神经上皮干细胞的分离培养及其体外分化特性的观察

目的探讨大鼠胚胎神经管神经上皮干细胞的分离培养条件,并观察其在体外的分化特性.方法采用显微解剖、机械吹打、无血清悬浮培养方法分离培养神经上皮干细胞,采用巢蛋白(nestin)免疫细胞化学染色技术检测神经上皮干细胞,用NSE和GFAP免疫组化染色检测并计数神经细胞和神经胶质细胞.结果大鼠胚胎神经管神经上皮干细胞在无血清培养基中可形成大量呈nestin抗原阳性细胞构成的神经球,经传代有血清培养后分化为NSE阳性和GFAP阳性细胞,其中NSE阳性细胞占细胞总数的47.7%,GFAP阳性细胞占细胞总数的39.8%.结论胎鼠神经管神经上皮干细胞在无血清培养中可增殖和传代,在有血清培养中可分化为神经细胞和神经胶质细胞,两者之比为47.7∶39.8.     

聚焦中国

小神经球传代法扩充干细胞哈尔滨医科大学神经外科梁鹏博士在国家自然科学基金的支持下,利用小神经球传代方法建立了神经干细胞体外长期培养传代系统。用小神经球传代方法在体外可培养神经干细胞达到10个月,传代25代,从单一的细胞可扩增至10万个细胞。多次传代后细胞冻存对细胞的     

兔胚胎神经干细胞的分离、培养和鉴别

目的：研究兔胎脑神经干细胞体外生长特性,为探讨神经干细胞的临床应用及神经系统的发育奠定基础。方法：采用含碱性成纤维细胞生长因子（bFGF）和表皮细胞生长因子（EGF）的N2无血清培养技术,取18天龄兔胚胎脑组织,分离神经干细胞,并观察分离的细胞体外培养、增殖、分化潜能,免疫组化鉴定。结果：从18天龄兔胎脑皮质和纹状体中成功分离出具有自我更新和多分化潜能的神经干细胞,在无血清培养时细胞呈半贴壁状态生长,形成神经球,可传代。细胞呈Nestin免疫反应阳性;在含血清培养基中培养时则分化,分化后的细胞表达神经元细胞、星形胶质细胞和少突胶质细胞的特异性抗原。结论：来自兔胎脑神经干细胞能在体外培养、增殖并保持传代能力。无血清N2EGF、bFGF培养基有利于兔胎脑神经干细胞的存活和增殖,含血清培养基能诱导兔胎脑神经干细胞分化。     

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。     

小鼠胚胎神经干细胞的分离培养及其鉴定

且的探索小鼠胚胎神经干细胞的体外培养方法,并获取高纯度的神经干细胞,为神经干细胞的深入研究提供实验材料。方法无菌条件下分离E15天小鼠胚脑皮质,制成单细胞悬液,在bFGF和B27存在的培养基中培养扩增,通过免疫细胞化学染色鉴定神经干细胞及其子代细胞的分化方向。结果培养的部分细胞在B27和bFGF存在的无血清培养基中可以在体外分裂增殖,同时表达神经干细胞特异性抗原nestin,并在撤出B27和bFGF的有血清培养基中向神经细胞和胶质细胞分化。结论小鼠胚脑皮质存在具有多向分化潜能的神经干细胞,这些细胞可以在体外稳定培养、传代并自然分化,为细胞替代治疗提供了理想的细胞来源。     

体外神经干细胞克隆球的超微结构-透射电镜观察

为观察培养的神经干细胞克隆球内部的超微结构特征,采用无血清培养技术,在体外进行小鼠纹状体神经干细胞克隆球的培养传代,经过免疫细胞化学鉴定后,对单一的神经干细胞克隆球进行固定,常规透射电镜观察。结果表明,神经干细胞可以在bFGF等生长因子存在的情况下,在无血清培养液内增殖生成悬浮状态的神经干细胞克隆球,这种克隆可被诱导生成神经细胞和神经胶质细胞,电镜下,神经干细胞克隆球内部细胞相互间可形成特化的膜性结构,细胞内可有小泡出现,部分细胞有凋亡的形态。     

神经干细胞分离培养方法的介绍

在成体的许多组织中发现了多能干细胞,这些干细胞可以进行自我复制,参与组织的正常修复。神经干细胞在体外能分化为神经元、星形胶质细胞和少突胶质细胞,并具有多向分化潜能。成体神经干细胞和胚胎干细胞都能分化成成体神经系统中的各种神经细胞。神经干细胞具有自我更新能力,因此神经干细胞可以应用于神经损伤或者神经疾病的修复。本文概述了神经干细胞体外分离培养的方法及其生长影响因子。     

大鼠骨髓基质干细胞的分离培养与向神经元样细胞诱导分化的实验研究

目的 探讨大鼠骨髓基质干细胞的提取、分离培养和体外扩增的最佳条件,研究其在体外培养中定向诱导分化为神经元样细胞的可能。方法 通过密度梯度离心和贴壁培养法从成年大鼠骨髓中分离骨髓基质干细胞,进行培养扩增,观察其生长特性;用2-巯基乙醇(β-mercaptoethanol,β-ME)对传代细胞诱导分化,并通过免疫细胞化学染色鉴定分化细胞的类型。结果 原代培养时形成由基质干细胞组成的细胞集落,细胞集落14d时接近融合,传代后,细胞体积变大,约5～7d传代一次。β-ME诱导后,70％以上的细胞在形态上呈神经元样,免疫细胞化学染色呈NSE阳性,GFAP阴性,说明诱导分化的细胞为神经元,而不是星形胶质细胞。结论 骨髓基质干细胞在体外培养条件下生长良好,并可连续传代;在β-ME作用下可被诱导分化为神经元样细胞。     

胚胎大鼠脑和脊髓神经干细胞的分离和培养

研究采用显微解剖、无血清细胞培养和免疫荧光细胞化学染色等实验技术 ,成功地建立了胚胎大鼠脑和脊髓神经干细胞 (NSCs)的分离和培养方法。结果显示 ,( 1)在含成纤维细胞生长因子 2 (FGF 2 )和表皮生长因子(EGF)的无血清培养液中 ,两种来源的NSCs经体外培养 8- 10代后 ,其细胞数呈指数级增加 ,其中脑来源的NSCs数由原代培养时的 1× 10 6 增加至 1× 10 12 ,脊髓来源的NSCs数从 1× 10 6 增加至 1× 10 11。增殖的细胞表达神经上皮干细胞蛋白 (nestin) ;( 2 )在含 1%胎牛血清 (FBS)的培养条件下 ,它们都能被诱导分化为神经元、少突胶质细胞和星型胶质细胞。但其分化比例可随细胞传代次数的增加而改变 ,其中 ,大脑来源的NSCs分化为神经元的比例从第二代 (P2 )的 11 95± 2 5 %下降至第五代 (P5)的 1 97± 1 16% (P <0 0 1) ,而少突胶质细胞的分化比例则基本保持不变 ,这一分化格局同样可在脊髓来源的NSCs中发现。结果表明 ,我们所分离和培养的细胞在体外经多次传代后仍具有很强的增殖能力和多向分化潜能 ,它们都表达nestin ,属于中枢神经系统的干细胞     

人酸性成纤维细胞生长因子神经营养作用的初步研究

本实验研究了人酸性成纤维细胞生长因子(haFGF)的体外神经营养作用。结果表明,haFGF在体外能明显促进鸡胚(E-8)脊髓组织神经突起的生长,并能明显改变新生大鼠脑星形胶质细胞的形态,使扁平、多角形紧密联接的细胞转化为具有纤维样突起的胶质细胞,同时对胶质细胞DNA合成也有一定促进作用。实验还证明,haFGF可增加体外培养新生大鼠海马神经元的存活,且大大增加神经元胞体体积及突起长度。     

大鼠脑神经干细胞系（RNSC—FMU 1）的建立和鉴定

A neural stem cell line (RNSC-FMU 1) from rat brain have been established successfully by isolating and culturing neural stem cells from newborn SD rat brain in vitro with free-serum medium and passaging with mechanical division. The cell line cultured can continuously generate in vitro for long-term and it is 21 months (>100 passages) so far. These cells keep the feature of neural stem cell and normal karyotype. These neural stem cells can be induced to differentiate into neurons, astrocytes and oligodendrocytes. The cells have an extensive self-renewal capacity; its doubling time of proliferation is about 20 h. The cells are also cryopreservable. Tumor formation is not observed in nude mice that explanted with the cells. This cell line is a good tool for research of neural stem cell.     

Fate of amnion-derived stem cells transplanted to the fetal rat brain: migration, survival and differentiation

We have recently characterized a stem cell population isolated from the rodent amniotic membrane termed amnion-derived stem cells (ADSCs). In vitro ADSCs differentiate into cell types representing all three embryonic layers, including neural cells. In this study we evaluated the neuroectodermal potential of ADSCs in vivo after in utero transplantation into the developing rat brain. A clonal line of green fluorescent protein-expressing ADSCs were infused into the telencephalic ventricles of the developing embryonic day 15.5 rat brain. At E17.5 donor cells existed primarily as spheres in the ventricles with subsets fused to the ventricular walls, suggesting a mode of entry into the brain parenchyma. By E21.5 green fluorescent protein (GFP) ADSCs migrated to a number of brain regions. Examination at postnatal time points revealed that donor ADSCs expressed vimentin and nestin. Subsets of transplanted ADSCs attained neuronal morphologies, although there was no immunohistochemical evidence of neural or glial differentiation. Some donor cells migrated around blood vessels and differentiated into putative endothelial cells. Donor ADSCs transplanted in utero were present in recipients into adulthood with no evidence of immunological rejection or tumour formation. Long-term survival may suggest utility in the treatment of disorders where differentiation to a neural cell type is not required for clinical benefit.     

Cellular Environment Directs Differentiation of Human Umbilical Cord Blood�CDerived Neural Stem Cells In Vitro

Cord blood–derived neural stem cells (NSCs) are proposed as an alternative cell source to repair brain damage upon transplantation. However, there is a lack of data showing how these cells are driven to generate desired phenotypes by recipient nervous tissue. Previous research indicates that local environment provides signals driving the fate of stem cells. To investigate the impact of these local cues interaction, the authors used a model of cord blood–derived NSCs co-cultured with different rat brain–specific primary cultures, creating the neural-like microenvironment conditions in vitro. Neuronal and astro-, oligo-, and microglia cell cultures were obtained by the previously described methods. The CMFDA-labeled neural stem cells originated from, non-transformed human umbilical cord blood cell line (HUCB-NSCs) established in a laboratory. The authors show that the close vicinity of astrocytes and oligodendrocytes promotes neuronal differentiation of HUCB-NSCs, whereas postmitotic neurons induce oligodendrogliogenesis of these cells. In turn, microglia or endothelial cells do not favor any phenotypes of their neural commitment. Studies have confirmed that HUCB-NSCs can read cues from the neurogenic microenvironment, attaining features of neurons, astrocytes, or oligodendrocytes. The specific responses of neurally committed cord blood–derived cells, reported in this work, are very much similar to those described previously for NSCs derived from other “more typical” sources. This further proves their genuine neural nature. Apart from having a better insight into the neurogenesis in the adult brain, these findings might be important when predicting cord blood cell derivative behavior after their transplantation for neurological disorders.     

Adult vascular smooth muscle cells in culture express neural stem cell markers typical of resident multipotent vascular stem cells

Differentiation of resident multipotent vascular stem cells (MVSCs) or de-differentiation of vascular smooth muscle cells (vSMCs) might be responsible for the SMC phenotype that plays a major role in vascular diseases such as arteriosclerosis and restenosis. We examined vSMCs from three different species (rat, murine and bovine) to establish whether they exhibit neural stem cell characteristics typical of MVSCs. We determined their SMC differentiation, neural stem cell marker expression and multipotency following induction in vitro by using immunocytochemistry, confocal microscopy, fluorescence-activated cell sorting analysis and quantitative real-time polymerase chain reaction. MVSCs isolated from rat aortic explants, enzymatically dispersed rat SMCs and rat bone-marrow-derived mesenchymal stem cells served as controls. Murine carotid artery lysates and primary rat aortic vSMCs were both myosin-heavy-chain-positive but weakly expressed the neural crest stem cell marker, Sox10. Each vSMC line examined expressed SMC differentiation markers (smooth muscle α–actin, myosin heavy chain and calponin), neural crest stem cell markers (Sox10⁺, Sox17⁺) and a glia marker (S100β⁺). Serum deprivation significantly increased calponin and myosin heavy chain expression and decreased stem cell marker expression, when compared with serum-rich conditions. vSMCs did not differentiate to adipocytes or osteoblasts following adipogenic or osteogenic inductive stimulation, respectively, or respond to transforming growth factor-β1 or Notch following γ-secretase inhibition. Thus, vascular SMCs in culture express neural stem cell markers typical of MVSCs, concomitant with SMC differentiation markers, but do not retain their multipotency. The ultimate origin of these cells might have important implications for their use in investigations of vascular proliferative disease in vitro.     

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。     

Adherent self-renewable human embryonic stem cell-derived neural stem cell line: functional engraftment in experimental stroke model

Background

Human embryonic stem cells (hESCs) offer a virtually unlimited source of neural cells for structural repair in neurological disorders, such as stroke. Neural cells can be derived from hESCs either by direct enrichment, or by isolating specific growth factor-responsive and expandable populations of human neural stem cells (hNSCs). Studies have indicated that the direct enrichment method generates a heterogeneous population of cells that may contain residual undifferentiated stem cells that could lead to tumor formation in vivo.

Methods/Principal Findings

We isolated an expandable and homogenous population of hNSCs (named SD56) from hESCs using a defined media supplemented with epidermal growth factor (EGF), basic fibroblast growth factor (bFGF) and leukemia inhibitory growth factor (LIF). These hNSCs grew as an adherent monolayer culture. They were fully neuralized and uniformly expressed molecular features of NSCs, including nestin, vimentin and radial glial markers. These hNSCs did not express the pluripotency markers Oct4 or Nanog, nor did they express markers for the mesoderm or endoderm lineages. The self-renewal property of the hNSCs was characterized by a predominant symmetrical mode of cell division. The SD56 hNSCs differentiated into neurons, astrocytes and oligodendrocytes throughout multiple passages in vitro, as well as after transplantation. Together, these criteria confirm the definitive NSC identity of the SD56 cell line. Importantly, they exhibited no chromosome abnormalities and did not form tumors after implantation into rat ischemic brains and into naïve nude rat brains and flanks. Furthermore, hNSCs isolated under these conditions migrated toward the ischemia-injured adult brain parenchyma and improved the independent use of the stroke-impaired forelimb two months post-transplantation.

Conclusions/Significance

The SD56 human neural stem cells derived under the reported conditions are stable, do not form tumors in vivo and enable functional recovery after stroke. These properties indicate that this hNSC line may offer a renewable, homogenous source of neural cells that will be valuable for basic and translational research.     

Isolation and characterization of a neural progenitor cell line from tilapia brain

Astroglial cell lines have many applications for advancing neural developmental and functional studies. However, few astroglial cell lines have been reported from fish. In this study, we report the characterization of the immortal cell line TB2 isolated from adult tilapia brain tissue. The cell line was established at 25 degrees C in L15 medium supplemented with 15% fetal bovine serum. Most of the cells displayed a fibrous morphology and were immunoreactive for A2B5 antigen, glial fibrillary acidic protein (GFAP), keratin, vimentin, and the gap junction protein connexin 43 (Cx43). They weakly expressed glutamine synthetase (GS), S100 protein, and the neural stem cell markers Sox2 and brain lipid binding protein (BLBP). In contrast to astroglia in vivo, most TB2 cells also expressed galactocerebroside (GalC), substance P (SP), and tyrosine hydroxylase (TH). By immunoblot and RT-PCR, the cells also expressed myelin basic protein (MBP), proteolipid protein (PLP), and Cx35. On a poly-L-lysine-coated substrate in vitro, TB2 cells showed increases in neuronal dopamine decarboxylase (DDC) and microtubule-associated protein 2 (MAP2), indicating that they can initiate differentiation into neurons. Taken together, the results suggest that TB2 cells are astroglial progenitor cells (neural stem cells) and may develop into oligodendrocytes and neurons in a suitable environment. The present study advances our knowledge of fish astroglia. However, the factors that affect neural development in fish remain unknown, as do the characteristics of the intermediate differentiation stages between stem cells and mature nerve cells. The TB2 cell line will promote these investigations.     

Isolation and characterization of a neural progenitor cell line from tilapia brain.

Astroglial cell lines have many applications for advancing neural developmental and functional studies. However, few astroglial cell lines have been reported from fish. In this study, we report the characterization of the immortal cell line TB2 isolated from adult tilapia brain tissue. The cell line was established at 25 degrees C in L15 medium supplemented with 15% fetal bovine serum. Most of the cells displayed a fibrous morphology and were immunoreactive for A2B5 antigen, glial fibrillary acidic protein (GFAP), keratin, vimentin, and the gap junction protein connexin 43 (Cx43). They weakly expressed glutamine synthetase (GS), S100 protein, and the neural stem cell markers Sox2 and brain lipid binding protein (BLBP). In contrast to astroglia in vivo, most TB2 cells also expressed galactocerebroside (GalC), substance P (SP), and tyrosine hydroxylase (TH). By immunoblot and RT-PCR, the cells also expressed myelin basic protein (MBP), proteolipid protein (PLP), and Cx35. On a poly-L-lysine-coated substrate in vitro, TB2 cells showed increases in neuronal dopamine decarboxylase (DDC) and microtubule-associated protein 2 (MAP2), indicating that they can initiate differentiation into neurons. Taken together, the results suggest that TB2 cells are astroglial progenitor cells (neural stem cells) and may develop into oligodendrocytes and neurons in a suitable environment. The present study advances our knowledge of fish astroglia. However, the factors that affect neural development in fish remain unknown, as do the characteristics of the intermediate differentiation stages between stem cells and mature nerve cells. The TB2 cell line will promote these investigations.     

Effects of human cultural neuronal and mesenchymal stem cells on the rat learning and brain state after acute hypoxia

The aim of the study was to compare the effects of neurotransplantation of cultural neural stem cells (NSC) and mesenchymal stem cells (MSC) on the rat behaviour and brain state after acute hypoxia. It was shown that development of two-way avoidance defensive conditioning in a shuttle box improved in rats-recipients with NSC, but not MSC as compared to control. Both the transplants of NSC and transplants of MSC exert neuroprotective influence on the rat brain. NSC both in vitro (before transplantation) and in vivo (on day 27 after transplantation) gave rise to all neural cell types: stem/progenitor cells, precursors of neurons and glia, neurons and glial cells. MSC population in vitro and in vivo (on day 10 after transplantation) consisted of fibroblast-like cells which were eliminated by day 20 after transplantation and were surrounded by reactive glia. We suggest that effects of NSC may be connected with their good survival and potential to differentiate into neurons and with trophic influence on the brain of recipient, whereas MSC only have possible positive trophic effect at early stages after transplantation.