海带多糖对肾上腺素致内皮细胞超微结构损害的保护作用

目的:观察海带多糖(PL)对肾上腺素(Adr)致内皮细胞超微结构损害的保护作用。方法:体外培养人脐静脉内皮细胞(HUVEC)24h,实验组分为正常组、Adr组、PL组、低剂量PL(L-PL)+Adr组、高剂量PL(H-PL)+Adr组,采用透射电镜技术观察细胞的超微结构。结果:Adr组细胞核形状不规则,核仁固缩;线粒体肿胀,嵴消失、空泡化;L-PL+Adr组细胞核形态明显变形,线粒体嵴稀少、内有空泡;H-PL+Adr组和PL组细胞核及线粒体结构完好。结论:海带多糖能够保护Adr对内皮细胞的细胞核、线粒体超微结构的损害。     

细胞间粘附分子-1在血管内皮细胞冻融损伤中的作用

目的:探讨血管内皮细胞(VEC)表面细胞间粘附分子-1(ICAM-1)在VEC冻融损伤中的作用,以阐明冻融损伤的发病机制。方法:以大鼠主动脉VEC和大鼠外周血嗜中性粒细胞(PMN)为材料,使用WKL-Ⅴ型速率冷冻仪冷冻VEC然后在水浴中复温,制备VEC冻融模型。采用免疫组化法测定VEC冻融后4、12和24 h其表面ICAM-1的表达;将冻融VEC与正常PMN共同孵育后,以rose bengal染色法测定冻融VEC与PMN粘附,测定培养液中LDL活性确定VEC损伤程度。结果:冻融后4 h,VEC表面ICAM-1表达阳性率由冻融前的13.2%±3.6%增加至22.3%±4.4%,冻后12h达高峰(37.9%±2.5%)。冻融VEC与PMN共同孵育后,VEC-PMN粘附由对照组的0.204±0.025增加至0.363±0.022(P<0.01),培养液中LDH活性由对照组的104.64±20.14U/L增加至162.33±27.88U/L(P<0.01);ICAM-1Mab可部分阻断冻融VEC-PMN粘附(0.270±0.021,P<0.01),且使培养液中LDH活性降低至125.39±22.26U/L(P<0.05)。结论:冻融可诱发VEC表面ICAM-1的表达,进而增强VEC-PMN粘附而导致VEC损伤。     

降钙素基因相关肽对血管内膜损伤后内皮细胞功能恢复的影响

在球囊剥脱大鼠主动脉内膜造成的内皮损伤模型上,用ＣＧＲＰ（１０μｇ／ｋｇ／ｄ）治疗后观察血管内皮合成释放ｖＷＦ含量及ｔ－ＰＡ活性的变化。结果表明ＣＧＲＰ能明显降低ｖＷＦ含量和增加ｔ－ＰＡ活性。提示ＣＧＲＰ能减轻内皮损伤反应,在促内皮细胞增殖的同时对内皮某些功能恢复亦有一定的作用     

油酸对培养血管内皮细胞的直接损伤作用

本研究发现:油酸可引起内皮细胞特征性形态变化;内皮细胞与血小板粘附性增强;内皮细胞~(51)Cr释放率、细胞上清液中乳酸脱氢酶(LDH)浓度升高,表明油酸引起细胞通透性升高;培养上清液中6-酮-PGF_(1a)含量升高,提示细胞代谢功能的改变。在一定范围内,上述改变与油酸浓度、作用时间有密切关系。结果还表明,油酸对培养血管内皮细胞有直接损伤作用,推测油酸对内皮细胞的直接损伤,在急性肺损伤早期内皮细胞损伤发病机制中占有重要的地位。     

超氧化物歧化酶对内皮细胞缺氧复氧损伤的防护作用

体外培养扔兔胸主动脉内皮细胞缺氧３０ｍｉｎ后复氧１０ｍｉｎ,可以发现缺氧后复氧可引起细胞乳酸脱氢酶释放量,细胞悬液丙二醛含量增加,谷胱甘肽过氧化酶活性降低,细胞合成释放一氧化氮减少,细胞内钙离子浓度明显升高;ＥＣ的这些损伤在缺氧期间即有表现,复氧后更为加剧。而在缺氧前预先加入终浓度为２００Ｕ／ｍｌ的超氧化物歧化酶可改善细胞的抗氧化能力,减轻缺氧复氧对ＥＣ的损伤。     

oxLDL对血管内皮细胞的损伤机制

天然的低密度脂蛋白(LDL)经氧化修饰形成氧化低密度脂蛋白(oxLDL).天然LDL核心的脂肪酸中含有大量不饱和脂肪酸,约占LDL总脂肪酸含量的35-70%,所以容易发生自身氧化.oxLDL具有一系列生物学毒性作用,氧化修饰后的LDL不能经LDL受体代谢,由清道夫受体识别、结合、内吞饮入细胞并逃逸正常的胆固醇代谢途径,引起细胞内脂质沉积,泡沫样变.oxLDL引发动脉粥样硬化的机制之一就是损伤血管内皮细胞,因此细胞损伤机制的进一步阐明将为改善内皮细胞功能和治疗动脉粥样硬化提供新的思路.     

新型血管内皮细胞抑制因子VEGI_(151)的基因克隆表达及其活性

血管内皮细胞生长抑制因子 (vascularendothelialcellgrowthinhibitor,VEGI)是近年发现的一类肿瘤坏死因子超家族成员 ,具有抑制内皮细胞增殖的作用。从人脐静脉内皮细胞株 (ECV30 4)克隆到其基因 ,构建N端缺失 2 3个氨基酸的表达载体 ,并通过原核表达系统进行表达 (命名为VEGI151) ,表达量为 2 5 .5 % ,纯化后纯度达92 .5 %。通过生物学效应检测 ,发现VEGI151可明显抑制无血清培养基中内皮细胞的增殖 ,2 4h时VEGI151对内皮细胞的IC50 为 10mg/L ,0 .6 13mg/L时使内皮细胞在 36h内完全凋亡。通过检测体外培养肿瘤细胞 (A5 49、HepG2、Hela等 )的存活率 ,未发现明显的增殖或抑制效应。提示VEGI是一种主要作用于血管内皮细胞 ,在新生血管性疾病及肿瘤的治疗中有潜在的应用前景。     

脓毒症致肺血管内皮细胞损伤机制的研究进展

ICU病房中,急性肺损伤(Acute lung injury,ALI)是脓毒症常见并发症并有较高发病率和死亡率.研究表明肺血管内皮细胞是脓毒症致ALI的重要靶细胞和效应细胞,肺血管内皮细胞功能紊乱和损伤在脓毒症致ALI发生、发展中有重要作用,本文概述脓毒症致肺血管内皮损伤的相关发病机制.     

肌肽对低氧所致大鼠血管内皮细胞损伤的保护作用

目的：研究肌肽对低氧所致大鼠血管内皮细胞损伤的影响。方法：建立低氧条件下大鼠血管内皮细胞损伤模型,用MTT法观察肌肽对低氧损伤的血管内皮细胞活性的影响,测定细胞培养基中LDH活力,并对细胞骨架进行考马斯亮蓝R-250染色观测其细胞结构。结果：浓度为10mmol/L～20mmol/L肌肽孵育血管内皮细胞6h后,可以抑制缺氧12h和24h引起的血管内皮细胞活性下降,同时减少LDH的释放,保持细胞骨架完整。结论：肌肽对低氧所致的血管内皮细胞损伤具有保护作用。     

牡砺糖胺聚糖对血管内皮细胞损伤的保护作用研究

目的：探讨牡蛎糖胺聚糖（O—GAG）对血管内皮细胞损伤的保护作用,观察它对损伤的血管内皮细胞内一氧化氮（NO）、丙二醛（iDA）含量及乳酸脱氢酶（LDH）活性的影响。方法：采用人脐静脉内皮细胞株ECV304体外培养的方法,建立过氧化氢（H2O2）诱导的内皮细胞损伤模型,噻唑蓝（MTT）比色法观察牡蛎糖胺聚糖对血管内皮细胞增殖活性的影响,硝酸还原酶法、硫代巴比妥酸法和硝基苯肼法分别检测细胞内NO的含量、细胞培养液内MDA的含量和LDH的活性。结果：模型组较正常对照组细胞增殖活性明显降低（P〈0．01）。与模型组相比,经牡蛎糖胺聚糖预处理的各保护组（除10μg／ml）细胞增殖活性明显增加（P〈0．05,P〈0．01）,NO的含量增加,MDA的含量和LDH的活性降低（P〈0．01）。牡蛎糖胺聚糖（100、200μg／ml）对于正常的内皮细胞有促增殖作用（P〈0．05）。结论：牡蛎糖胺聚糖对氧化损伤的血管内皮细胞具有保护作用,其作用机制可能与增加细胞NO含量、减少MDA生成和LDH释放有关。牡蛎糖胺聚糖对正常血管内皮细胞在一定剂量范围内有促增殖作用．     

海带内生芽胞杆菌DNN7和HSN2胞外蛋白抗肿瘤活性初步研究

为检测海带内生芽胞杆菌DNN7和HSN2胞外蛋白的抗肿瘤活性,用0.22μm滤膜过滤将海带内生芽胞杆菌DNN7和HSN2的菌体和发酵液分开,用硫酸铵沉淀发酵液的蛋白组分并用SDS-PAGE检测,用海虾毒性法和MTT法检测胞外蛋白的抗肿瘤活性。结果表明,海带内生芽胞杆菌DNN7的粗蛋白主要由分子量约为66×103、52×103和34×103的3条带组成,HSN2的粗蛋白主要由分子量约为44×103和52×103的2条带组成。DNN7胞外蛋白对体外慢性粒细胞白血病癌细胞K562、肝肿瘤细胞HepG2和乳腺癌细胞MDA-MB-231均具有较好的抑制活性,其抑制率分别高达96.46%、42.99%和85.70%;HSN2胞外蛋白对体外慢性粒细胞白血病癌细胞K562、肝肿瘤细胞HepG2和乳腺癌细胞MDA-MB-231也具有较好的抑制活性,其抑制率分别为92.65%、66.80%、88.48%。     

Isolation of endothelial cells from human placental microvessels: effect of different proteolytic enzymes on releasing endothelial cells from villous tissue

Approaches for the isolation of human placental microvascular endothelial cells (HPMEC) using proteolytic enzymes have been described recently. However, the isolation procedure and enzyme composition most suitable for optimal disaggregation of placental tissue and isolation of HPMEC has not yet been established. We tested different proteolytic enzymes and enzyme mixtures for their capabilities of releasing endothelial cells from human term placental villous tissue. Best results were obtained with a mixture of collagenase/dispase/deoxyribonuclease I (0.28%/0.25%/0.01%). By adding a discontinuous Percoll gradient centrifugation step to the enzymatic dispersion, about 1 x 10(6) cells/g tissue with more than 30% von Willebrand factor (vWf)-positive cells were obtained. However, the total cell number and number of vWf-positive cells were highly dependent on the lot of collagenase used. A perfusion step prior to mincing of villous tissue did not increase the amount of vWf-positive cells. We conclude that the methods described in this study are suitable to isolate high yields of HPMEC and that the composition of the collagenase preparation is crucial to the successful release of endothelial cells from placental tissue. To obtain pure HPMEC, further separation steps, e.g., cell sorting with antibodies against endothelial specific cell surface antigens are necessary.     

Coptis japonica Makino extract suppresses angiogenesis through regulation of cell cycle-related proteins

Angiogenesis, neovascularization from pre-existing vessels, is a key step in tumor growth and metastasis, and anti-angiogenic agents that can interfere with these essential steps of cancer development are a promising strategy for human cancer treatment. In this study, we characterized the anti-angiogenic effects of Coptis japonica Makino extract (CJME) and its mechanism of action. CJME significantly inhibited the proliferation, migration, and invasion of vascular endothelial growth factor (VEGF)-stimulated HUVECs. Furthermore, CJME suppressed VEGF-induced tube formation in vitro and VEGF-induced microvessel sprouting ex vivo. According to our study, CJME blocked VEGF-induced cell cycle transition in G1. CJME decreased expression of cell cycle-regulated proteins, including Cyclin D, Cyclin E, Cdk2, and Cdk4 in response to VEGF. Taken together, the results of our study indicate that CJME suppresses VEGF-induced angiogenic events such as proliferation, migration, and tube formation via cell cycle arrest in G1.     

Establishment of a novel corneal endothelial cell line from domestic rabbit, Oryctolagus curiculus

To develop a rabbit corneal endothelial (RCE) cell line, in vitro culture of RCE cells was initiated from Oryctolagus curiculus corneas and a novel RCE cell line was established in this study. To initiate the primary culture of RCE cells, corneas from rabbit eyes were sliced and attached into glutin-coated wells with endothelial cell surface down. After being cultured at a time-gradient interval from 48 to 6 h, the corneal slices were detached and reattached into new wells, respectively. Cells in the wells containing only a pure population of RCE cells were collected and cultured in 20% FBS-DMEM/F12 medium containing chondroitin sulfate, ocular extract, epidermal growth factor (EGF), basic fibroblast growth factor (bFGF), carboxymethyl-chitosan, N-acetylglucosamine hydrochloride, glucosamine hydrochloride,culture medium of rabbit corneal stromal cells and oxidation-degradation products of chondroitin sulfate at 37℃, 5% CO2. The cultured RCE cells, in quadrangle and polygonal shapes, proliferated to confluence 3 weeks later. During the subsequent subculture, the shape of RCE cells changed gradually from polygonal to more fibroblastic. A novel RCE cell line, growing at a steady rate, with a population doubling time of 53.8 h, has been established and subcultured to passage 67. Chromosome analysis showed that the RCE cells exhibited chromosomal aneuploidy with the modal chromosome number of 44. The results of immuno-cytochemical staining with neuron specific enolase (NSE) confirmed that the RCE cells were in neuroectodermal origin. Combined with the results of vascular endothelial growth factor (VEGF) treatment and endothelial cell morphology recovery, it can be concluded that the cell line established here is an RCE cell line. This RCE cell line may serve as a useful tool in theoretical researches of mammalian corneal endothelial cells, and may also have potential application in artificial corneal endothelium development.     

Establishment of a novel corneal endothelial cell line from domestic rabbit, Oryctolagus curiculus

To develop a rabbit corneal endothelial (RCE) cell line, in vitro culture of RCE cells was initiated from Oryctolagus curiculus corneas and a novel RCE cell line was established in this study. To initiate the primary culture of RCE cells, corneas from rabbit eyes were sliced and attached into glutin-coated wells with endothelial cell surface down. After being cultured at a time-gradient interval from 48 to 6 h, the corneal slices were detached and reattached into new wells, respectively. Cells in the wells containing only a pure population of RCE cells were collected and cultured in 20% FBS-DMEM/F12 medium con- taining chondroitin sulfate, ocular extract, epidermal growth factor (EGF), basic fibroblast growth factor (bFGF), carboxymethyl-chitosan, N-acetylglucosamine hydrochloride, glucosamine hydrochloride, culture medium of rabbit corneal stromal cells and oxidation-degradation products of chondroitin sul- fate at 37℃, 5% CO2. The cultured RCE cells, in quadrangle and polygonal shapes, proliferated to con- fluence 3 weeks later. During the subsequent subculture, the shape of RCE cells changed gradually from polygonal to more fibroblastic. A novel RCE cell line, growing at a steady rate, with a population doubling time of 53.8 h, has been established and subcultured to passage 67. Chromosome analysis showed that the RCE cells exhibited chromosomal aneuploidy with the modal chromosome number of 44. The results of immuno-cytochemical staining with neuron specific enolase (NSE) confirmed that the RCE cells were in neuroectodermal origin. Combined with the results of vascular endothelial growth factor (VEGF) treatment and endothelial cell morphology recovery, it can be concluded that the cell line established here is an RCE cell line. This RCE cell line may serve as a useful tool in theoretical re- searches of mammalian corneal endothelial cells, and may also have potential application in artificial corneal endothelium development.     

细胞生长因子对冠状动脉内皮细胞增殖与迁移的影响

目的 :观察肝细胞生长因子 (HGF)和血管内皮细胞生长因子 (VEGF)对体外培养牛冠状动脉内皮细胞(BCAEC)增殖、迁移的影响。方法 :分离和培养BCAEC ,设对照组、VEGF组、HGF组。采用四甲基偶氮唑蓝法(MTT)观察细胞增殖 ;倒置显微镜观察培养的血管内皮细胞的迁移。结果 :对照组、VEGF组、HGF组的OD值分别为 0 .2 2± 0 .0 1、0 .40± 0 .1 4、0 .44± 0 .1 5 ;VEGF组、HGF组BCAEC的增殖率分别为 81 .8%± 1 6 .9%、1 0 0 %±2 1 .1 % ;对照组BCAEC迁移不明显 ,而VEGF组和HGF组BCAEC迁移明显。结论 :VEGF、HGF能促进BCAEC增殖、迁移 ,HGF作用强度不亚于VEGF。     

Hypoxia‐induced endothelial secretion of macrophage migration inhibitory factor and role in endothelial progenitor cell recruitment

Macrophage migration inhibitory factor (MIF) is a pleiotropic inflammatory cytokine that was recently identified as a non‐cognate ligand of the CXC‐family chemokine receptors 2 and 4 (CXCR2 and CXCR4). MIF is expressed and secreted from endothelial cells (ECs) following atherogenic stimulation, exhibits chemokine‐like properties and promotes the recruitment of leucocytes to atherogenic endothelium. CXCR4 expressed on endothelial progenitor cells (EPCs) and EC‐derived CXCL12, the cognate ligand of CXCR4, have been demonstrated to be critical when EPCs are recruited to ischemic tissues. Here we studied whether hypoxic stimulation triggers MIF secretion from ECs and whether the MIF/CXCR4 axis contributes to EPC recruitment. Exposure of human umbilical vein endothelial cells (HUVECs) and human aortic endothelial cells (HAoECs) to 1% hypoxia led to the specific release of substantial amounts of MIF. Hypoxia‐induced MIF release followed a biphasic behaviour. MIF secretion in the first phase peaked at 60 min. and was inhibited by glyburide, indicating that this MIF pool was secreted by a non‐classical mechanism and originated from pre‐formed MIF stores. Early hypoxia‐triggered MIF secretion was not inhibited by cycloheximide and echinomycin, inhibitors of general and hypoxia‐inducible factor (HIF)‐1α‐induced protein synthesis, respectively. A second phase of MIF secretion peaked around 8 hrs and was likely due to HIF‐1α‐induced de novo synthesis of MIF. To functionally investigate the role of hypoxia‐inducible secreted MIF on the recruitment of EPCs, we subjected human AcLDL⁺ KDR⁺ CD31⁺ EPCs to a chemotactic MIF gradient. MIF potently promoted EPC chemotaxis in a dose‐dependent bell‐shaped manner (peak: 10 ng/ml MIF). Importantly, EPC migration was induced by supernatants of hypoxia‐conditioned HUVECs, an effect that was completely abrogated by anti‐MIF‐ or anti‐CXCR4‐antibodies. Thus, hypoxia‐induced MIF secretion from ECs might play an important role in the recruitment and migration of EPCs to hypoxic tissues such as after ischemia‐induced myocardial damage.     

Localized cysteine sulfenic acid formation by vascular endothelial growth factor: role in endothelial cell migration and angiogenesis

Abstract

Reactive oxygen species (ROS) are important mediators for VEGF receptor 2 (VEGFR2) signalling involved in angiogenesis. The initial product of Cys oxidation, cysteine sulfenic acid (Cys-OH), is a key intermediate in redox signal transduction; however, its role in VEGF signalling is unknown. We have previously demonstrated IQGAP1 as a VEGFR2 binding scaffold protein involved in ROS-dependent EC migration and post-ischemic angiogenesis. Using a biotin-labelled Cys-OH trapping reagent, we show that VEGF increases protein-Cys-OH formation at the lamellipodial leading edge where it co-localizes with NADPH oxidase and IQGAP1 in migrating ECs, which is prevented by IQGAP1 siRNA or trapping of Cys-OH with dimedone. VEGF increases IQGAP1-Cys-OH formation, which is prevented by N-acetyl cysteine or dimedone, which inhibits VEGF-induced EC migration and capillary network formation. In vivo, hindlimb ischemia in mice increases Cys-OH formation in small vessels and IQGAP1 in ischemic tissues. In summary, VEGF stimulates localized formation of Cys-OH-IQGAP1 at the leading edge, thereby promoting directional EC migration, which may contribute to post-natal angiogenesis in vivo. Thus, targeting Cys-oxidized proteins at specific compartments may be the potential therapeutic strategy for various angiogenesis-dependent diseases.