小鼠胚胎干细胞分化为血管内皮细胞的永生化研究

本文探讨了小鼠胚胎干细胞(ES细胞)诱导分化的血管内皮细胞永生化。在体外培养系统中,以维甲酸(RA)和转化生长因子-β1(TGF-β1)诱导小鼠胚胎干细胞(ES细胞)的拟胚体(EB)分化为“圆形细胞”和由这些“圆形细胞”组成的血管样结构。经光学和扫描电镜及免疫荧光等法分析检测,证明组成血管样结构的细胞具有专一性vWF荧光染色,表明是血管内皮样细胞。利用脂质体将人端粒酶催化亚基逆转录酶(hTERT)基因转染诱导分化中的“圆形细胞”。应用Dot-blot,RT-PCR,Western blot及免疫组织化学等方法分析、观察和证明了诱导分化的组成血管样结构的园形细胞和被hTERT基因转染的“圆形”细胞的形态和生物学特性。结果表明,携带hTERT基因的从ES细胞分化来的圆形细胞在体外可大量增殖,持续传代,95%具有血管内皮细胞的一些特有标志和管道化生长特性。因此,通过人端粒酶基因的转染途径可解决由ES细胞诱导分化而来的内皮细胞扩增和永生化问题,为构建组织工程化血管及其它人工血管的内皮化提供种子细胞来源打下基础。     

胚胎干细胞分化为血管内皮细胞的分子调控机制

胚胎干细胞在不同的诱导条件下具有多向分化的潜能,多种胞内外信号途径参与其分化过程的调控。现就胚胎干细胞向血管内皮细胞分化的诱导条件及分子机制做一综述,并阐明不同阶段的内皮前体细胞所表达的不同分子标志,同时提出胚胎干细胞在再生医学中的应用前景。     

小鼠胚胎干细胞体外分化形成新生血管的实验研究

目的探讨小鼠胚胎干细胞(ES)在体外向内皮细胞(ECs)分化并形成新生血管的条件及特点。方法分别建立二维和三维小鼠ES细胞分化体系,对分化细胞行血小板内皮细胞粘附分子(PECAM-1)免疫荧光染色和DiI-乙酰化低密度脂蛋白(DiI-Ac-LDL)标记,观察ECs分化及血管形成特点。结果在二维分化体系,ES细胞在无外源性生长因子存在的条件下可自发向ECs分化,ECs主要定位在分化细胞密集处,分化表现为:ECs呈集落样生长,不形成网状结构;ECs互相连接形成网状结构,PECAM-1免疫荧光染色证实为ECs网。在三维的悬浮拟胚体培养体系,ECs的分化不依赖于外源性生长因子,分化表现为条索状结构、管腔样结构及排列紊乱的细胞团三种形式。对该拟胚体的冷冻切片进行的三维图像重构显示,拟胚体中有大量的血管网形成。在三维的Ⅰ型胶原培养体系中,ES形成的拟胚体表现为出芽式血管新生,这一过程依赖于外源性生长因子混合物。结论在二维和三维ES细胞分化体系中,ECs分化及新生血管形成过程与体内相似,表现为血管生成和血管新生两种形式,因此可作为研究血管发育机制的理想模型。     

诱导小鼠胚胎干细胞在体外分化为骨骼肌细胞的实验研究

小鼠胚胎干细胞是从胚泡未分化的内部细胞团中得到的干细胞,它在体外培养的环境中具有无限增殖、自我更新以及多向分化的特性。将小鼠胚胎干细胞在体外诱导分化为肌肉细胞,并且利用这些分化得来的肌肉细胞治疗肌肉退行性疾病,是干细胞研究领域的热点。该实验的目的在于筛选小鼠胚胎干细胞向骨骼肌细胞定向分化的实验条件,有效地将体外单层贴壁培养的小鼠胚胎干细胞诱导分化成骨骼肌细胞。最终发现,10-8mol/L维甲酸(retinoid acid,RA)+0.5%二甲基亚砜(dimethyl sulfoxide,DMSO)组诱导小鼠胚胎干细胞在体外分化成骨骼肌前体细胞的效率最高,分化得到的骨骼肌前体细胞经进一步纯化,能分化为多核的肌管。该实验为治疗肌肉退行性疾病提供了细胞来源,也为研究小鼠胚胎干细胞分化为骨骼肌细胞的机制提供了有利的条件。     

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。     

小鼠胚胎干细胞建系技术研究进展

目前,对小鼠胚胎干细胞的研究较为深入,并已成为研究细胞分化及信号转导、新基因发现及功能鉴定、器官发生、人类疾病和药物开发等的有效手段。胚胎干细胞建系是一项基础性工作。虽然技术日趋成熟,有些品系小鼠的胚胎干细胞建系已是常规技术,但不同品系小鼠胚胎干细胞的建系效率仍有很大差异,建系途径和方法各有特点,一个品系胚胎干细胞的建系方法不一定都适用于其他品系。本文从小鼠胚胎干细胞建系的途径、分离操作技术、培养体系等方面进行综述,并就与之相关的有些问题提出思考和对策。     

胚胎干细胞的诱导分化研究

胚胎干细胞(embryonic stem cell, ES细胞)是指由胚胎内细胞团(inner cell mass, ICM)细胞经体外抑制培养而筛选得到的细胞, 具有发育上的全能性. 近两年在ES细胞诱导分化方面的研究取得了一些突破性的进展, 其中, ES细胞向生殖细胞分化(2003年)以及首次克隆成功人ES细胞(2004年)先后被评为《科学》杂志当年度十大科学进展之一; 另外, 维持ES细胞不分化状态的关键基因(Nanog)及相关化合物(BIO)的发现, 其自身分化状态调控机理的深入研究, 以及向不同方向诱导分化和应用等的研究成果, 同样受人关注.     

齐墩果酸诱导多种小鼠胚胎干细胞向生殖细胞方向分化研究

目的：寻找一种能诱导多种胚胎干细胞向生殖细胞方向分化的化合物,并以常用的诱导物维甲酸（Retinoic Acid, RA）作为阳性参照物。方法：分别培养小鼠胚胎干细胞1 B10、D3、R1／E,诱导它们形成拟胚体,让拟胚体贴壁生长,加入特定化合物诱导贴壁细胞分化,诱导72 h后,提取被诱导细胞的RNA,再合成cDNA,最后利用实时荧光定量PCR检测各被诱导细胞中与生殖分化相关的基因的表达水平的变化。结果：发现齐墩果酸（Oleanolic Acid,OA）显著上调了所有被研究的小鼠胚胎干细胞的生殖分化关键基因的表达水平,同时发现阳性参照物RA仅能诱导1 B10、R1／E ,而不能诱导D3向生殖细胞方向分化。结论：OA能诱导多种胚胎干细胞向生殖细胞方向分化,诱导能力方面具有比常用诱导物维甲酸更广泛的普遍性。     

Tissue engineering of blood vessels with endothelial cells differentiated from mouse embryonic stem cells

Endothelial cells (TEC3 cells) derived from mouse embryonic stem (ES) cells were used as seed cells to construct blood vessels. Tissue engineered blood vessels were made by seeding 8 X 106 smooth muscle cells (SMCs) ob-tained from rabbit arteries onto a sheet of nonwoven polyglycolic acid (PGA) fibers, which was used as a biode-gradable polymer scaffold. After being cultured in DMEM medium for 7 days in vitro, SMCs grew well on the PGA fibers, and the cell-PGA sheet was then wrapped around a silicon tube, and implanted subcutaneously into nude mice. After 6～8 weeks, the silicon tube was replaced with another silicon tube in smaller diameter, and then the TEC3 cells (endothelial cells differentiated from mouse ES cells) were injected inside the engineered vessel tube as the test group. In the control group only culture medium was injected. Five days later, the engineered vessels were harvested for gross observation, histological and immunohistochemical analysis. The preliminary results demonstrated that the SMC-PGA construct could form a tubular structure in 6-8 weeks and PGA fibers were completely degraded. Histological and immunohistochemical analysis of the newly formed tissue revealed a typical blood vessel structure, including a lining of endothelial cells (ECs) on the lumimal surface and the presence of SMC and collagen in the wall. No EC lining was found in the tubes of control group. Therefore, the ECs differentiated from mouse ES cells can serve as seed cells for endothelium lining in tissue engineered blood vessels.     

Presynaptic dopaminergic properties of differentiated mouse embryonic stem cells

This study characterized the presynaptic dopaminergic properties of neuronally differentiated mouse embryonic stem (ES) cells. Approximately 30% of the ES cells expressed tyrosine hydroxylase (TH) immunoreactivity when co-cultured with PA6 cells. These cultures expressed high affinity, sodium-dependent dopamine uptake as well as depolarization-induced and calcium-dependent dopamine release of this transmitter. These and other important dopaminergic genes found expressed in these cultures by RT-PCR included Nurr1, vesicular monoamine transporter 2 (VMAT2), TH, dopamine transporter (DAT), and glial cell line-derived neurotrophic factor (GDNF) receptors c-Ret and GFRalpha1. These results demonstrate that differentiated ES cells have the presynaptic functions for maintaining dopaminergic homeostasis, which may be essential for their long-term use in restoring CNS levels of this transmitter.     

Cells differentiated from mouse embryonic stem cells via embryoid bodies express renal marker molecules

Differentiation of mouse embryonic stem (ES) cells via embryoid bodies (EB) is established as a suitable model to study cellular processes of development in vitro. ES cells are known to be pluripotent because of their capability to differentiate into cell types of all three germ layers including germ cells. Here, we show that ES cells differentiate into renal cell types in vitro. We found that genes were expressed during EB cultivation, which have been previously described to be involved in renal development. Marker molecules characteristic for terminally differentiated renal cell types were found to be expressed predominantly during late stages of EB cultivation, while marker molecules involved in the initiation of nephrogenesis were already expressed during early steps of EB development. On the cellular level--using immunostaining--we detected cells expressing podocin, nephrin and wt-1, characteristic for differentiated podocytes and other cells, which expressed Tamm-Horsfall protein, a marker for distal tubule epithelial cells of kidney tissue. Furthermore, the proximal tubule marker molecules renal-specific oxido reductase, kidney androgen-related protein and 25-hydroxyvitamin D3alpha-hydroxylase were found to be expressed in EBs. In particular, we could demonstrate that cells expressing podocyte marker molecules assemble to distinct ring-like structures within the EBs. Because the differentiation efficiency into these cell types is still relatively low, application of fibroblast growth factor (FGF)-2 in combination with leukaemia inhibitory factor was tested for induction, but did not enhance ES cell-derived renal differentiation in vitro.     

Chondrocytes derived from mouse embryonic stem cells

Our knowledge of cellular differentiation processes during chondro- and osteogenesis, in particular the complex interaction of differentiation factors, is still limited. We used the model system of embryonic stem (ES) cell differentiation in vitro via cellular aggregates, so called embryoid bodies (EBs), to analyze chondrogenic and osteogenic differentiation. ES cells differentiated into chondrocytes and osteocytes throughout a series of developmental stages resembling cellular differentiation events during skeletal development in vivo. A lineage from pluripotent ES cells via mesenchymal, prechondrogenic cells, chondrocytes and hypertrophicchondrocytes up to osteogenic cells was characterized. Furthermore, we found evidence for another osteogenic lineage, bypassing the chondrogenic stage. Together our results suggest that this in vitro system will be helpful to answer so far unacknowledged questions regarding chondrogenic and osteogenic differentiation. For example, we isolated an as yet unknown cDNA fragment from ES cell-derived chondrocytes, which showed a developmentally regulated expression pattern during EB differentiation. Considering ES cell differentiation as an alternative approach for cellular therapy, we used two different methods to obtain pure chondrocyte cultures from the heterogenous EBs. First, members of the transforming growth factor (TGF)-β family were applied and found to modulate chondrogenic differentiation but were not effective enough to produce sufficient amounts of chondrocytes. Second, chondrocytes were isolated from EBs by micro-manipulation. These cells initially showed dedifferentiation into fiboblastoid cells in culture, but later redifferentiated into mature chondrocytes. However, a small amount of chondrocytes isolated from EBs transdifferentiated into other mesenchymal cell types, indicating that chondrocytes derived from ES cells posses a distinct differentiation plasticity. This revised version was published online in July 2006 with corrections to the Cover Date.     

Proteomic identification of differentially expressed genes in mouse neural stem cells and neurons differentiated from embryonic stem cells in vitro

Embryonic stem (ES) cells are pluripotent stem cells and give rise to a variety of differentiated cell types including neurons. To study a molecular basis for differentiation from ES cells to neural cells, we searched for proteins involved in mouse neurogenesis from ES cells to neural stem (NS) cells and neurons by two-dimensional gel electrophoresis (2-DE) and peptide mass fingerprinting, using highly homogeneous cells differentiated from ES cells in vitro. We newly identified seven proteins with increased expression and one protein with decreased expression from ES cells to NS cells, and eight proteins with decreased expression from NS cells to neurons. Western blot analysis confirmed that a tumor-specific transplantation antigen, HS90B, decreased, and an extracellular matrix and membrane glycoprotein (such as laminin)-binding protein, galectin 1 (LEG1), increased in NS cells, and LEG1 and a cell adhesion receptor, laminin receptor (RSSA), decreased in neurons. The results of RT-PCR showed that mRNA of LEG1 was also up-regulated in NS cells and down-regulated in neurons, implying an important role of LEG1 in regulating the differentiation. The differentially expressed proteins identified here provide insight into the molecular basis of neurogenesis from ES cells to NS cells and neurons.     

Generation of insulin-expressing cells from mouse embryonic stem cells

The therapeutic potential of transplantation of insulin-secreting pancreatic beta-cells has stimulated interest in using pluripotent embryonic stem (ES) cells as a starting material from which to generate insulin secreting cells in vitro. Mature beta-cells are endodermal in origin so most reported differentiation protocols rely on the identification of endoderm-specific markers. However, endoderm development is an early event in embryogenesis that produces cells destined for the gut and associated organs in the embryo, and for the development of extra-embryonic structures such as the yolk sac. We have demonstrated that mouse ES cells readily differentiate into extra-embryonic endoderm in vitro, and that these cell populations express the insulin gene and other functional elements associated with beta-cells. We suggest that the insulin-expressing cells generated in this and other studies are not authentic pancreatic beta-cells, but may be of extra-embryonic endodermal origin.     

The pro-inflammatory signature of lipopolysaccharide in spontaneous contracting embryoid bodies differentiated from mouse embryonic stem cells

Embryonic stem (ES) cells differentiate towards all three germ layers, including cardiac cells and leukocytes, and may be therefore suitable to model inflammatory reactions in vitro. In the present study, embryoid bodies differentiated from mouse ES cells were treated with increasing doses of lipopolysaccharide (LPS) to mimic infection with gram-negative bacteria. LPS treatment dose-dependent increased contraction frequency of cardiac cell areas and calcium spikes and increased protein expression of α-actinin. LPS treatment increased the expression of the macrophage marker CD68 and CD69, which is upregulated after activation on T cells, B cells and NK cells. LPS dose-dependent increased protein expression of toll-like receptor 4 (TLR4). Moreover, upregulation of NLR family pyrin domain containing 3 (NLRP3), IL-1ß and cleaved caspase 1 was observed, indicating activation of inflammasome. In parallel, generation of reactive oxygen species (ROS), nitric oxide (NO), and expression of NOX1, NOX2, NOX4 and eNOS occurred. ROS generation, NOX2 expression and NO generation were downregulated by the TLR4 receptor antagonist TAK-242 which abolished the LPS-induced positive chronotropic effect of LPS. In conclusion, our data demonstrate that LPS induced a pro-inflammatory cellular immune response in tissues derived from ES cells, recommending the in vitro model of embryoid bodies for inflammation research.     

Cloned transgenic mouse fetuses from embryonic stem cells

Development of efficient efficient system for genetic modification and large-scale cloning of livestock is of importance for agriculture, biotechnology, or human medicine. The mouse, on the other hand, is an ideal model in the basic studies of genetic modification. In this study, we investigated about production of clone mice from established embryonic stem (ES) cell line by nuclear transfer. Further, we had try of production of cloned transgenic mouse fetuses/offspring using ES cells modified with a marker gene, EGFP. With the ES cell line TT2 which is at least 15 passages, reconstructed oocytes developed to 2-8 cell embryos, morulae, or blastocysts (44.8%), and 17.2% of them developed to term (19.5 days post-coitum, dpc). When 40 embryos with the marker gene transferred to 11 surrogate mothers (pseudopregnant females), 5 live fetuses were recognized in the uteli at 13.5 dpc and in these fetuses expression of GFP was observed, but none developed beyond 19.5 dpc. The present results suggest that ES cells can be used tg produce cloned mice.     

Directed differentiation of dendritic cells from mouse embryonic stem cells

Dendritic cells (DCs) are uniquely capable of presenting antigen to naive T cells, either eliciting immunity [1] or ensuring self-tolerance [2]. This property identifies DCs as potential candidates for enhancing responses to foreign [3] and tumour antigens [4], and as targets for immune intervention in the treatment of autoimmunity and allograft rejection [1]. Realisation of their therapeutic potential would be greatly facilitated by a fuller understanding of the function of DC-specific genes, a goal that has frequently proven elusive because of the paucity of stable lines of DCs that retain their unique properties, and the inherent resistance of primary DCs to genetic modification. Protocols for the genetic manipulation of embryonic stem (ES) cells are, by contrast, well established [5], as is their capacity to differentiate into a wide variety of cell types in vitro, including many of hematopoietic origin [6]. Here, we report the establishment, from mouse ES cells, of long-term cultures of immature DCs that share many characteristics with macrophages, but acquire, upon maturation, the allostimulatory capacity and surface phenotype of classical DCs, including expression of CD11c, major histocompatibility complex (MHC) class II and co-stimulatory molecules. This novel source should prove valuable for the generation of primary, untransformed DCs in which candidate genes have been overexpressed or functionally ablated, while providing insights into the earliest stages of DC ontogeny.     

Paracrine factors of vascular endothelial cells facilitate cardiomyocyte differentiation of mouse embryonic stem cells

For myocardial regeneration therapy, the low differentiation capability of functional cardiomyocytes sufficient to replace the damaged myocardial tissue is one of the major difficulties. Using Nkx2.5-GFP knock-in ES cells, we show a new efficient method to obtain cardiomyocytes from embryonic stem (ES) cells. The proportion of GFP-positive cells was significantly increased when ES cells were cultured with a conditioned medium from aortic endothelial cells (ECs), accompanied by upregulation of cardiac-specific genes as well as other mesodermal genes. The promotion was more prominent when EC-conditioned medium was added at an early stage of ES cell differentiation culture (Day 0-3). Inhibitors of bone morphogenic protein (BMP), cyclooxygenase (COX), and nitric oxide synthetase (NO) prevented the promotion of cardiomyogenesis by EC-conditioned medium. These results suggest that supplementation of EC-conditioned medium enables cardiomyocytes to be obtained efficiently through promotion of mesoderm induction, which is regulated by BMP, COX, and NOS.