巢蛋白在P19神经元分化过程中的表达

小鼠巢蛋白（ｎｅｓｔｉｎ）基因编码了一个中等纤维骨架蛋白,该基因在小鼠中枢神经系统发育过程中的瞬时性表达,为了推测该基因的神经发育过程中可能的功能,我们分析了该基因在ＲＡ诱导的Ｐ１９胚胎性癌细胞体外神经分化过程中的表达规律,结果显示,在上述过程中,巢蛋白基因的表达早于神经前体细胞（ｎｅｕｒａｌｐｒｅｃｕｓｏｒｃｅｌｌ）中表达的ＢＭＰ４,以及在成熟神经元特异表达的标分子神经线（ＮＦ１６０）,表明巢蛋     

小鼠巢蛋白基因结构及其转录调控元件的初步鉴定

通过筛选小鼠基因组ＢＡＣ文库,得到小鼠巢蛋白基因组２３．３ｋｂ ＤＮＡ序列,其中约１５．３ｋｂ已完成测序。与小鼠ｃＤＮＡ序列比较结果表明,小鼠巢蛋白基因包含３个内含子。与大鼠及人巢蛋白基因相比,小鼠巢蛋白基因中３个内含子的位置及大小均很保守。利用神经发育的体外实验模型,检测小鼠巢蛋白基因第２个内含子对荧光素酶报告基因的调控活性。系列缺失质粒转染细胞显示,小鼠巢蛋白基因第２个内含子对报告基因的转录具     

巢蛋白基因沉默通过激活细胞周期依赖性激酶（cdk5）促进大鼠神经胶质瘤细胞C6的迁移和增殖

中间纤维蛋白巢蛋白(nestin)在各种胚胎前体细胞及成熟组织中均有表达.近年一些研究显示,巢蛋白的表达上调和一些恶性肿瘤的病理特征有相关性.但是,巢蛋白在干细胞分化及肿瘤发生中的作用还不为人知.在本研究中,我们运用短发卡状的RNA为工具,以大鼠神经胶质瘤细胞系C6为模型,对巢蛋白的功能进行了研究.划痕实验和迁移实验的结果均显示,巢蛋白基因沉默可以促进C6细胞的迁移.同时,BrdU渗入实验显示,此过程伴随着细胞增殖的增加.进一步研究显示,细胞周期依赖性激酶cdk5的活性在此过程中有显著的增加.此外,巢蛋白基因沉默所引起的迁移改变可以被cdk5特异性抑制剂roscovitine所回复, 而对细胞增殖则没有显著影响.综上所述,本研究揭示了巢蛋白基因沉默与神经胶质瘤细胞的迁移和增殖相关,而cdk5是此过程的重要调节因子.     

化学方法体外诱导大鼠骨髓间充质干细胞成神经样细胞分化

目的:研究化学方法体外诱导大鼠骨髓间充质干细胞向神经样细胞的可持续性分化。方法:体外培养大鼠骨髓间充质干细胞至P5代,流式细胞术检测细胞表面标志物,将细胞分为丁羟茴醚(BHA)诱导组、β巯基乙醇(BME)诱导组和对照组,分别进行化学诱导分化,通过荧光定量PCR、Western印迹和免疫细胞化学法分别检测巢蛋白、神经元特异性烯醇化酶(NSE)、胶质原纤维酸性蛋白(GFAP)等神经细胞标志分子的表达情况。结果:BHA诱导组高表达GFAP,而BME诱导组高表达巢蛋白,2组NSE表达均较弱;同时在诱导结束后继续培养的过程中,2组神经标志分子表达量持续降低。结论:2种方法都能诱导骨髓间充质干细胞向神经样细胞分化,但分化结局不同,BHA诱导分化后细胞主要表达星形胶质细胞表面标志GFAP,而BME诱导分化后细胞主要表达神经前体细胞表面标志巢蛋白;此外,通过化学方法诱导分化的效果是不可持续的,在诱导结束后继续培养的过程中神经标志分子表达逐渐下调。     

兔抗人NESTIN抗血清的制备与鉴定(简报)

巢蛋白(nestin)属Ⅵ类中等纤维蛋白。最初在神经系统发育早期发现有该蛋白的表达。后在正常神经系统中发现仅在未分化的神经前体细胞中有nestin的短暂表达,分化后在神经元和神经胶质细胞中分别被NF(neurofilament,神经丝)和GFAP(Glial fibrillary acidic protein,神经胶质元纤维酸性蛋白)所代替。所以nestin的表达通常被视为神经前体细胞的标志之一。就我们所知,目前商品化nestin的抗体都是鼠抗鼠(克隆Rat401)的抗体,而人鼠之间该蛋白序列的同源性仅为50%左     

山羊胚胎大脑皮层神经干细胞分离、培养与鉴定

目的 :从山羊胚胎大脑皮层中分离培养并鉴定神经干细胞。方法 :利用NBS培养和单细胞克隆技术在山羊胚胎大脑皮层中分离出具有单细胞克隆能力的细胞 ,并进行培养、传代、分化观察 ,采用免疫组化检测克隆细胞的神经巢蛋白 (Nestin)抗原和分化后特异性成熟神经细胞抗原的表达。结果 :从胚龄 2 4～ 30d的新鲜山羊胚胎大脑皮层中成功分离出神经干细胞 ,该细胞具有连续克隆能力 ,可传代培养 ,表达神经巢蛋白抗原。分化后的细胞表达神经元细胞、胶质细胞和少突胶质细胞的特异性抗原。结论 :山羊胚胎大脑皮层中存在具有自我更新能力和多分化潜能的神经干细胞。     

LincRNA1230抑制小鼠胚胎干细胞向神经前体细胞分化

胚胎干细胞是一类具有多向分化潜能的细胞.胚胎干细胞可以模拟体内发育过程,在无外界信号分子刺激的情况下,自发向神经前体细胞分化.有研究表明,这一体外发育过程受神经分化相关转录因子和表观遗传修饰的共同调控,然而该过程中的分子机制尚不清楚.本研究发现长链非编码RNA1230(LincRNA1230)参与了小鼠(Mus musculus)胚胎干细胞向神经前体细胞的分化过程.在小鼠的胚胎干细胞中过表达LincRNA1230可以显著抑制其神经分化效率;反之,干扰LincRNA1230可以提高分化效率.进一步研究表明,LincRNA1230通过结合Wdr5,降低神经分化相关基因启动子区H3K4me3的修饰水平,从而抑制相关基因的表达活性.这些发现揭示了LincRNA1230在小鼠胚胎干细胞神经分化过程中的重要作用.     

Adam10基因在成年小鼠中枢神经系统的表达模式研究

目的研究adam10基因在成年小鼠中枢神经系统表达的脑区分布特点以及细胞类型。方法构建小鼠源性adam10 cRNA探针,通过原位杂交技术,观察adam10 mRNA在成年小鼠中枢神经系统分布特点,并在原位杂交后进行免疫组织化学染色,把adam10原位杂交信号和神经元、星形胶质细胞特异性细胞标记物进行双标,观察adam10基因表达的细胞类型。结果 Adam10基因在成年小鼠大脑皮层、海马、丘脑和小脑中表达,原位杂交后进行免疫组织化学染色结果显示adam10原位杂交阳性信号主要和神经元标记物NeuN共标,而和星形胶质细胞标记物GFAP不共标。结论本研究证实了在成年小鼠中枢神经系统中adam10基因在大脑皮层、海马、丘脑和小脑中都有表达;并且首次明确了大脑中ad-am10基因主要在神经元中表达,在星形胶质细胞中不表达,小脑中主要在小脑颗粒细胞和蒲肯野细胞中表达。     

Gsα调控小鼠大脑皮层发育

异源三聚体G蛋白激活alpha亚基(Gsα),是一种普遍存在的鸟苷酸结合蛋白,调节受体介导的胞内cAMP信号通路进而参与调控细胞的生命活动。目前Gsα信号通路的研究主要在生物化学和药物方面,但在小鼠大脑皮层发育中的作用还没有详尽的描述。本研究首先利用cre-loxP系统在小鼠大脑皮层神经前体细胞中成功敲除Gsα基因;其次,通过收集出生后不同天数的正常小鼠和敲除小鼠,统计分析后发现敲除鼠的脑重和体重减轻;最后,对小鼠大脑做切片后染色,发现在小鼠大脑皮层条件性敲除Gsα基因的成年鼠中表达thy1-EGFP(增强绿色荧光蛋白)的神经元的数量减少,皮层形成异常。由此推测,Gsα在小鼠大脑皮层发育中发挥重要作用。     

慢病毒介导Nanog基因在小鼠ES细胞的表达

试验尝试构建小鼠Nanog基因慢病毒表达载体,培养表达外源Nanog基因的小鼠ES细胞。结果显示通过RT-PCR扩增出918bp的小鼠Nanog基因,测序正确的小鼠Nanog基因通过慢病毒介导在小鼠ES细胞表达后,表达外源Nanog基因的小鼠ES细胞生长状态同普通ES细胞无明显差异,在无LIF的ES细胞培养液培养条件下,表达外源Nanog基因的小鼠ES细胞保持正常的ES细胞集落,碱性磷酸酶、Oct4和SSEA-1免疫细胞化学检测为阳性,相同情况下未表达外源Nanog基因的小鼠ES细胞集落退化消失。试验证实了通过慢病毒载体介导培养了表达外源Nanog基因的小鼠ES细胞。试验尝试构建小鼠Nanog基因慢病毒表达载体,培养表达外源Nanog基因的小鼠ES细胞。根据小鼠Nanog基因m RNA序列设计Nanog基因引物,引物两端带有Nhe I和Xho I酶切位点。Trizol试剂处理小鼠ES细胞,通过RT-PCR扩增出小鼠Nanog基因,小鼠Nanog基因用Nhe I和Xho I酶切后连入pcDNA3.1载体中,PCR检测阳性的细菌克隆进行测序,测序正确的Nanog基因片段连接入PLL-IRES-Neo慢病毒表达载体中,包装含有Nanog基因的慢病毒感染小鼠ES细胞,在SNL细胞饲养层上G418筛选2周后,添加普通ES细胞培养液在普通小鼠胎儿成纤维细胞饲养层上培养。结果显示通过RT-PCR扩增出918 bp的小鼠Nanog基因,测序正确的小鼠Nanog基因通过慢病毒介导在小鼠ES细胞表达后,表达外源Nanog基因的小鼠ES细胞生长状态同普通ES细胞无明显差异,在无LIF的ES细胞培养液培养条件下,表达外源Nanog基因的小鼠ES细胞保持正常的ES细胞集落,碱性磷酸酶、Oct4和SSEA-1免疫细胞化学检测为阳性,相同情况下未表达外源Nanog基因的小鼠ES细胞集落退化消失。试验证实了通过慢病毒载体介导培养了表达外源Nanog基因的小鼠ES细胞。     

2-D DIGE as a quantitative tool for investigating the HUPO Brain Proteome Project mouse series

Brain development and aging is a complex process involving proliferation, differentiation and apoptosis. Elucidating proteome changes in these processes can help to understand the mechanisms of brain development and maintenance as well as neurodegenerative diseases. The research reported here is a contribution to the HUPO Brain Proteome Project mouse pilot study. Whole, frozen C57BL/6J mouse brain comprising three different developmental stages (embryonic day 16, postnatal day 7, and postnatal days 54-58) were processed by using 2-D DIGE. A total of 1999 spots were matched between all gels. Of these, 206 spots were differentially expressed between the different stages: 122 spots were highest in intensity in embryonic stage E16, 26 highest in the juvenile group P7 and 58 spots highest in P56, the adult stage. The results show a pattern of temporal expression. Based on the expression patterns we tentatively suggest that proteins involved in the establishment of primary structures in the brain are expressed highest in the embryonic mouse. Proteins involved in the development of the brain are expressed highest in the juvenile phase and proteins that make utilization of the brain possible by delivering energy are expressed highest in the adult mice.     

Identification of a set of genes with developmentally down-regulated expression in the mouse brain.

Using a subtraction cloning approach, we have isolated a set of cDNA clones from mouse neural precursor cells whose respective mRNA levels are down-regulated during the development of mouse brain. Single stranded DNA prepared from neuronal precursor cell cDNA library in lambda Zap vector was subtracted with poly (A)+ RNA prepared from postnatal and adult mouse brain to obtain several clones which show developmental down-regulation of expression. Their patterns of expression indicate that these genes may play important roles during the embryonic development and differentiation of central nervous system.     

Polysialic Acid Synthase (ST8Sia II/STX) mRNA Expression in the Developing Mouse Central Nervous System

Abstract: A comparative study was undertaken to correlate the immunohistochemical localization of polysialic acid (PSA) and the in situ localization of ST8Sia II mRNA. In situ hybridization of postnatal day 3 mouse brain showed high levels of ST8Sia II mRNA expression in the cerebral neocortex, striatum, hippocampus, subiculum, medial habenular nucleus, thalamus, pontine nuclei, and inferior colliculus; intermediate-level expression in the olfactory bulb, hypothalamus, superior colliculus, and cerebellum; and low-level expression in other regions. The distribution of ST8Sia II mRNA in the neocortex and cerebellum coincided with the immunohistochemical localization of PSA. During brain development, ST8Sia II mRNA started decreasing and had almost disappeared by postnatal day 14. Comparison between ST8Sia II and IV mRNA expression was also undertaken by northern blot analysis and competitive PCR analysis. During the late embryonic to early postnatal stages of the mouse CNS, the ST8Sia II mRNA showed abundant mRNA expression compared with the ST8Sia IV mRNA. Competitive PCR analysis of the adult mouse CNS showed weak expression of the two genes in the olfactory bulb, thalamus, hippocampus, and eyes. The regional and transient expression of ST8Sia II mRNA coincides with that of PSA, suggesting that ST8Sia II is closely involved in the biosynthesis and expression of PSA in the developing mouse CNS.     

Expression profile of mouse BWF1, a protein with a BEACH domain, WD40 domain and FYVE domain

We isolated a mouse cDNA encoding a protein that contains a BEACH domain, 5 WD40 repeats and a FYVE domain, which we designated as BWF1. The mRNA is approximately 10 kb in size and encodes a protein consisting of 3508 amino acids with a predicted molecular weight of 385 kDa. BWF1 has 45% homology with the Drosophila protein, blue cheese (BCHS). The BWF1 gene consists of 67 exons, which span 270 kb of genomic sequence, and has been mapped to mouse chromosome 5. Northern blot analysis revealed that it was strongly expressed in the liver, moderately in the kidney and testis, and weakly in the brain of adult mice. During the development of the mouse brain, BWF1 mRNA was abundant on embryonic day (E) 14-16; after birth, the level of BWF1 mRNA expression decreased markedly to reach the adult level at postnatal day 3. In situ hybridization analysis revealed that the expressed BWF1 mRNA was restricted to the marginal region both in E14 and E16 embryonic brain, but became diffuse after birth. Confocal microscopy studies of the epitope-tagged BWF1 protein showed that the protein was a cytoplasmic one.