinase inhibitor did not prevent the reduction in perfusion pressure seen with VEGF but blocked the increase in cGMP. Pretreatment with L-NNA completely inhibited VEGF and PlGF vasodilation and prevented the increase in cGMP seen with both agonists. Pretreatment with Indo or GF109203X did not reduce the dilator response to VEGF. CONCLUSIONS: VEGF vasodilation may follow nitric oxide release in the piglet pulmonary circulation. VEGF vasorelaxation may not only occur through binding to VEGFR2, since PlGF, the specific VEGFR1 agonist, also causes vasodilation. Therefore, vasodilator response to VEGF may involve both types of receptor in the neonatal piglet pulmonary vasculature.     

Insulin suppresses plasma concentration of vascular endothelial growth factor and matrix metalloproteinase-9

OBJECTIVE: We recently demonstrated a potent anti-inflammatory and thus a potential antiatherogenic effect of insulin in human aortic endothelial cells and mononuclear cells at physiologically relevant concentrations. We have now further investigated the anti-inflammatory suppressive action of insulin on vascular endothelial growth factor (VEGF) and matrix metalloproteinase (MMP)-9. VEGF and MMP-9 play a central regulatory role in angiogenesis, contribute to the pathogenesis of proliferative retinopathy, and have also been found to accelerate atherosclerosis. RESEARCH DESIGN AND METHODS: Insulin was infused (2 IU/h) in 5% dextrose (100 ml/h) and KCl (8 mmol/h) into 10 fasting, obese, nondiabetic subjects for 4 h. Subjects were also infused with 5% dextrose without insulin and with saline on two separate occasions. Blood samples were obtained at 0, 2, 4, and 6 h. RESULTS: Plasma insulin concentrations increased from a basal level of 12.5 +/- 2.2 to 28.2 +/- 3.3 micro U/ml at 2 h and 24.4 +/- 3.7 micro U/ml at 4 h after insulin infusion. VEGF concentration decreased from 307.2 +/- 163.8 pg/ml (100%) at 0 h to 73.5 +/- 20.9% of the basal level at 2 h and 67.1 +/- 23.2% at 4h. Plasma MMP-9 concentrations decreased from 375 +/- 196.3 ng/ml (100%) at 0 h to 83 +/- 22% of the basal level at 2 h and to 82 +/- 21% of the basal level at 4 h (P < 0.05). Dextrose infusion alone did not change plasma VEGF concentration. However, plasma MMP-9 concentration increased significantly at 4 h following dextrose infusion alone (P < 0.05). Saline infusions without insulin caused no alteration in glucose, insulin, VEGF, or MMP-9. CONCLUSIONS: These observations may have implications for a potential antiretinopathic and antiatherosclerotic effect of insulin in the long term.