神经干细胞迁移的研究进展

神经干细胞的定向迁移是胚胎神经系统发育的先决条件,同时在成体组织的许多生理、病理过程中也起着重要作用;研究发现,许多神经退行性疾病都与神经干细胞迁移的缺陷相关。近年来,越来越多的证据表明,无论是内源性的还是移植的神经干细胞都有向大脑损伤部位迁移的特性,显示出神经干细胞用于神经再生及损伤修复治疗的潜能。该文着重在神经干细胞的基本特性以及神经干细胞定向迁移的细胞与分子机制研究等方面进行了综述。     

脑内皮细胞与神经干细胞共培养促进神经干细胞的迁移

近些年来,人们发现神经发生和血管发生间有着密切的联系,并逐渐开始关注内皮细胞对神经干细胞（NSCs）的影响。人们发现内皮细胞对NSCs的自我更新、分化、迁移有着重要的调节作用,而NSCs对内皮细胞也有促血管形成的作用。有研究报道,内皮细胞具有分泌VEGF、BDNF、SDF-1等因子的功能,内皮细胞是否通过其分泌的因子对NSCs的迁移进行调节,     

神经干细胞研究介绍

神经干细胞研究是近年脑科学研究的热点，本文综述了神经干细胞的分离培养方法、脑内迁移路线、发育分化的影响因素以及可能的应用前景。     

神经干细胞的分化影响其对肝细胞生长因子的趋化性迁移

神经干细胞（neural stem cells,NSCs）的定向迁移对神经系统发育和损伤后修复至关重要,但NSCs的定向迁移与NSCs的分化之间的关系鲜有研究。该研究以此为切入点,以肝细胞生长因子（hepatocyte growth factor,HGF）为趋化因子,神经干细胞系C17．2为研究对象,首先,建立了不同分化阶段的NSCs（分别分化0,12,24,72h）的分化模型;其次,运用Boyden chamber和Dunn chamber研究了不同分化状态下的NSCs对HGF的趋化性迁移。Boyden chamber结果显示：下室加入HGF后,分化12,24h的NSCs迁移至膜下方的细胞数目显著高于分化0,72h的NSCs;Dunn chamber结果显示：分化12,24h的NSCs迁移效率显著高于分化0,72h的NSCs。这些结果表明,NSCs的分化影响其对HGF的趋化性迁移,为在临床上更有效地利用NSCs治疗各种神经系统退行性疾病提供了理论依据。     

大鼠纹状体内移植神经干细胞的迁移分化行为

本文分离培养胎鼠脑室下带区(SVZ)神经干细胞,经含绿色荧光蛋白基因(GFP)的2型重组腺相关病毒感染,获得具有GFP标记的神经干细胞。标记后的细胞移植到成年SD大鼠纹状体内。分别在移植后45天、90天、120天时,取移植大鼠全脑进行矢状连续冰冻切片观察。结果显示,在各时间段,移植位点始终能检测到标记细胞,但有相当数量的细胞远离移植位点向周围迁移。移植后45天,细胞迁移出现明显的方向性、迁移细胞成链式排列。移植后120天,明显观察到两条迁移路线:一条沿弧形路线向背后侧迁移到达胼胝体下缘;另一条向腹后侧迁移到达黑质,并有细胞绕过或穿过黑质到达大脑底端。免疫组织化学分析显示,迁移细胞呈现β-tubulinⅢ阳性。     

黑色素母细胞沿神经的迁移

黑色素细胞是皮肤中的特殊细胞,它产生黑色素,并将其传递给周围的角质形成细胞,从而决定皮肤的颜色等,其来源于黑色素母细胞.因此,了解黑色素母细胞如何迁移至靶点,对改善个体肤色以及诊断和治疗黑色素瘤等都具有重要意义.文章通过对黑色素母细胞沿神经迁移这一模式的过程和相关机制进行综述,希望为个体肤色改善以及黑色素瘤术后复发机制...     

神经营养因子与神经干细胞

生长因子在神经干细胞的增殖,分化和存活过程中有重要作用。神经营养因子是其中的一类,它包括神经生长因子（NGF）家族,胶质源性神经营养因子（GDNF）家族和其它神经营养因子。NGF家族包括NGF,BDNF,NT－3,NT－4／5和NT－6。这一家族可促进epidermic growth facter(EGF)反应 海马及前脑室管膜下区神经干细胞的存活和分化。GDNF家族包括GDNF,NTN,PSP和ART。GDNF家族促神经发育的作用主要在外周,它促进肠神经嵴前体细胞的存活和增殖,且对外周感觉神经的发育至关重要。其它生长因子如bFGF和EGF,它们能促进神经干细胞增殖和存活;CNTF和LIF等在神经干细胞的分化中也有重要作用。     

大鼠胚胎神经干细胞纹状体内移植后特性

观察大鼠胚胎神经干细胞移植入成年大鼠纹状体后的存活、迁移和分化状况。自14天胎鼠脑室下区分离获得神经干细胞,利用无血清培养基培养扩增并进行鉴定。经4～5代的扩增后,以BrdU标记的神经干细胞通过脑立体定位注射移植入成年大鼠纹状体内,然后分别于移植后2周、4周、6周和8周时做脑冰冻切片,通过免疫组织化学和免疫荧光方法检测移植细胞的数量、定位和分化情况。8周后移植细胞的检出率约16%;移植细胞向周围宿主组织有广泛的迁移表现,尤以沿着白质束向头尾方向的迁移最为显著,最远向后侧达到内囊;纹状体中移植细胞主要分化为神经元和星形胶质细胞。星形胶质细胞数量最多,主要位于移植区与宿主组织临界部位,而神经元处于移植区中央。培养的大鼠胚胎神经干细胞可以作为移植替代治疗神经退行性疾病研究的供体细胞源,而移植中的迁移现象值得注意。     

神经干细胞脑内移植后的存活、迁移和分化

从胚胎或成体大鼠脑组织、人胚脑组织均能分离到神经干细胞 ,将它们进行体外原代培养扩增或永生化后植入脑内 ,均能观察到其在脑内的迁移和分化现象。其分化能力主要取决于移植部位的脑内微环境 ,但这种影响作用是相对的。同时 ,体外培养环境如培养时间和细胞融合程度、维甲酸类诱导分化剂处理、NGF转导处理再移植或与嗜铬细胞 (分泌NGF)共移植等 ,也能决定神经干细胞脑内移植后向神经元方向分化的能力。神经干细胞移植为中枢神经系统功能重建和神经再生带来新的希望。     

神经干细胞研究进展

神经干细胞研究是当今生命科学研究的热点之一。神经干细胞是神经系统发育过程中保留下来的具有自我更新和多分化潜能的原始细胞。随着对神经干细胞认识的不断深入,其临床应用前景与价值得到了越来越多研究者的肯定。从神经干细胞的生物学特征、来源、培养鉴定、分化及应用等几个方面对目前的研究做一概述。     

神经干细胞研究进展

神经干细胞(neural stem cells, NSCs)是中枢神经系统中保持分裂和分化潜能的细胞,对它的研究和应用已成为近年来脑科学研究的一个重要领域.神经干细胞体外培养技术的建立提供了对其进行研究的有力手段.目前的研究主要集中于神经干细胞在脑中的起源、分布及在中枢神经系统疾病治疗中的应用等方面.     

The Effects of Co-Culture of Embryonic Stem Cells with Neural Stem Cells on Differentiation

Researching the technology for in vitro differentiation of embryonic stem cells (ESCs) into neural lineages is very important in developmental biology, regenerative medicine, and cell therapy. Thus, studies on in vitro differentiation of ESCs into neural lineages by co-culture are expected to improve our understanding of this process. A co-culture system has long been used to study interactions between cell populations, improve culture efficiency, and establish synthetic interactions between populations. In this study, we investigated the effect of a co-culture of ESCs with neural stem cells (NSCs) in two-dimensional (2D) or three-dimensional (3D) culture conditions. Furthermore, we examined the effect of an NSC-derived conditioned medium (CM) on ESC differentiation. OG2-ESCs lost the specific morphology of colonies and Oct4-GFP when co-cultured with NSC. Additionally, real-time PCR analysis showed that ESCs co-cultured with NSCs expressed higher levels of ectoderm markers Pax6 and Sox1 under both co-culture conditions. However, the differentiation efficiency of CM was lower than that of the non-conditioned medium. Collectively, our results show that co-culture with NSCs promotes the differentiation of ESCs into the ectoderm.     

BRCA-1 基因与神经干细胞

乳腺癌易感基因(Breast cancer susceptibility gene,Brca-1)是肿瘤抑制基因家族中的一员,它是乳腺癌特异性抑癌基因,1994年Miki等[1]采用定位克隆方法首次将Brca-1分离出来。Brca-1能防止细胞过快地或失去控制地生长和分化,在调节细胞进程、DNA损伤修复、细胞生长与凋亡及转录活化和抑制等多种生物学途径都发挥重要作用,Korhonen等2003年报道Brca-1基因可促进体外培养的大鼠来源的神经干细胞的增殖。     

Human Mesenchymal Stem Cells Signals Regulate Neural Stem Cell Fate

Neural stem cells (NSCs) differentiate into neurons, astrocytes and oligodendrocytes depending on their location within the central nervous system (CNS). The cellular and molecular cues mediating end-stage cell fate choices are not completely understood. The retention of multipotent NSCs in the adult CNS raises the possibility that selective recruitment of their progeny to specific lineages may facilitate repair in a spectrum of neuropathological conditions. Previous studies suggest that adult human bone marrow derived mesenchymal stem cells (hMSCs) improve functional outcome after a wide range of CNS insults, probably through their trophic influence. In the context of such trophic activity, here we demonstrate that hMSCs in culture provide humoral signals that selectively promote the genesis of neurons and oligodendrocytes from NSCs. Cell–cell contacts were less effective and the proportion of hMSCs that could be induced to express neural characteristics was very small. We propose that the selective promotion of neuronal and oligodendroglial fates in neural stem cell progeny is responsible for the ability of MSCs to enhance recovery after a wide range of CNS injuries. Special issue dedicated to Anthony Campagnoni.     

Cell Lineage and Regional Identity of Cultured Spinal Cord Neural Stem Cells and Comparison to Brain-Derived Neural Stem Cells

Neural stem cells (NSCs) can be isolated from different regions of the central nervous system. There has been controversy whether regional differences amongst stem and progenitor cells are cell intrinsic and whether these differences are maintained during expansion in culture. The identification of inherent regional differences has important implications for the use of these cells in neural repair. Here, we compared NSCs derived from the spinal cord and embryonic cortex. We found that while cultured cortical and spinal cord derived NSCs respond similarly to mitogens and are equally neuronogenic, they retain and maintain through multiple passages gene expression patterns indicative of the region from which they were isolated (e.g Emx2 and HoxD10). Further microarray analysis identified 229 genes that were differentially expressed between cortical and spinal cord derived neurospheres, including many Hox genes, Nuclear receptors, Irx3, Pace4, Lhx2, Emx2 and Ntrk2. NSCs in the cortex express LeX. However, in the embryonic spinal cord there are two lineally related populations of NSCs: one that expresses LeX and one that does not. The LeX negative population contains few markers of regional identity but is able to generate LeX expressing NSCs that express markers of regional identity. LeX positive cells do not give rise to LeX-negative NSCs. These results demonstrate that while both embryonic cortical and spinal cord NSCs have similar self-renewal properties and multipotency, they retain aspects of regional identity, even when passaged long-term in vitro. Furthermore, there is a population of a LeX negative NSC that is present in neurospheres derived from the embryonic spinal cord but not the cortex.     

Immunohistochemical Detection of Neural Stem Cells and Glioblastoma Stem Cells in the Subventricular Zone of Glioblastoma Patients

Glioblastoma usually recurs after therapy consisting of surgery, radiotherapy, and chemotherapy. Recurrence is at least partly caused by glioblastoma stem cells (GSCs) that are maintained in intratumoral hypoxic peri-arteriolar microenvironments, or niches, in a slowly dividing state that renders GSCs resistant to radiotherapy and chemotherapy. Because the subventricular zone (SVZ) is a major niche for neural stem cells (NSCs) in the brain, we investigated whether GSCs are present in the SVZ at distance from the glioblastoma tumor. We characterized the SVZ of brains of seven glioblastoma patients using fluorescence immunohistochemistry and image analysis. NSCs were identified by CD133 and SOX2 but not CD9 expression, whereas GSCs were positive for all three biomarkers. NSCs were present in all seven samples and GSCs in six out of seven samples. The SVZ in all samples were hypoxic and expressed the same relevant chemokines and their receptors as GSC niches in glioblastoma tumors: stromal-derived factor-1α (SDF-1α), C-X-C receptor type 4 (CXCR4), osteopontin, and CD44. In conclusion, in glioblastoma patients, GSCs are present at distance from the glioblastoma tumor in the SVZ. These findings suggest that GSCs in the SVZ niche are protected against radiotherapy and chemotherapy and protected against surgical resection due to their distant localization and thus may contribute to tumor recurrence after therapy.     

Repression of SIRT1 Promotes the Differentiation of Mouse Induced Pluripotent Stem Cells into Neural Stem Cells

The use of transplanting functional neural stem cells (NSCs) derived from induced pluripotent stem cells (iPSCs) has increased for the treatment of brain diseases. As such, it is important to understand the molecular mechanisms that promote NSCs differentiation of iPSCs for future NSC-based therapies. Sirtuin 1 (SIRT1), a NAD⁺-dependent protein deacetylase, has attracted significant attention over the past decade due to its prominent role in processes including organ development, longevity, and cancer. However, it remains unclear whether SIRT1 plays a role in the differentiation of mouse iPSCs toward NSCs. In this study, we produced NSCs from mouse iPSCs using serum-free medium supplemented with retinoic acid. We then assessed changes in the expression of SIRT1 and microRNA-34a, which regulates SIRT1 expression. Moreover, we used a SIRT1 inhibitor to investigate the role of SIRT1 in NSCs differentiation of iPSCs. Data revealed that the expression of SIRT1 decreased, whereas miRNAs-34a increased, during this process. In addition, the inhibition of SIRT1 enhanced the generation of NSCs and mature neurocytes. This suggests that SIRT1 negatively regulated the differentiation of mouse iPSCs into NSCs, and that this process may be regulated by miRNA-34a.