小胶质细胞的培养及鉴定

目的:获得高纯度培养原代小胶质细胞的方法并检测Notch信号通路相关分子在小胶质细胞的表达情况。方法:取胎鼠利用反复机械振摇纯化分离小胶质细胞;利用流式细胞仪,根据CD11b及MHCII的表达水平对分离的小胶质细胞纯度进行鉴定;利用qPCR及琼脂糖凝胶电泳检测小胶质细胞中Notch通路相关分子的表达情况。结果:利用5只胎鼠采取反复机械振摇的方法可较稳定的获得1.1×106个的小胶质细胞,流式细胞术结果显示细胞纯度高达97.77%,并在小胶质细胞中检测到Notch相关分子的表达。结论:利用胎鼠反复机械振摇法可以获得较高纯度及产量的小胶质细胞,小胶质细胞表达Notch信号通路。     

小胶质细胞的培养及鉴定

目的：获得高纯度培养原代小胶质细胞的方法并检测Notch信号通路相关分子在小胶质细胞的表达情况。方法：取胎鼠利用反复机械振摇纯化分离小胶质细胞;利用流式细胞仪,根据CDllb及MHCII的表达水平对分离的小胶质细胞纯度进行鉴定：利用qPCR及琼脂糖凝胶电泳检测小胶质细胞中Notch通路相关分子的表达情况。结果：利用5只胎鼠采取反复机械振摇的方法可较稳定的获得1．1x10‘个的小胶质细胞,流式细胞术结果显示细胞纯度高达97．77％,并在小胶质细胞中检测到Notch相关分子的表达。结论：利用胎鼠反复机械振摇法可以获得较高纯度及产量的小胶质细胞,小胶质细胞表达Notch信号通路。     

原代培养星形胶质细胞和小胶质细胞的特性与鉴定

本研究旨在明确原代培养的星形胶质细胞和小胶质细胞不同代次的生长特性,优化高效获取状态一致细胞的技术方法。将新生乳鼠的脑组织进行原代分离培养胶质细胞,通过细胞增殖检测试剂盒（cell counting kit-8,CCK-8）测定混合胶质细胞增殖曲线,使用流式细胞术检测两类细胞比例,并通过免疫荧光染色鉴定两类胶质细胞分型情况。生长曲线显示P0和P1代混合胶质细胞增殖活力最好;通过170 r/min机械振摇30 min可获得97.3%的高纯度小胶质细胞,该纯化方法得到的P0、P1、P2代离子钙接头蛋白-1（ionized calcium-binding adapter molecule 1,Iba-1）阳性小胶质细胞的形态及其M1、M2表型比例无代次差别;通过星形胶质细胞表面抗原-2（astrocyte cell surface antigen-2,ACSA-2）磁珠抗体分选的方法可获得纯度达到95.7%的星形胶质细胞,该纯化方法得到的P0、P1、P2代胶质纤维酸性蛋白（glial fibrillary acidic protein,GFAP）阳性星形胶质细胞的形态及其A1、A2表型比例无代次差别。本研究详述了原代分离培养的小胶质细胞和星形胶质细胞的生长特点,证明了获取两类胶质细胞的最佳代次,优化了获取两类胶质细胞的技术方法,验证了连续培养两代不会影响其功能表型。本结果为研究神经系统炎症相关疾病的分子机制提供了技术支撑。     

小胶质细胞纯化分离培养方法的改良

目的改良现有的小胶质细胞纯化分离培养方法,建立稳定简便的培养模型。方法利用盐酸利多卡因注射液代替机械振摇纯化分离小胶质细胞;利用CD11b/c(OX42)免疫细胞化学的方法对分离的小胶质细胞纯度进行鉴定,同时观察小胶质细胞形态及活化指标NFкBp65的表达情况;利用流式细胞仪,结合细胞计数及MTT细胞活力测定检测纯化分离后小胶质的增殖情况。结果改良的方法可稳定的获得1.2×106个/培养瓶(75cm2,250ml)的小胶质细胞,纯度达到98%,存活率≥95%,形态上以阿米巴样为主,继续培养3-5d,约半数细胞可转变为静止状态。NFкBp65免疫细胞化学染色为胞浆表达。流式细胞仪检测结合细胞计数及MTT细胞活力检测结果显示,体外纯化培养的小胶质细胞多位于G0/G1期,培养过程中未出现明显的增殖。结论改良的方法易于操作,产量多,纯度高。为体外小胶质细胞进一步研究提供了基础。     

小鼠大脑皮质星形胶质细胞原代培养与鉴定

为探讨简便、高效的大脑皮质星形胶质细胞体外培养方法,本研究取新生24 h内的ICR小鼠大脑皮层,采用物理方法将其分成约1 mm^3,震荡过滤后进行培养。通过拍照的方式记录原代培养1 d、3 d、7 d、14 d、21 d、28 d、35 d和原代培养14 d后再传代培养14 d(记为P2-14 d)细胞形态;通过实时定量PCR和Western blotting比较原代培养1周、2周、3周、4周、5周和原代培养2周后再传代培养2周(即P2-2)的星形胶质细胞内胶质纤维酸性蛋白(glial fibrillary acidic protein,GFAP)基因和蛋白水平变化。选取GFAP、S100-β和谷氨酸转运蛋白(excitatory amino acid transporter 1,EAAT1)标记星形胶质细胞,微管相关蛋白(microtubuleassociated protein 2,MAP-2)、离子钙接头蛋白-1(ionized calcium-binding adapter molecule 1,Iba-1)和髓鞘相关糖蛋白(myelin associated glycoprotein,MAG)抗体分别标记神经元、小胶质细胞和少突胶质细胞。通过免疫荧光染色鉴定细胞种类及纯度。研究结果显示细胞生长良好,原代培养4周星形胶质细胞内GFAP比2周、3周、5周和传代培养2周的细胞更加稳定。经免疫荧光鉴定,星形胶质细胞纯度在95%以上。本实验采用相对较简单经济的方法培养出高纯度且生理状态相对较稳定的原代星形胶质细胞,该细胞模型不仅可以用于星形胶质细胞生理功能研究,还可以用于中枢神经系统相关疾病的体外研究。     

SD大鼠星形胶质细胞来源外泌体的提取及鉴定

对原代培养的SD大鼠星形胶质细胞分泌的外泌体进行提取并鉴定.首先原代培养大鼠星形胶质细胞,免疫荧光鉴定星形胶质细胞标记性蛋白(胶质纤维酸性蛋白:glial fibrillary acidic protein,GFAP)以鉴定星形胶质细胞的纯度,然后采用超速离心法对大鼠原代星形胶质细胞培养上清液中的外泌体进行分离和提取;...     

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...     

新生大鼠雪旺细胞原代培养方法改良

对常用的阿糖胞苷处理及差速贴壁法进行大鼠雪旺细胞原代培养及纯化的方法进行改进。先用阿糖胞苷处理杀死大部分的成纤维细胞,再用抗-Thy-1.1抗体和兔补体处理去除残余成纤维细胞,获得纯化的雪旺细胞。此外,我们对抗-Thy-1.1抗体和兔补体的浓度、处理时间等都进行了改进,避免了由于雪旺细胞状态不好而引起的大量雪旺细胞死亡。此方法能够将雪旺细胞的纯度由90%提高到99%。     

树鼩原代小胶质细胞的分离培养、纯化与鉴定

本文旨在建立树鼩(Tupaia belangeri)小胶质细胞原代培养及纯化的方法,为利用新型实验动物树鼩进行相关研究工作提供实验材料。将新生树鼩大脑皮质机械分离,皮质组织块用胰蛋白酶消化后制成细胞悬液;培养9～10 d后,分别采用直立手拍法、温和胰酶消化法以及恒温振荡法分离纯化树鼩小胶质细胞,通过差速贴壁进一步纯化。荧光显微镜下,利用小胶质细胞的特异性标记物CD11b抗体进行鉴定。结果显示,小胶质细胞分离培养第3天时呈静息状态,表现为梭形、杆状、分支状等不规则形态。细胞免疫荧光CD11b呈阳性。不同纯化方法细胞免疫荧光并计数显示,直立手拍法所获得的细胞产量明显高于恒温振荡法(P 0.05),细胞阳性率( 96%)明显高于温和胰酶消化法( 90%,P 0.05)。直立手拍法可获得产量及纯度高的树鼩原代小胶质细胞。     

老年大鼠脊髓小胶质细胞分选新方法及功能特征观察*

目的: 建立分离纯化老年大鼠小胶质细胞的改良方法,并初步观察老年大鼠脊髓小胶质细胞的生物学特性。方法: 以年轻SD大鼠(2月龄)为对照组,采用胰酶、胰酶替代物和机械网搓法等不同的制备方法,制备大鼠小胶质细胞的单细胞悬液,通过检测细胞纯度、存活率,观察细胞形态特征,分析细胞的炎性功能特征等,确定老年大鼠(20月龄)小胶质细胞的分离纯化方法,观察老年大鼠脊髓小胶质细胞功能特征。结果: 胰酶消化所得细胞的存活率低(年轻大鼠83%,老年大鼠60%);机械网搓法虽得到的存活率较高(95%),但是细胞获取率最低(年轻大鼠((0.207±0.020)×10⁶,老年大鼠(0.243±0.023)×10⁶);采用胰酶替代物解离、密度梯度离心方法分选出的老年大鼠脊髓小胶质细胞数量多、活性好、存活率高,细胞纯度可达85%以上,我们采用此方法分选纯化不同年龄大鼠脊髓小胶质细胞,与年轻大鼠相比,老年鼠脊髓组织量大,所需消化液多,但消化时间缩短;与年轻大鼠小胶质细胞相比,老年大鼠脊髓小胶质细胞其胞体较大较圆,突起少且粗短,形态上偏向于激活状态,老年大鼠小胶质细胞促炎因子IL-1β表达降低(P＜0.05),而抗炎因子IL-10(P＜0.01)表达升高。结论: 成功建立胰酶替代物解离结合密度梯度离心法从大鼠脊髓组织中分离纯化小胶质细胞,老年大鼠脊髓内小胶质细胞整体表现出抗炎表型。     

大鼠视网膜色素上皮细胞分离的改良及其MMP表达

目的探索和优化大鼠视网膜色素上皮(RPE)细胞分离培养的方法,评价RPE细胞的存活状态及细胞基质金属蛋白酶(MMP)的表达,为相关眼底疾病的研究提供细胞来源。方法采用改良的三步酶消化法分离大鼠RPE细胞,并进行细胞体外培养。倒置显微镜观察细胞形态,细胞生长曲线评价不同培养代数的RPE细胞的增殖活力。免疫荧光检测CRALBP和角蛋白表达鉴定RPE细胞,并观察不同培养代数RPE细胞中多种基质金属蛋白酶的表达。结果分离培养的RPE细胞可呈梭形、六角形,并维持RPE细胞特征性蛋白CRALBP和角蛋白表达,但细胞内色素成分随着细胞分裂和传代次数的增多逐渐减少。基质金属蛋白酶MMP2、MMP3、MMP9和MMP10在第1代和第3代RPE细胞中均表达阳性,且表达强度未见明显改变。结论应用改良的三步酶消化法可以成功的分离培养大鼠RPE细胞,并在第1代和第3代RPE细胞维持基质金属蛋白酶MMP2、MMP3、MMP9和MMP10的阳性表达。体外培养的大鼠RPE细胞为研究视网膜相关疾病提供了细胞模型。     

原代小鼠肝脏细胞的高效分离纯化与培养

目的：建立一种能稳定获得高活力和高纯度原代小鼠肝脏细胞的分离、纯化及培养方法。方法：应用改良的Seglen 二步法原位灌注和机械离心分离肝脏细胞,并用改良的高糖DMEM培养基进行培养。台盼蓝拒染法检测接种时肝脏细胞的存活率,倒置显微镜动态观察肝脏细胞形态变化,应用免疫荧光技术对肝脏细胞进行Albumin 染色。结果：每只小鼠可获取肝脏细胞的总产量平均为1.35× 10^6 / g体重,肝脏细胞存活率＞ 90%。倒置显微镜下观察贴壁前肝细胞直径为35.14 滋m± 4.35 滋m,肝脏细胞在接种后3 h基本完成贴壁;肝脏细胞接种后24h,所有肝脏细胞均强阳性表达成熟肝脏细胞标志物Albumin,肝细胞纯度＞ 95%。结论：改良的分离纯化及培养方法能稳定获得高产量、高活率及高纯度的小鼠肝脏细胞。     

体外共培养模式下神经干细胞对视网膜小胶质细胞生物学功能的影响

目的:通过构建体外共培养体系,探讨神经干细胞(NSCs)对脂多糖(LPS)活化后的视网膜小胶质细胞(RMG)生物学功能的影响及TIMP1/MMP9途径在其中的可能作用。方法:采用振荡分离法获取C57/BL6小鼠原代RMG,通过免疫荧光技术检测细胞Iba1的表达对其进行鉴定。采用含有LPS的培养基(终浓度为1μg·mL~(-1))刺激RMG 24h后,将其分为LPS对照组、NSCs组、TB-NSCs组,其中NSCs组将RMG与NSCs共培养24 h,TB-NSCs组将RMG与用中和性抗体封闭TIMP1的NSCs共培养24h;同时,未予以LPS刺激的RMG作为空白对照组。采用免疫荧光技术检测各组RMG的Ki67表达情况,观察其增殖能力;TUNEL技术检测各组RMG凋亡情况;ELISA方法检测各组RMG上清液中TNF-α、IL~(-1)β的蛋白质量浓度。结果:采用振荡分离法获取的原代RMG经免疫荧光染色鉴定Iba1呈阳性。NSCs组Ki67阳性率较LPS对照组降低(P0.05),而TB-NSCs组Ki67阳性率较NSCs组升高(P0.05)。NSCs组TUNEL阳性率较LPS对照组明显升高(P0.05),而TB-NSCs组TUNEL阳性率与NSCs组间差异无统计学意义(P0.05)。空白对照组、LPS对照组、NSCs组、TB-NSCs组RMG上清液中TNF-α蛋白质量浓度分别为(2.10±0.65)、(25.69±2.01)、(20.01±1.63)、(23.76±1.45)ng·mL~(-1),总体比较差异显著(FTNF-α=302.65,PTNF-α0.05);IL~(-1)β蛋白质量浓度分别为(1.77±0.74)、(15.38±1.18)、(10.88±0.95)、(13.45±1.41)ng·mL~(-1),总体比较差异非常显著(FIL~(-1)β=179.84,PIL~(-1)β0.05);其中,NSCs组TNF-α及IL~(-1)β蛋白质量浓度均较LPS对照组显著降低(P0.05),TB-NSCs组TNF-α及IL~(-1)β蛋白质量浓度较NSCs组明显升高(P0.05)。结论:体外共培养模式下,NSCs可抑制RMG增殖能力,提高其凋亡水平,并抑制其分泌促炎因子TNF-α及IL~(-1)β,该效应可能与调控TIMP1/MMP9相关。     

Primary Microglia Isolation from Mixed Glial Cell Cultures of Neonatal Rat Brain Tissue

Microglia account for approximately 12% of the total cellular population in the mammalian brain. While neurons and astrocytes are considered the major cell types of the nervous system, microglia play a significant role in normal brain physiology by monitoring tissue for debris and pathogens and maintaining homeostasis in the parenchyma via phagocytic activity ^1,2. Microglia are activated during a number of injury and disease conditions, including neurodegenerative disease, traumatic brain injury, and nervous system infection ³. Under these activating conditions, microglia increase their phagocytic activity, undergo morpohological and proliferative change, and actively secrete reactive oxygen and nitrogen species, pro-inflammatory chemokines and cytokines, often activating a paracrine or autocrine loop ^4-6. As these microglial responses contribute to disease pathogenesis in neurological conditions, research focused on microglia is warranted.Due to the cellular heterogeneity of the brain, it is technically difficult to obtain sufficient microglial sample material with high purity during in vivo experiments. Current research on the neuroprotective and neurotoxic functions of microglia require a routine technical method to consistently generate pure and healthy microglia with sufficient yield for study. We present, in text and video, a protocol to isolate pure primary microglia from mixed glia cultures for a variety of downstream applications. Briefly, this technique utilizes dissociated brain tissue from neonatal rat pups to produce mixed glial cell cultures. After the mixed glial cultures reach confluency, primary microglia are mechanically isolated from the culture by a brief duration of shaking. The microglia are then plated at high purity for experimental study.The principle and protocol of this methodology have been described in the literature ^7,8. Additionally, alternate methodologies to isolate primary microglia are well described ^9-12. Homogenized brain tissue may be separated by density gradient centrifugation to yield primary microglia ¹². However, the centrifugation is of moderate length (45 min) and may cause cellular damage and activation, as well as, cause enriched microglia and other cellular populations. Another protocol has been utilized to isolate primary microglia in a variety of organisms by prolonged (16 hr) shaking while in culture ^9-11. After shaking, the media supernatant is centrifuged to isolate microglia. This longer two-step isolation method may also perturb microglial function and activation. We chiefly utilize the following microglia isolation protocol in our laboratory for a number of reasons: (1) primary microglia simulate in vivo biology more faithfully than immortalized rodent microglia cell lines, (2) nominal mechanical disruption minimizes potential cellular dysfunction or activation, and (3) sufficient yield can be obtained without passage of the mixed glial cell cultures.It is important to note that this protocol uses brain tissue from neonatal rat pups to isolate microglia and that using older rats to isolate microglia can significantly impact the yield, activation status, and functional properties of isolated microglia. There is evidence that aging is linked with microglia dysfunction, increased neuroinflammation and neurodegenerative pathologies, so previous studies have used ex vivo adult microglia to better understand the role of microglia in neurodegenerative diseases where aging is important parameter. However, ex vivo microglia cannot be kept in culture for prolonged periods of time. Therefore, while this protocol extends the life of primary microglia in culture, it should be noted that the microglia behave differently from adult microglia and in vitro studies should be carefully considered when translated to an in vivo setting.     

Purification and Properties of Calmodulin-Lysine N-Methyltransferase from Rat Brain Cytosol

A S-adenosylmethionine:protein-lysine N-methyltransferase (EC 2.1.1.43) has been purified from rat brain cytosol 7,080-fold with a yield of 8%, using octopus calmodulin as a substrate. It contains a lysine residue that is not fully methylated. The enzyme was purified by ammonium sulfate fractionation, Sephacryl S-200 gel filtration, and phosphocellulose and octopus calmodulin-Sepharose affinity chromatographies. Among protein substrates, it was highly specific toward octupus calmodulin. The Km values for octopus calmodulin and S-adenosyl-L-methionine were found to be 2.2 X 10(-8) M and 0.8 X 10(-6) M, respectively. The molecular weight was estimated to be 57,000 by gel filtration and the pH optimum was between 7.5 and 8.5. The enzyme was stimulated in the presence of 10(-7) M Mn2+ and 10(-4) M Ca2+. HPLC of the acid hydrolysate of methyl-3H-labeled calmodulin showed the formation of epsilon-N-mono, epsilon-N-di, and epsilon-N-trimethyllysine. Reverse-phase HPLC of tryptic peptides of the methyl-3H-labeled calmodulin demonstrated that the labeled N-methyllysine lies in the 107-126 peptide. These findings suggest that this enzyme methylated a specific lysine residue of octopus calmodulin.     

成年SD大鼠心肌原代成纤维细胞分离及培养的优化方案

目的:摸索及优选成年SD大鼠心肌原代成纤维细胞的体外分离、培养及鉴定的实验方法。方法:将成年SD大鼠心脏剪成小组织块,采用以下四种方案(A:0.08%胰酶+0.1%胶原酶II消化15 min,B:0.2%胶原酶II消化15 min,C:0.2%胶原酶II消化60min,D:0.2%胶原酶II消化90 min)提取成年大鼠心脏原代成纤维细胞,再通过差速贴壁分离方法培养原代成纤维细胞。采用倒置显微镜观察成纤维细胞的基本形态特征,并进行Vimentiin免疫荧光染色对培养的原代细胞进行荧光鉴定;采用台盼兰染色对培养的原代成纤维细胞存活率进行鉴定;采用细胞计数对培养的成纤维细胞生长趋势进行鉴定。结果:四种方法均能培养成纤维细胞,但单酶消化60 min可一次性提取较多细胞,并且细胞状态佳,3 d即可传代。72 h成纤维细胞Vimentin免疫荧光染色阳性率高达97%。台盼兰染色可见其细胞死亡率明显降低,并且细胞计数可见细胞生长状态极佳。结论:单酶消化60 min是提取成年SD大鼠心肌原代成纤维细胞的高效、快速、稳定的实验方法,为心脏疾病的基础及临床研究提供了较为理想的细胞学实验模型。     

Purification, Properties, and Phosphorylation by Protein Kinase C of Two Phosphoinositidase C Isozymes from Rat Brain

Two forms of phosphoinositidase C have been purified from the soluble fraction of rat brain. The purification scheme included gel filtration followed by chromatography on cellulose phosphate, phenyl-Sepharose, and Mono Q. Gradient sodium dodecyl sulphate-polyacrylamide gel electrophoresis gave apparent molecular masses of 151 kDa and 147 kDa. Western blotting with monoclonal antibodies showed that the isozymes corresponded to PLC-beta-1 and PLC-gamma of bovine brain. With both enzymes phosphatidylinositol 4,5-bisphosphate was a better substrate than phosphatidylinositol at neutral pH and low calcium ion concentrations. Both enzymes produced a proportion of inositol 1:2-cyclic phosphates from each substrate, particularly at acid pH. Some GTPase activity was seen in the early stages of purification, but was separated from PLC-beta-1 and PLC-gamma on Mono Q. Purified rat brain protein kinase C phosphorylated PLC-gamma but not PLC-beta-1. Incubation with the kinase increased the activity of both enzymes however, possibly by phosphorylation of another protein in the preparations.     

大鼠表皮细胞的体外培养及纯化方法

根据表皮细胞和成纤维细胞对胰蛋白酶敏感性、贴壁时间及要求不同的,采用胰蛋白酶消化法和反复贴壁法相结合,能有效清除成纤维细胞的混合生长,获得纯化的表皮细胞。本方法经济、简便、实用。