大鼠脑微血管内皮细胞的分离与原代培养

为了建立大鼠脑微血管内皮细胞体外培养模型,探索纯度较高的大鼠脑微血管内皮细胞分离和原代培养的方法并进行形态学观察。采用2～3周龄的SD大鼠,解剖得到大脑皮质,两次酶消化及牛血清白蛋白或葡聚糖和Percoll梯度离心获得较纯的脑微血管段后,接种于涂布基质的培养皿进行原代培养;培养的细胞采用相差显微镜形态学观察、透射电镜观察及Ⅷ因子相关抗原免疫组化检测鉴定。结果发现,培养12h即可见细胞从贴壁的脑微血管段周围长出,细胞呈短梭形,区域性单层生长,5～7天内皮细胞融合,内皮细胞纯度达90％以上;内皮细胞的贴壁和生长有赖于所涂布的基质,纤连蛋白／Ⅳ型胶原优于鼠尾胶和明胶;Ⅷ因子相关抗原免疫组化检测内皮细胞表达阳性,透射电镜观察可见相邻内皮细胞间存在紧密连接结构。提示该方法能成功进行纯度较高的大鼠脑微血管内皮细胞原代培养,可用于脑微血管内皮的生理、生化及药理学研究,亦可用于构建大鼠血脑屏障模型。     

血脑屏障上的药物转运体P-糖蛋白

血脑屏障(Blood-brain Barrier,简称BBB)是维护脑内环境稳态的重要功能单位,它不仅可以阻止血液中的有害物质进入脑组织,而且能够清除脑内的有毒代谢产物。BBB上表达的转运系统在积极转运营养物质入脑和选择性外排药物的两个方面均发挥了重要作用。其中P-糖蛋白由于自身结构功能的特异性和作用底物的广泛性而备受关注。本文主要论述了BBB上P-糖蛋白的特性、表达、转运底物及其体内外研究的进展情况。P-糖蛋白作为BBB的重要组成部分在中枢神经系统治疗药物的摄取、分布和排泄中发挥了越来越重要的作用。因此,对P-糖蛋白的研究将有助于阐明药物脑部转运机制,为增加药物的BBB通透性、提高脑内靶点药物浓度提供新的研究思路。     

运用植块法培养脑微血管内皮细胞

探讨简易可行的脑微血管内皮细胞(brain microvascular endothelial cells,BMECs培)养方法,为研究BMECs细胞在脑血管疾病中的重要作用提供技术支持。分离出生后1~7天内的SD乳鼠大脑皮质区,植块法培养BMECs细胞。用倒置显微镜观察BMECs细胞的形态以及从皮质块迁出的过程;MTT比色法检测BMECs细胞的生长曲线;采用免疫组化染色检测VIII因子相关抗原和CD34抗原,以鉴定内皮细胞。结果发现,大脑皮质块植块法培养的大鼠BMECs细胞呈单层贴壁生长,细胞形态以长梭形、多角形三角形、四边形为主,呈典型的“铺路石”样征象,经鉴定为内皮细胞,第三代纯度达95%以上。提示该方法具有经济、简便、要求条件不高,易于纯化的优点,可作为大鼠BMECs细胞体外培养的良好模型。     

培养的大鼠脑微血管内皮细胞生化特性观察

用胶原酶消化、差异离心和尼龙网过滤的方法分离鼠脑微血管内皮细胞,建立其体外长期培养方法。经形态学、免疫组化,酶学鉴定,培养细胞为脑微血管内皮细胞,动态观察培养细胞酶含量变化,发现随着细胞培养时间的延长,血管紧张素转换酶Ⅰ（ACE）呈上升趋势,而γ－谷氨酰胺转化酶（γ-GT）和硷性磷酸酶（ALP）则明显下降,实验结果提示,血脑屏障的主要功能酶γ－GT和ALP可作为体外脑微血管内皮细胞的标志酶,但要维持长时间体外表达则需要某种因子的介导。本实验可为体外研究血脑屏障及相关疾病提供帮助。     

单筛过滤法体外分离培养原代大鼠脑微血管内皮细胞及其鉴定

目的 采用单筛过滤法获取脑微血管以培养纯度高、活性好的原代大鼠脑微血管内皮细胞。方法 取4周龄SD大鼠脑皮质,经剪碎、单层细胞筛网过滤、收集网上截留组织、Ⅱ型胶原酶消化后,置于CO₂培养箱中进行原代培养。通过细胞形态学观察、第Ⅷ因子相关抗原免疫细胞化学染色检测鉴定所培养的目的细胞。结果 体外培养24 h后,短梭形细胞从脑微血管段周围爬出;48 h后“岛屿状”的细胞团簇形成;96 h后细胞融合,呈典型的单层、“铺路石样”、镶嵌式贴壁生长。第Ⅷ因子相关抗原免疫细胞化学染色检测显示细胞胞质呈现棕红色,表达为阳性。结论 单筛过滤法能够成功分离培养出原代大鼠脑微血管内皮细胞。     

CCL2促进大鼠原代心肌微血管内皮细胞血管形成

本文旨在探讨趋化因子CCL2在成年大鼠原代心肌微血管内皮细胞(cardiac microvascular endothelial cell, CMEC)血管形成中的作用。分离原代大鼠CMEC,用CD31和VIII因子免疫染色鉴定,观察不同时间点基质胶(Matrigel)上CMEC血管形成情况,用real-time RT-PCR和ELISA分别检测在血管形成过程中CCL2的表达和分泌情况。结果显示:(1)大鼠原代CMEC分离成功,该细胞具有形成血管能力,成网数和节点数在Matrigel处理后4 h显著增加;(2) CMEC血管形成过程中CCL2和CCR2的表达量显著上调,并且CCL2的分泌量明显增加;(3) CCL2阻断抗体和CCR2拮抗剂均可显著降低CMEC血管形成能力。上述结果提示,大鼠原代CMEC在血管形成过程中可分泌CCL2,并且CCL2-CCR2信号通路促进了CMEC血管形成。     

原代SD大鼠视网膜微血管内皮细胞的培养及鉴定

目的 探讨大鼠视网膜微血管内皮细胞的体外分离培养方法.方法 选取6～8周龄SD大鼠5只,摘取眼球,挤压球壁后,人工剥离视网膜.将大鼠视网膜剪碎,依次经过200μm、75μm不锈钢筛网;收集滤液,离心,弃上清,予0.1％II型胶原酶消化15～20min;再次将消化液通过45μm尼龙筛网,反复冲洗筛网,收集网上物;添加培养...     

鼠脑微血管内皮细胞的分离与长期培养

采用胶原酶消化、差速离心、尼龙网滤过技术分离和获取鼠脑微血管内皮细胞,接种后4h换液使获得的内皮细胞纯化,体外进行长期培养。细胞在体外生长176天,传至30代,细胞初期成活率为92％,纯度近90％。经形态学、超微结构和免疫组化鉴定,培养细胞为血管内皮细胞。培养至第30代的细胞仍能合成和分泌PGI2、ACE等,ⅧF:Ag阳性表达,染色体为二倍体(2n=42),基本保持着细胞的主要特征。该分离和培养方法的建立,将为研究与脑血管相关疾病提供有用工具。     

流动剪切力对鼠脑微血管内皮细胞ICAM—1表达的影响

利用内皮细胞流动小室方法,对大鼠脑微血管内皮细胞的剪切力作用下细胞内粘附分子－1（ICAM－1,intercellular adhesion molecule-1）的表达进行了研究。图像分析结果提示,脑微血管内皮细胞在剪切力作用下ICAM－1的表达呈特异上调,且存在着时间依赖性,与一定范围内的剪切力强度无关,用对细胞施加剪切力作用后提取上清液孵育内皮细胞的方法证明：剪切力对鼠脑微血管内皮细胞ICAM－1表达的影响,是直接作用于内皮细胞引起的细胞内的直接反应,而不是剪切力导致细胞先释放细胞因子,释放的细胞因子再引起ICAM－1变化的间接反应。该工作为进一步开展剪切力对微血管内皮细胞信号转导机制的影响提供了实验数据。     

肺微血管内皮细胞的原代培养

目的:建立简单高效获取大鼠肺微血管内皮细胞(pulmonary microvascular endothelial cells,PMVECs)的培养方法.方法:(1)组织块贴壁法培养大鼠PMVECs;(2)光镜下观察细胞的形态;(3)扫描电镜和透射电镜分别观察细胞表面及内部的结构特征;(4)免疫荧光法鉴定PMVECs.结果:(1)获得的PMVECs长满后呈典型的铺路石或鹅卵石状;(2)扫描电镜下可见内皮细胞表面存在微绒毛等特殊结构;(3)透射电镜观察可见细胞浆内存在韦伯潘力氏小体(Webel Palade body,WPB);(4)免疫组化结果显示细胞浆中有Ⅷ因子相关抗原存在.结论:改良的组织块法培养肺微血管内皮细胞是一种简单、快捷,有效的方法.     

机械力对鼠脑微血管内皮细胞膜电流的影响

采用膜片钳技术以全细胞方式在鼠脑微血管内皮细胞中记录到一延迟外向电流,对Ｋ＾＋具有高度特异性,胞外施加２０ｍｍｏｌ／Ｌ的ＴＥＡ－Ｃｌ在明显抑制该电流。实验的保持电位定在－１００ｍＶ,测试电位从－１００ｍＶ至＋９０ｍＶ,每次增加１０ｍＶ,刺激波宽为２１００ｍｓ。该电流具有ＴＥＡ敏感,并有浓度依赖性,其ＩＣ５０约为２．０ｍｍｏｌ／Ｌ,类似延迟整流性钾电流特征（ＩＫｖ）。机械力作用下可引出一外向电流,膜     

A Novel Brain Neurovascular Unit Model with Neurons,Astrocytes and Microvascular Endothelial Cells of Rat

A novel triple cell neurovascular unit (NVU) model co-culturing with neurons, brain microvascular endothelial cells (BMECs) and astrocytes was established in this study for investigating the cerebral diseases and screening the candidates of therapeutic drug. We have first performed the cell identification and morphological characterization, analyzed the specific protein expression and determined the blood-brain barrier (BBB) function of the co-culture model under normal condition. Then, we further determined the BBB function, inflammation, cell injury and the variation of neuroprotective factor in this model after anoxia-reoxygenation. The results suggest that this model exhibited a better BBB function and significantly increased expression of P-glycoprotein (Pg-P) and ZO-1 compared with BMECs only or co-culture with astrocytes or neurons. After anoxia-reoxygenation, the pathological changes of this model were basically resemblance to the pathological changes of brain cells and BBB in vivo. And nimodipine, an antagonist of calcium, could reverse those changes as well. According to our observations, we deduce that this triple cell co-culture model exhibits the basic structure, function and cell-cell interaction of NVU, which may offer a more proper in vitro system of NVU for the further investigation of cerebral diseases and drug screening.     

Isolation of Primary Murine Brain Microvascular Endothelial Cells

The blood-brain-barrier is ultrastructurally assembled by a monolayer of brain microvascular endothelial cells (BMEC) interconnected by a junctional complex of tight and adherens junctions. Together with other cell-types such as astrocytes or pericytes, they form the neurovascular unit (NVU), which specifically regulates the interchange of fluids, molecules and cells between the peripheral blood and the CNS. Through this complex and dynamic system BMECs are involved in various processes maintaining the homeostasis of the CNS. A dysfunction of the BBB is observed as an essential step in the pathogenesis of many severe CNS diseases. However, specific and targeted therapies are very limited, as the underlying mechanisms are still far from being understood. Animal and in vitro models have been extensively used to gain in-depth understanding of complex physiological and pathophysiological processes. By reduction and simplification it is possible to focus the investigation on the subject of interest and to exclude a variety of confounding factors. However, comparability and transferability are also reduced in model systems, which have to be taken into account for evaluation. The most common animal models are based on mice, among other reasons, mainly due to the constantly increasing possibilities of methodology. In vitro studies of isolated murine BMECs might enable an in-depth analysis of their properties and of the blood-brain-barrier under physiological and pathophysiological conditions. Further insights into the complex mechanisms at the BBB potentially provide the basis for new therapeutic strategies.This protocol describes a method to isolate primary murine microvascular endothelial cells by a sequence of physical and chemical purification steps. Special considerations for purity and cultivation of MBMECs as well as quality control, potential applications and limitations are discussed.     

大肠杆菌yijP侵袭蛋白诱导人脑微血管内皮细胞凋亡

为研究大肠杆菌的脑微血管内皮细胞侵袭基因yijP的功能,将yijP基因（1．04kb）克隆到pQE30表达载体,构建表达产物为N末端带有6个组氨酸（His）序列的yijP汇合蛋白,以M15（pREP4）为受体菌,大量表达（His）6-yijP汇合蛋白,利用Ni—NTA亲和层析纯化汇合蛋白,将经透析法复性的一定浓度的（His）6-yijP蛋白加入到体外培养的人脑微血管内皮细胞中,结果显示yijP蛋白对人脑微血管内皮细胞有较强的细胞毒作用：在相差显微镜下可观察到细胞皱缩、胞膜呈泡状膨出,随着时间延长细胞逐渐脱落;荧光显微镜下可见细胞核呈现为致密团块状或圆形浓染颗粒状,呈凋亡样改变：DNA琼脂糖凝胶电泳可见DNA阶梯状条带;流式细胞仪显示在正常二倍体峰之前出现一个亚二倍体峰;Western印迹可检测到caspase-3的活性片段。这些现象均出现在yijP蛋白作用于人脑微血管内皮细胞的16h之后,提示在大肠杆菌侵袭人脑微血管内皮细胞过程中,yijP蛋白可能起到诱导脑微血管内皮细胞迟发性凋亡的毒素作用。     

Mrp1 Multidrug Resistance-Associated Protein and P-Glycoprotein Expression in Rat Brain Microvessel Endothelial Cells

Abstract: Two membrane glycoproteins acting as energy-dependent efflux pumps, mdr -encoded P-glycoprotein (P-gp) and the more recently described multidrug resistance-associated protein (MRP), are known to confer cellular resistance to many cytotoxic hydrophobic drugs. In the brain, P-gp has been shown to be expressed specifically in the capillary endothelial cells forming the blood-brain barrier, but localization of MRP has not been well characterized yet. Using RT-PCR and immunoblot analysis, we have compared the expression of P-gp and Mrp1 in homogenates, isolated capillaries, primary cultured endothelial cells, and RBE4 immortalized endothelial cells from rat brain. Whereas the mdr1a P-gp-encoding mRNA was specifically detected in brain microvessels and mdr1b mRNA in brain parenchyma, mrp1 mRNA was present both in microvessels and in parenchyma. However, Mrp1 was weakly expressed in microvessels. Mrp1 expression was higher in brain parenchyma, as well as in primary cultured brain endothelial cells and in immortalized RBE4 cells. This Mrp1 overexpression in cultured brain endothelial cells was less pronounced when the cells were cocultured with astrocytes. A low Mrp activity could be demonstrated in the endothelial cell primary monocultures, because the intracellular [³H]vincristine accumulation was increased by several MRP modulators. No Mrp activity was found in the cocultures or in the RBE4 cells. We suggest that in rat brain, Mrp1, unlike P-gp, is not predominantly expressed in the blood-brain barrier endothelial cells and that Mrp1 and the mdr1b P-gp isoform may be present in other cerebral cells.     

Stretch in Brain Microvascular Endothelial Cells (cEND) as an In Vitro Traumatic Brain Injury Model of the Blood Brain Barrier

Due to the high mortality incident brought about by traumatic brain injury (TBI), methods that would enable one to better understand the underlying mechanisms involved in it are useful for treatment. There are both in vivo and in vitro methods available for this purpose. In vivo models can mimic actual head injury as it occurs during TBI. However, in vivo techniques may not be exploited for studies at the cell physiology level. Hence, in vitro methods are more advantageous for this purpose since they provide easier access to the cells and the extracellular environment for manipulation.Our protocol presents an in vitro model of TBI using stretch injury in brain microvascular endothelial cells. It utilizes pressure applied to the cells cultured in flexible-bottomed wells. The pressure applied may easily be controlled and can produce injury that ranges from low to severe. The murine brain microvascular endothelial cells (cEND) generated in our laboratory is a well-suited model for the blood brain barrier (BBB) thus providing an advantage to other systems that employ a similar technique. In addition, due to the simplicity of the method, experimental set-ups are easily duplicated. Thus, this model can be used in studying the cellular and molecular mechanisms involved in TBI at the BBB.     

内质网应激条件下血管内皮细胞生长因子在人脑微血管内皮细胞中的表达

为观察内质网应激条件下血管内皮细胞生长因子的表达情况,用不同浓度的衣霉素处理体外培养的人脑微血管内皮细胞,建立内质网应激模型,采用RT—PCR、蛋白质免疫印迹以及免疫细胞化学的方法检测了细胞内血管内皮细胞生长因子的表达。结果发现血管内皮细胞生长因子在人脑微血管内皮细胞中存在一定的表达;内质网应激可诱导血管内皮细胞生长因子表达升高,随着衣霉素浓度的增高,血管内皮细胞生长因子的表达逐渐增加,与mRNA水平相比,血管内皮细胞生长因子蛋白量的增加更明显。实验结果提示人脑微血管内皮细胞中存在血管内皮细胞生长因子自分泌,血管内皮细胞生长因子可能是内质网应激的靶基因。     

Pericytes from Brain Microvessels Strengthen the Barrier Integrity in Primary Cultures of Rat Brain Endothelial Cells

(1) The blood–brain barrier (BBB) characteristics of cerebral endothelial cells are induced by organ-specific local signals. Brain endothelial cells lose their phenotype in cultures without cross-talk with neighboring cells. (2) In contrast to astrocytes, pericytes, another neighboring cell of endothelial cells in brain capillaries, are rarely used in BBB co-culture systems. (3) Seven different types of BBB models, mono-culture, double and triple co-cultures, were constructed from primary rat brain endothelial cells, astrocytes and pericytes on culture inserts. The barrier integrity of the models were compared by measurement of transendothelial electrical resistance and permeability for the small molecular weight marker fluorescein. (4) We could confirm that brain endothelial monolayers in mono-culture do not form tight barrier. Pericytes induced higher electrical resistance and lower permeability for fluorescein than type I astrocytes in co-culture conditions. In triple co-culture models the tightest barrier was observed when endothelial cells and pericytes were positioned on the two sides of the porous filter membrane of the inserts and astrocytes at the bottom of the culture dish. (5) For the first time a rat primary culture based syngeneic triple co-culture BBB model has been constructed using brain pericytes beside brain endothelial cells and astrocytes. This model, mimicking closely the anatomical position of the cells at the BBB in vivo, was superior to the other BBB models tested. (6) The influence of pericytes on the BBB properties of brain endothelial cells may be as important as that of astrocytes and could be exploited in the construction of better BBB models.