诱导干细胞分人为神经细胞的研究进展

干细胞是在机体分化过程中存在的具有自我增殖,更新能力,且能形成各种类型分化细胞的一类细胞的总称,它不但为细胞发育分化和细胞诱导研究提供了很好的模型,而且对于临床细胞替代疗法与细胞移植具有重要意义,作者综合干细胞研究的成果,从方法,机理及诱导得到的神经细胞的检查等几个方面对诱导干细胞向神经细胞分化的进展加以综述。     

诱导胚胎干细胞向神经细胞分化方法的研究与探讨

胚胎干细胞(ES细胞)是一种能够在体外进行不断自我更新,并具有多种分化潜能的细胞。胚胎干细胞向神经细胞诱导分化的研究进展迅速,相关实验技术和理论也不断发展。总结了近年来各国研究者诱导小鼠和人胚胎干细胞向神经细胞分化的方法,分析了一些方法的原理并初步探讨其相关的分子机制,并提出一些可行性新方法。胚胎干细胞向神经细胞诱导分化因其体外的可操作性、来源的广泛性及质量可控性将有可能成为临床上治疗神经系统疾病的有效方法。     

诱导性多能干细胞向神经细胞分化的研究进展

诱导性多能干细胞(induced pluripotent stem cell,iPS cell)是通过转染外源特定的基因组合来诱导成体细胞重编程为类似于胚胎干细胞的一种多潜能干细胞,iPS细胞与胚胎干细胞不仅在形态上相似,而且在功能方面几乎相同.另外,iPS细胞的诞生克服了胚胎干细胞在临床应用时涉及的移植免疫排斥与伦理道德问题,因此具有重要的临床应用价值.目前iPS在治疗中枢神经系统性疾病方面的研究已取得很大进展,包括iPS细胞向神经细胞诱导分化方法的改进、分化机理的探索以及iPS细胞分化来源神经细胞在神经系统疾病模型中治疗作用的研究等.从iPS细胞的创建及特点、iPS细胞向神经细胞分化的诱导方法及研究新进展方面予以综述.     

胚胎干细胞体外诱导分化

胚胎干细胞能在体外长期不断自我更新,具有高度分化潜能,可分化成胎儿和成体的几乎所有类型的细胞,如心肌细胞、神经细胞、上皮细胞、肝细胞、血细胞、胰岛细胞、脂肪细胞及生殖细胞等.在细胞治疗和组织器官替代治疗、发育生物学等的研究中将具有广阔的应用前景.目前已有多种胚胎干细胞体外定向诱导的报道.本文从体外诱导分化影响因素和几种主要诱导细胞类型进行分析和总结,为胚胎干细胞的诱导分化研究提供参考资料.     

胚胎干细胞体外诱导分化

胚胎干细胞能在体外长期不断自我更新,具有高度分化潜能,可分化成胎儿和成体的几乎所有类型的细胞,如心肌细胞、神经细胞、上皮细胞、肝细胞、血细胞、胰岛细胞、脂肪细胞及生殖细胞等。在细胞治疗和组织器官替代治疗、发育生物学等的研究中将具有广阔的应用前景。目前已有多种胚胎干细胞体外定向诱导的报道。本文从体外诱导分化影响因素和几种主要诱导细胞类型进行分析和总结,为胚胎干细胞的诱导分化研究提供参考资料。     

动物胚胎干细胞诱导分化的研究进展

胚胎干细胞 (ES细胞 )是从动物早期胚胎的内细胞团或原始生殖细胞分离出来的具有发育全能性的一种未分化的无限增殖细胞系 ,ES细胞能体外诱导分化为神经细胞、肌肉细胞、成纤维细胞等各种细胞。综述了动物的ES细胞的分化诱导机理及目前体外诱导分化的研究现状     

胚胎干细胞分化潜能研究进展

胚胎干细胞(ESC)是来源于哺乳动物早期胚胎的一种具有多向分化潜能的细胞。目前已经从胚胎干细胞分化培育出了心肌细胞,神经细胞,血管内皮细胞和壁细胞,胰岛细胞等。胚胎干细胞的诱导分化可以从形成拟胚体途径,也可以直接分化。对胚胎干细胞的研究具有广阔的应用前景,但也存在很多问题尚待解决。     

表皮生长因子诱导骨髓间充质干细胞向视网膜神经细胞分化的体外研究

目的:研究表皮生长因子诱导骨髓间充质干细胞向视网膜神经细胞分化的可能性。方法:体外培养骨髓间充质干细胞,利用流式细胞仪分析其细胞表型。采用含EGF的培养液诱导骨髓间充质干细胞向视网膜神经细胞分化,并利用免疫荧光法进行鉴定。结果:从骨髓中分离培养的细胞具有成纤维细胞样形态,贴壁生长,表型相对均一,表面标志为CD90、CD44、CD147阳性;而CD34、CD38、CD45、CD14、HLA-DR阴性。体外诱导后可以得到神经干细胞标志物nestin、神经胶质细胞标志物GFAP和视网膜光感受器细胞标志物Rhodopsin呈阳性表达的细胞。结论:从骨髓中分离培养得到的间充质干细胞具有向视网膜神经细胞分化的潜能。     

神经退行性疾病和脑损伤的细胞疗法

成熟的神经细胞属于终末分化细胞,具有不可再生性。神经退行性疾病以及其他脑损伤引起的神经元缺失,难以自发修复取代。如何修复大脑中受损的神经细胞、补充神经细胞已成为治疗各类神经系统疾病的关键。本综述将通过干细胞移植和诱导星形胶质细胞去分化两种途径来介绍针对神经退行性疾病和脑损伤的最新疗法。     

干细胞定向分化的基础和临床应用研究

胚胎干细胞具有多向性分化的潜能,可以分化成为内、中、外三个胚层的所有细胞,存在于组织器官中的成体干细胞（包括心脏等的前体细胞）也能分化成为某些细胞,用来修复、补充体内受损、死亡的细胞.目前干细胞研究的重点是：干细胞未分化和多向性机制的基础研究;干细胞向特定细胞群体分化的调控和分化细胞的应用研究,而后者是连接基础研究和临床研究的必经之路.干细胞的基础和临床应用研究不但可以了解正常的胚胎发育过程,而且利用掌握的知识通过体外诱导或体内激活的方法针对性地治疗某些疾病.目前我们的研究集中在神经细胞（包括视网膜细胞和内耳前体细胞）、脂肪细胞和心肌细胞定向分化的分子机理,并通过疾病动物模型验证这些定向分化的细胞的功能.希望通过建立人胚胎干细胞以及成体干细胞向外胚层的特种神经元（包括前脑神经上皮细胞、GABA和胆碱能神经元、视觉细胞、听觉细胞、多巴胺能神经元）和中胚层的脂肪细胞、骨细胞以及心肌细胞定向分化的模型,继而采用蛋白质组学和基因组学最新技术分析这些建立的模型,研究相关因子通过哪条信号传导通路导致这些细胞的定向分化或者通过改变哪个目的基因的表达,或改变目的蛋白的修饰导致干细胞定向成神经细胞、脂肪细胞和心肌细胞;研究成年脑内源性干细胞定向诱导成这些功能性神经元的机理,并进行比较研究.用Lentivirus转染干细胞高表达、或用RNA干扰抑制上述研究得到的目的基因,在细胞模型和动物体内验证这些信号通路和目的基因在干细胞定向分化中的作用.     

Plant stem cells and their regulations in shoot apical meristems

Stem cells in plants, established during embryogenesis, are located in the centers of the shoot apical meristem (SAM) and the root apical meristem (RAM). Stem cells in SAM have a capacity to renew themselves and to produce new organs and tissues indefinitely. Although fully differentiated organs such as leaves do not contain stem cells, cells in such organs do have the capacity to re-establish new stem cells, especially under the induction of phytohormones in vitro. Cytokinin and auxin are critical in creating position signals in the SAM to maintain the stem cell organizing center and to position the new organ primordia, respectively. This review addresses the distinct features of plant stem cells and focuses on how stem cell renewal and differentiation are regulated in SAMs.     

Rigid matrix supports osteogenic differentiation of stem cells from human exfoliated deciduous teeth (SHED)

Stem cell fate can be induced by the grade of stiffness of the extracellular matrix, depending on the developed tissue or complex tissues. For example, a rigid extracellular matrix induces the osteogenic differentiation in bone marrow derived mesenchymal stem cells (MSCs), while a softer surface induces the osteogenic differentiation in dental follicle cells (DFCs). To determine whether differentiation of ectomesenchymal dental precursor cells is supported by similar grades of extracellular matrices (ECMs) stiffness, we examined the influence of the surface stiffness on the proliferation and osteogenic differentiation of stem cells from human exfoliated deciduous teeth (SHED). Cell proliferation of SHED was significantly decreased on cell culture surfaces with a muscle-like stiffness. A dexamethasone-based differentiation medium induced the osteogenic differentiation of SHED on substrates of varying mechanical stiffness. Here, the hardest surface improved the induction of osteogenic differentiation in comparison to that with the softest stiffness. In conclusion, our study showed that the osteogenic differentiation of ectomesenchymal dental precursor cells SHED and DFCs are not supported by similar grades of ECM stiffness.     

植物根尖干细胞的表观遗传调控

干细胞是一类具有特化为不同细胞类型能力的多能性细胞,他为多细胞生物的器官发生、损伤修复和再生源源不断提供新细胞。干细胞的特化和维持需要复杂的基因调控网络来有序调控。此外,表观遗传调控在包括干细胞命运决定在内的许多生物学过程中发挥极其重要的作用。本文归纳了近年来对植物,主要是模式植物拟南芥（Arabidopsis thaliana（L.）Heynh.）根尖干细胞表观遗传调控方面的研究进展,重点论述了表观调控因子与控制干细胞的关键转录因子之间如何互作、调控植物根尖干细胞的自我更新和分化,并对今后研究的突破方向进行了展望。     

小分子化合物诱导干细胞向视网膜感光细胞分化的研究进展

干细胞是一类具有多向分化潜能的细胞群,如胚胎干细胞(embryonic stem cell,ESC)、诱导多潜能干细胞(induced pluripotent stem cell,i PSC)等,可在特定的条件下向包括视网膜感光细胞在内的多种细胞分化。小分子化合物是一类由组织细胞合成、分泌的小分子多肽类因子,特定的小分子化合物可作用于干细胞诱导其向视网膜感光细胞分化。目前,对干细胞体外培养,通过使用不同的诱导培养方案,探索干细胞向视网膜感光细胞分化的研究成为热点。早期,研究者们主要在共培养条件下采用小分子化合物诱导ESC向视网膜感光细胞分化,随着研究的进展,逐渐开始探索在无共培养条件下小分子化合物诱导ESC向视网膜感光细胞的分化以及小分子化合物诱导i PSC向视网膜感光细胞的分化。本文主要就小分子化合物促进ESC和i PSC向视网膜感光细胞分化的研究进展进行综述。     

Stem cell mechanobiology

Stem cells are undifferentiated cells that are capable of proliferation, self‐maintenance and differentiation towards specific cell phenotypes. These processes are controlled by a variety of cues including physicochemical factors associated with the specific mechanical environment in which the cells reside. The control of stem cell biology through mechanical factors remains poorly understood and is the focus of the developing field of mechanobiology. This review provides an insight into the current knowledge of the role of mechanical forces in the induction of differentiation of stem cells. While the details associated with individual studies are complex and typically associated with the stem cell type studied and model system adopted, certain key themes emerge. First, the differentiation process affects the mechanical properties of the cells and of specific subcellular components. Secondly, that stem cells are able to detect and respond to alterations in the stiffness of their surrounding microenvironment via induction of lineage‐specific differentiation. Finally, the application of external mechanical forces to stem cells, transduced through a variety of mechanisms, can initiate and drive differentiation processes. The coalescence of these three key concepts permit the introduction of a new theory for the maintenance of stem cells and alternatively their differentiation via the concept of a stem cell ‘mechano‐niche’, defined as a specific combination of cell mechanical properties, extracellular matrix stiffness and external mechanical cues conducive to the maintenance of the stem cell population. J. Cell. Biochem. 112: 1–9, 2011. © 2010 Wiley‐Liss, Inc.     

Letter from the Guest Editor

Understanding the mechanisms of stem cell proliferation, self-renewal and differentiation is fundamental for stem cell biology. Stem cells proliferate by either symmetric division or asymmetric division. Through asymmetric division, stem cells self-renew and differentiate to mature cells. Stem cells could also divide symmetrically to give rise to differentiated cells. Besides intrinsic cues, proliferation and self-renewal of most stem cell types also rely on extrinsic signals from niche or surrounding cells. Failure in any of these factors may result in disturbed stem cell proliferation, self-renewal or differentiation and/or generate cancer stem cells that drive cancer development.     

Structural properties of scaffolds: Crucial parameters towards stem cells differentiation

Tissue engineering is a multidisciplinary field that applies the principles of engineering and life-sciences for regeneration of damaged tissues. Stem cells have attracted much interest in tissue engineering as a cell source due to their ability to proliferate in an undifferentiated state for prolonged time and capability of differentiating to different cell types after induction. Scaffolds play an important role in tissue engineering as a substrate that can mimic the native extracellular matrix and the properties of scaffolds have been shown to affect the cell behavior such as the cell attachment, proliferation and differentiation. Here, we focus on the recent reports that investigated the various aspects of scaffolds including the materials used for scaffold fabrication, surface modification of scaffolds, topography and mechanical properties of scaffolds towards stem cells differentiation effect. We will present a more detailed overview on the effect of mechanical properties of scaffolds on stem cells fate.     

Retinal stem cells: promising candidates for retina transplantation

Stem cell transplantation is widely considered as a promising therapeutic approach for photoreceptor degeneration, one of the major causes of blindness. In this review, we focus on the biology of retinal stem cells (RSCs) and progenitor cells (RPCs) isolated from fetal, postnatal, and adult animals, with emphasis on those from rodents and humans. We discuss the origin of RSCs/RPCs, the markers expressed by these cells and the conditions for the isolation, culture, and differentiation of these cells in vitro or in vivo by induction with exogenous stimulation. Commercial disclosure: none.     

Stem cell fate and patterning in mammalian epidermis.

Recent studies highlight characteristics of epidermal stem cells that were not fully appreciated before. Stem cells are multipotential and signals exchanged with their neighbours help to regulate exit from the stem cell compartment and differentiation along specific lineages. Stem cells exhibit a high degree of spatial organisation, and cell clustering and motility contribute to the assembly and maintenance of the epidermis.