小鼠胚胎干细胞定向分化为神经干细胞过程中microRNA的变化

目的用生物芯片技术分析胚胎干细胞定向分化为神经干细胞过程中microRNA(miRNA)的表达变化,筛选调控的分化的miRNA,研究分化调控机制。方法胚胎干细胞在含LIF培养基中培养3d后,采用经典5步培养方法定向诱导向神经干细胞分化,采用nestin作为神经干细胞标记进行鉴定,送检胚胎干细胞及神经干细胞,提取总RNA以及小分子RNA,经荧光标记后与miRNA基因芯片杂交,获得胚胎干细胞诱导前后miRNA表达谱。结果1)胚胎干细胞在含LIF培养过程中保持未分化状态,Oct-4、碱性磷酸酶表达阳性;2)经典五步法诱导胚胎干细胞定向分化为神经干细胞,nestin阳性细胞为85%;3)通过基因微阵列分析,有90个miRNA的改变显著,其中68个表达上调,22个表达下调。结论miRNA可能对胚胎干细胞定向分化为神经干细胞过程起到关键作用。     

Fbxw7在干细胞维持中的作用

干细胞拥有独特的细胞周期状态,具有自我更新和多向分化的潜能。干细胞一般分为成体干细胞、胚胎干细胞和诱导多功能干细胞三大类。成体干细胞一般处于静止状态,在需要增殖的情况下,可以转换到增殖状态。然而,胚胎干细胞和诱导多功能干细胞会一直保持快速增殖的状态,直到出现分化诱导,中止细胞周期进程。揭示干细胞细胞周期的调控机制,能帮助我们更好地了解干细胞自我更新和分化之间的调控。目前已经鉴定出许多细胞因子及小分子化合物能促进干细胞增殖,但相关的负调控因子却了解不多。Fbxw7(F-box and WD40 repeat domaincontaining 7)作为一种泛素连接酶,能负向调控造血干细胞、神经干细胞、胚胎干细胞、精原干细胞以及肿瘤干细胞等的细胞周期进程,尤其是在调控成体干细胞的静止、增殖和分化方面有重要作用。     

重组腺相关病毒转染神经干细胞球的实验研究

目的:探讨重组腺相关病毒2型(rAAV2)对神经干细胞球的转染能力.方法:①将FITC标记的rAAV2(FITC-rAAV2)分成两组,A组直接与神经干细胞球混合,B组与肝素混匀后再与神经干细胞球混合,孵育30 min后在荧光显微镜下观察;②含有GFP报告基因的rAAV2(rAAV2-GFP)与神经干细胞球孵育30 min后,分成两组:A组继续在培养箱内培养,B组分散成单细胞后移植到大鼠脑内,一个月后分别在荧光显微镜下观察神经干细胞球和大鼠脑组织切片中报告基因的表达情况;③将含有低氧启动子(低氧应答元件,HRE)、VEGF和GFP的rAAV2(rAAV2-HRE-VEGF-GFP)转染神经干细胞球后分为两组:A组在低氧条件下培养,B组在常规条件下培养,72 h后观察报告基因的表达情况.结果:①FITC-rAAV2转染神经干细胞球的结果:A组有明亮的绿色荧光,B组基本无绿色荧光;②rAAV2-GFP转染神经干细胞球后一个月,A、B两组均可以看到绿色荧光;③rAAV2-HRE-VEGF-GFP转染神经干细胞球后72 h,A组可见绿色荧光,B组无绿色荧光.结论:rAAV2可以与神经干细胞球特异性结合,rAAV2携带的外源基因在体内和体外均可以有效表达,rAAV2携带外源基因的表达可以人为调控.     

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.     

小鼠精原干细胞与胚胎干细胞样细胞

近年来,通过培养小鼠精原干细胞(spermatogonial stem cells,SSCs)获得了胚胎干细胞样细胞(,embryonic stem cell-like cells,ES样细胞).这些研究表明小鼠精原干细胞不仅具备特异分化为精子的干细胞潜能,而且具备胚胎干细胞(embryonic stem cell,ES)分化为三胚层的多向分化潜能.因此.这将有助于研究干细胞的分化调控机制,并且这些研究成果延伸至人类精原干细胞,也将为再生医学获取特殊的胚胎干细胞样细胞或特异分化的精子细胞开辟了蹊径.     

神经干细胞向神经元分化调控的研究进展

神经干细胞是一类具有分裂潜能和自更新能力的母细胞,它可以通过对称分裂和不对称分裂方式产生神经组织的各类细胞,包括神经元、星形胶质细胞和少突胶质细胞。中枢神经系统受到损伤后,神经元和胶质细胞的损伤导致了临床症状,内源性神经干细胞的修复作用不大,原因是干细胞的数量有限,微环境的不允许。移植的神经干细胞进入体内后,由于受到多种因素的影响,常保持未分化状态或大部分分化为胶质细胞。神经干细胞向神经元分化的调控机制及其影响因素直接决定神经干细胞源性神经元的比例和神经元之间功能性突触的数量。现就其研究进展做一综述。     

B淋巴细胞的造血调控作用

我们以往的工作证实T细胞对造血干细胞增殖分化的调控作用,经特异或非特异性抗原激活的淋巴细胞具有更强的调控活性。为了进一步弄清细胞间相互作用在造血调控中的地位,近年来我们又探讨了B淋巴细胞对造血干、祖细胞增殖调控作用。     

WOX蛋白家族调控干细胞发育分子机制的研究进展

WOX蛋白家族是植物特有的一类转录因子家族, 是植物胚胎建成、干细胞维持和器官发生等发育过程中的重要调控因子。越来越多的研究表明, 作为干细胞维持的关键因子之一, WOX蛋白家族通过相似或特异的调控网络参与植物初生分生组织(茎尖和根尖分生组织)和次生分生组织(维管分生组织)等各级干细胞的维持和分化。该文综述了近年来WOX蛋白家族调控干细胞发育分子机制的研究进展, 并对其在单、双子叶植物中功能的保守性进行了比较和分析。     

机械力及力学信号转导影响干细胞命运的研究进展

干细胞作为一种未分化的祖细胞,目前已被广泛应用于开展组织损伤修复、再生以及干细胞特异谱系分化的研究.大量研究表明,干细胞所处的微环境对调控干细胞的生长和分化具有重要作用,多种溶液介质、细胞外基质和信号通路等参与了干细胞命运的调控.尽管已有大量研究证明,溶液介质(如激素和生长因子)在干细胞的生长和分化中发挥重要作用,但近年来越来越多的研究表明,机械力及力学信号转导同样在干细胞自我更新、分化、衰老和凋亡等细胞生理过程中起到重要的作用.本文将对机械应力响应的细胞基础、生物力学及力学信号调控干细胞自我更新和分化,以及生物力学调控干细胞命运可能的作用机制几个方面加以综述.     

皮毛之道：以表皮器官为研究模型探讨再生生物学与再生医学的基础概念

再生医学是一个具有巨大潜力的新兴医学领域。该文以此为方向讨论了再生医学研究中的三个关键问题,并以非神经外胚层器官的干细胞行为为例做进一步的探讨。第一,如何获取干细胞,介绍了包括胚胎干细胞、组织干细胞和诱导性多能干细胞的获得途径,以及若干组织细胞重编程的成功范例;第二,如何将干细胞转化为组织和器官,这需要了解干细胞分化以及形态发生的机制,并以羽毛的形态发生为模型,引入了千细胞拓扑生物学的概念以及干细胞微环境调控塑造器官形态的机制;第三,如何将干细胞及其转化产物置于患者体内,并以鼠毛生长周期波为例,阐明了宏观环境因素如何调控干细胞的活性：最后,还分析了在器官发生中干细胞的自组织对于新生毛发组织工程的重要意义。该文的许多原则不仅限于皮肤,同时也适用于其它体内器官。通过对生物再生的过程的基础研究,我们可以受到生物再生之道的启发,逐渐理解组织修复及再生的机制,并提高分子和细胞水平上的干细胞操作技术,希望在不久的将来将干细胞研究成果应用于临床医学。     

In vitro characterization of subventricular zone isolated neural stem cells,from adult monkey and rat brain

Neural stem cells (NSCs) are multipotent, self-renewable cells who are capable of differentiating into neurons, astrocytes, and oligodendrocytes. NSCs reside at the subventricular zone (SVZ) of the adult brain permanently to guarantee a lifelong neurogenesis during neural network plasticity or undesirable injuries. Although the specious inaccessibility of adult NSCs niche hampers their in vivo identification, researchers have been seeking ways to optimize adult NSCs isolation, expansion, and differentiation, in vitro. NSCs were isolated from rhesus monkey SVZ, expanded in vitro and then characterized for NSCs-specific markers expression by immunostaining, real-time PCR, flow cytometry, and cell differentiation assessments. Moreover, cell survival as well as self-renewal capacity were evaluated by TUNEL, Live/Dead and colony assays, respectively. In the next step, to validate SVZ-NSCs identity in other species, a similar protocol was applied to isolate NSCs from adult rat’s SVZ as well. Our findings revealed that isolated SVZ-NSCs from both monkey and rat preserve proliferation capacity in at least nine passages as confirmed by Ki67 expression. Additionally, both SVZ-NSCs sources are capable of self-renewal in addition to NESTIN, SOX2, and GFAP expression. The mortality was measured meager with over 95% viability according to TUNEL and Live/Dead assay results. Eventually, the multipotency of SVZ-NSCs appraised authentic after their differentiation into neurons, astrocytes, and oligodendrocytes. In this study, we proposed a reliable method for SVZ-NSCs in vitro maintenance and identification, which, we believe is a promising cell source for therapeutic approach to recover neurological disorders and injuries condition.

     

Cell surface N-glycans-mediated isolation of mouse neural stem cells

The isolation of neural stem cells (NSCs) has been hampered by the lack of valid cell-surface antigens on NSCs, and novel valuable markers have been proposed. Glycan (oligosaccharide chain) is a potential candidate as a marker to isolate NSCs, because the species and the combination order of saccharides in glycan generate remarkable structural diversity and specificity. At present, the expression of hundreds of glycoconjugates with glycans have been found in the NSCs; however, just a few glycan-epitopes have been identified as valuable cell-surface markers. This review focused on the isolation of NSC using glycoprotein, especially complex type N-glycans. The cell-surface N-glycan-mediated isolation of NSCs is therefore expected to provide a comprehensive understanding of the biologic characteristics of NSCs in the brain, and thereby help to develop novel strategies in the field of regenerative medicine.     

Functional roles of glycoconjugates in the maintenance of stemness and differentiation process of neural stem cells

Neural stem cells (NSCs) possess a high proliferative potential and capacity for self-renewal with retention of multipotency to differentiate into brain-forming cells. NSCs have gained a considerable attention because of their potential application in treatment strategies on the basis of transplantation for neurodegenerative disorders and nerve injuries. Although several signaling pathways have been reportedly involved in the fate determination process of NSCs, the molecular mechanisms underlying the maintenance of neural cell stemness and differentiation process remain largely unknown. Glycoconjugates expressed in the NSC niche in the brain offer markers of NSCs; moreover, they serve as cell regulators, which are actively involved in the modulation of signal transduction. The glycans function on NCS surfaces by recruiting growth factor receptors to specific microdomains as components of glycolipids, thereby mediating the ligand–receptor interactions both indirectly and directly as components of proteoglycans and interacting with specific lectin-type receptors as components of ligand glycoproteins. In this review, we outline current knowledge of the possible functional mechanisms of glycoconjugates to determine cell fates, which are associated with their expression pattern and structural characteristic features.     

Neuronal-glial interactions in central nervous system neurogenesis: the neural stem cell perspective

Essentially, three neuroectodermal-derived cell types make up the complex architecture of the adult CNS: neurons, astrocytes and oligodendrocytes. These elements are endowed with remarkable morphological, molecular and functional heterogeneity that reaches its maximal expression during development when stem/progenitor cells undergo progressive changes that drive them to a fully differentiated state. During this period the transient expression of molecular markers hampers precise identification of cell categories, even in neuronal and glial domains. These issues of developmental biology are recapitulated partially during the neurogenic processes that persist in discrete regions of the adult brain. The recent hypothesis that adult neural stem cells (NSCs) show a glial identity and derive directly from radial glia raises questions concerning the neuronal-glial relationships during pre- and post-natal brain development. The fact that NSCs isolated in vitro differentiate mainly into astrocytes, whereas in vivo they produce mainly neurons highlights the importance of epigenetic signals in the neurogenic niches, where glial cells and neurons exert mutual influences. Unravelling the mechanisms that underlie NSC plasticity in vivo and in vitro is crucial to understanding adult neurogenesis and exploiting this physiological process for brain repair. In this review we address the issues of neuronal/glial cell identity and neuronal-glial interactions in the context of NSC biology and NSC-driven neurogenesis during development and adulthood in vivo, focusing mainly on the CNS. We also discuss the peculiarities of neuronal-glial relationships for NSCs and their progeny in the context of in vitro systems.     

Co-transplantation of bFGF-expressing amniotic epithelial cells and neural stem cells promotes functional recovery in spinal cord-injured rats

We have previously demonstrated that amniotic epithelial cells (AECs) can enhance survival and neural differentiation of neural stem cells (NSCs) when co-cultured in basal media. In addition, the presence of basic fibroblast growth factor (bFGF) enhances this AEC function. The aim of the present study was to extend those findings and investigate whether AECs modified with the bFGF gene will also enhance NSCs survival and neural differentiation in vivo and promote repair of the injured spinal cord. Female Wistar rats were used for a contusive spinal cord injury (SCI) model. Contusive SCIs were induced using a weight-drop device at levels T9-T11. Seven days following contusion, rats received grafts of NSCs only, NSCs with AECs/pLEGFP-hbFGF, or NSCs with AECs/pLEGFP-C1 into the injured region. Significant locomotor improvement was observed in the NSCs/AECs co-graft group beginning at 3 weeks compared with the NSCs or NaCl only groups. These results were confirmed and extended in an electrophysiological analysis. An immunohistological analysis revealed that AECs/pLEGFP-hbFGF promoted the survival (vs NaCl group: 194+/-9.17 vs 103.6+/-13.05) and neural differentiation (vs NaCl group: 14.24+/-1.11 vs 7+/-0.63) of co-transplanted NSCs. We also confirmed that AECs could promote the survival of host neurons. These results suggest that AECs/pLEGFP-hbFGF improve the NSCs survival and differentiation microenvironment and may be useful as a source of sustained trophic supported to improve NSCs differentiation into neurons in vivo. These findings suggest that a cograft of AECs/pLEGFP-hbFGF and NSCs may have benefits for SCI.     

In vivo fate analysis reveals the multipotent and self-renewal capacities of Sox2+ neural stem cells in the adult hippocampus

To characterize the properties of adult neural stem cells (NSCs), we generated and analyzed Sox2-GFP transgenic mice. Sox2-GFP cells in the subgranular zone (SGZ) express markers specific for progenitors, but they represent two morphologically distinct populations that differ in proliferation levels. Lentivirus- and retrovirus-mediated fate-tracing studies showed that Sox2+ cells in the SGZ have potential to give rise to neurons and astrocytes, revealing their multipotency at the population as well as at a single-cell level. A subpopulation of Sox2+ cells gives rise to cells that retain Sox2, highlighting Sox2+ cells as a primary source for adult NSCs. In response to mitotic signals, increased proliferation of Sox2+ cells is coupled with the generation of Sox2+ NSCs as well as neuronal precursors. An asymmetric contribution of Sox2+ NSCs may play an important role in maintaining the constant size of the NSC pool and producing newly born neurons during adult neurogenesis.     

Neural stem cells redefined

Using the generally accepted ontogenetic definition, neural stem cells (NSCs) are characterized as undifferentiated cells originating from the neuroectoderm that have the capacity both to perpetually self-renew without differentiating and to generate multiple types of lineage-restricted progenitors (LRP). LRPs can themselves undergo limited self-renewal, then ultimately differentiate into highly specialized cells that compose the nervous system. However, this physiologically delimited definition of NSCs has been increasingly blurred in the current state of the field, as the great majority of studies have retrospectively inferred the existence of NSCs based on their deferred functional capability rather than prospectively identifying the actual cells that created the outcome. Further complicating the matter is the use of a wide variety of neuroepithelial or neurosphere preparations as a source of putative NSCs, without due consideration that these preparations are themselves composed of heterogeneous populations of both NSCs and LRPs. This article focuses on recent attempts using FACS strategies to prospectively isolate NSCs from different types of LRPs as they appear in vivo and reveals the contrasting differences among these populations at molecular, phenotypic, and functional levels. Thus, the strategies presented here provide a framework for more precise studies of NSC and LRP cell biology in the future.     

Membrane properties of rat embryonic multipotent neural stem cells

We have characterized several potential stem cell markers and defined the membrane properties of rat fetal (E10.5) neural stem cells (NSC) by immunocytochemistry, electrophysiology and microarray analysis. Immunocytochemical analysis demonstrates specificity of expression of Sox1, ABCG2/Bcrp1, and shows that nucleostemin labels both progenitor and stem cell populations. NSCs, like hematopoietic stem cells, express high levels of aldehyde dehydrogenase (ALDH) as assessed by Aldefluor labeling. Microarray analysis of 96 transporters and channels showed that Glucose transporter 1 (Glut1/Slc2a1) expression is unique to fetal NSCs or other differentiated cells. Electrophysiological examination showed that fetal NSCs respond to acetylcholine and its agonists, such as nicotine and muscarine. NSCs express low levels of tetrodotoxin (TTX) sensitive and insensitive sodium channels and calcium channels while expressing at least three kinds of potassium channels. We find that gap junction communication is mediated by connexin (Cx)43 and Cx45, and is essential for NSC survival and proliferation. Overall, our results show that fetal NSCs exhibit a unique signature that can be used to determine their location and assess their ability to respond to their environment.     

Experimental Study on Trace Marking and Oncogenicity of Neural Stem Cells Derived from Bone Marrow

It has been well accredited that the neural stem cells (NSCs) derived from bone marrow stroma cells (BMSCs) can be used as the therapeutic application. However, their efficacy and safety in therapeutic application are uncertain. In this experiment, the trace marking and oncogenicity of NSCs derived from BMSCs (BMSCs-D-NSCs) were studied. The BMSCs were harvested by gradient centrifugation and cultured in "NSCs medium" in vitro. The verified CD133/Nestin-positive BMSCs-D-NSCs were then transplanted into nude mice to detect the oncogenicity, into the right lateral cerebral ventricle or right caudae putamen and substantia nigra to examine, whether the symptoms were improved in Parkinson's Disease (PD) models after transplantation, by both SPECT image assay of dopamine transporter (DAT) in corpus striatum and its average standard uptake value (SUVave) in corpus striatum and thalamus. Tissue samples and surviving model animals were studied at 1, 3, and 6 months post-transplantation. Before transplantation, the cells were labeled with BrdU or rAAV-GFP for the pathological sections, and with Feridex for the in vivo trace by MRI assay. The concanavalin A (ConA) agglutination test, stop-dependence test with soft agar, karyotype analysis of chromosome G zone in BMSCs-D-NSCs, and the nude mouse neoplasia test were also performed. The BrdU, rAAV-GFP or Feridex can be used as trace markers of BMSCs-D-NSCs during transplantation. The transplanted BMSCs-D-NSCs displayed neither toxicity nor neoplasia up to 6 months in vivo, but could play an important role in improving the symptoms of the animals with degenerative diseases like PD.