诱导体外培养小鼠胚胎干细胞分化为心肌细胞方法的研究

目的:采用布法罗大鼠肝细胞条件培养基代替重组LIF,建立在不加任何化学诱导剂的情况下诱导体外培养小鼠胚胎干细胞(ES细胞)分化为心肌细胞的方法。方法:在诱导分化实验前,应用BRL条件培养基来维持ES细胞生长和抑制其分化,并采取将悬滴培养法和聚集培养法结合起来,分三步诱导ES细胞分化的方法。结果:分化细胞中可见节律性收缩的细胞,经超微结构分析和免疫细胞学鉴定为心肌细胞。结论:本法无需添加化学诱导剂,为一种简便、经济的诱导体外培养小鼠ES细胞分化为心肌细胞的方法。     

Multilineage differentiation from human embryonic stem cell lines

Stem cells are unique cell populations with the ability to undergo both self-renewal and differentiation. A wide variety of adult mammalian tissues harbors stem cells, yet "adult" stem cells may be capable of developing into only a limited number of cell types. In contrast, embryonic stem (ES) cells, derived from blastocyst-stage early mammalian embryos, have the ability to form any fully differentiated cell of the body. Human ES cells have a normal karyotype, maintain high telomerase activity, and exhibit remarkable long-term proliferative potential, providing the possibility for unlimited expansion in culture. Furthermore, they can differentiate into derivatives of all three embryonic germ layers when transferred to an in vivo environment. Data are now emerging that demonstrate human ES cells can initiate lineage-specific differentiation programs of many tissue and cell types in vitro. Based on this property, it is likely that human ES cells will provide a useful differentiation culture system to study the mechanisms underlying many facets of human development. Because they have the dual ability to proliferate indefinitely and differentiate into multiple tissue types, human ES cells could potentially provide an unlimited supply of tissue for human transplantation. Though human ES cell-based transplantation therapy holds great promise to successfully treat a variety of diseases (e.g., Parkinson's disease, diabetes, and heart failure) many barriers remain in the way of successful clinical trials.     

Collection of neural inducing factors from PA6 cells using heparin solution and their immobilization on plastic culture dishes for the induction of neurons from embryonic stem cells

Embryonic stem (ES) cells have the ability to replicate themselves and differentiate into various mature cells. Recently, dopaminergic neurons were efficiently induced from ES cells using mouse stromal cells (PA6 cells) as a feeder cell layer. This simple procedure seems to be very efficient to obtain dopamine-releasing cells for future clinical cell transplantation treatment of Parkinson's disease. In this study, we prepared stock solutions containing neural inducing factors (NIFs) by washing PA6 cells with phosphate-buffered saline containing heparin. ES cells grew successfully in culture media supplemented with 33 v/v% NIFs stock solution, and the rate of neural differentiation of ES cell progeny increased with increasing heparin concentration in the culture media. In addition, NIFs-immobilized surfaces were prepared by exposing polyethyleneimine-modified surfaces to NIFs stock solutions. The NIFs-immobilized culture dish effectively supported cell growth as the culture medium supplemented with NIFs stock did, but its induction effect to dopaminergic neurons from ES cells was much smaller than free NIFs. NIFs stock solutions have two different activities. One can stimulate cell growth and the other induces differentiation of ES cells to the neural fate when heparin existed. The former factors were effectively immobilized on the culture dish, but those that induce differentiation may not be. Further optimization is required.     

Molecular Pathways Governing Development of Vascular Endothelial Cells from ES/iPS Cells

Assembly of complex vascular networks occurs in numerous biological systems through morphogenetic processes such as vasculogenesis, angiogenesis and vascular remodeling. Pluripotent stem cells such as embryonic stem (ES) and induced pluripotent stem (iPS) cells can differentiate into any cell type, including endothelial cells (ECs), and have been extensively used as in vitro models to analyze molecular mechanisms underlying EC generation and differentiation. The emergence of these promising new approaches suggests that ECs could be used in clinical therapy. Much evidence suggests that ES/iPS cell differentiation into ECs in vitro mimics the in vivo vascular morphogenic process. Through sequential steps of maturation, ECs derived from ES/iPS cells can be further differentiated into arterial, venous, capillary and lymphatic ECs, as well as smooth muscle cells. Here, we review EC development from ES/iPS cells with special attention to molecular pathways functioning in EC specification.     

Hepatic differentiation of mouse embryonic stem cells and induced pluripotent stem cells during organoid formation in hollow fibers

We have focused on pluripotent stem cells as a potential source of a hybrid-type artificial liver (HAL) and tried to develop a method for differentiating the pluripotent stem cells into cells of a hepatic lineage. In this study, we investigated the hepatic differentiation of mouse embryonic stem (ES) cells and induced pluripotent stem (iPS) cells by applying hollow fiber (HF)/organoid culture method, in which cultured cells form a cellular aggregate called an "organoid" in the lumen of the HF. ES and iPS cells were injected into HFs to induce organoid formation, and cells were cultured. To induce hepatic differentiation, we added differentiation-promoting agents to the culture medium. The expression levels of differentiation-related genes were up-regulated, with cell proliferation and organoid formation inside HFs. Since we were able to achieve a high cell density in culture, the maximum levels of liver-specific functions per unit volume in the differentiating ES and iPS cells reached a level comparable to or better than that of primary mouse hepatocytes. In conclusion, ES and iPS cells have the potential to be a cell source for a HAL, and the HF/organoid culture method, therefore, has promise as a basic technology for the development of a HAL.     

Collagen IV induces trophoectoderm differentiation of mouse embryonic stem cells

The earliest segregation of lineages in the developing embryo is the commitment of cells to the inner cell mass or the trophoectoderm in preimplantation blastocysts. The exogenous signals that control commitment to a particular cell lineage are poorly understood; however, it has been suggested that extracellular "niche" and extracellular matrix, in particular, play an important role in determining the developmental fate of stem cells. Collagen IV (ColIV) has been reported to direct embryonic stem (ES) cell differentiation to mesodermal lineages in both mouse and human ES cells. To define the effects of ColIV on ES cell differentiation and to identify the resulting heterogeneous cell types, we performed microarray analyses and determined global gene expression. We observed that ColIV induced the expression of mesodermal genes specific to hematopoietic, endothelial, and smooth muscle cells and, surprisingly, also a panel of trophoectoderm-restricted markers. This effect was specific to collagen IV, as no trophoblast differentiation was seen on collagen I, laminin, or fibronectin. Stimulation with basic fibroblast growth factor (FGF) or FGF4 increased the number of trophoectodermal cells. These cells were isolated under clonal conditions and successfully differentiated into a variety of trophoblast derivatives. Interestingly, differentiation of ES cells to trophoblastic lineages was only seen in ES cell lines maintained on embryonic feeder layers and was caudal-type homeobox protein 2 (Cdx2)-dependent, consistent with Cdx2's postulated role in trophoectoderm commitment. Our data suggest that, given the appropriate extracellular stimuli, mouse embryonic stem cells can differentiate into trophoectoderm. Disclosure of potential conflicts of interest is found at the end of this article.     

Double labeling of mRNA and protein markers in cultured embryoid bodies

Summary In vitro suspension cultures of embryonal carcinoma or embryonic stem cells (EC/ES) generate cell aggregates termed as embryoid bodies (EBs). EBs have been analyzed to study the mechanisms of cellular differentiation in vitro. The multipotency of EC/ES cells to differentiate into various cell types as well as the expression of many marker genes provides a valuable in vitro model system to study the mechanisms of cellular differentiation. Here we present a procedure for a mRNA detection of a specific gene using double labeling-mRNA probe and an antibody against cellular marker proteins. This double labeling analysis in combination with a culture of EBs provides a useful approach to analyze several mechanisms of cellular differentiation from multipotent EC/ES cells.     

Overexpression of Nodal promotes differentiation of mouse embryonic stem cells into mesoderm and endoderm at the expense of neuroectoderm formation

Understanding how to direct the fate of embryonic stem (ES) cells upon differentiation is critical to their eventual use in therapeutic applications. Clues for controlling ES cell differentiation may be found in the early embryo because mouse ES cells form derivatives of all three embryonic germ layers upon injection into blastocysts. One promising candidate for influencing the differentiation of ES cells into the embryonic germ layers is the transforming growth factor-beta (TGF-beta) growth factor, Nodal. Nodal null mouse mutants lack mesoderm, and injection of Nodal mRNA into nonmammalian embryos induces mesodermal and endodermal tissues. We find that overexpression of Nodal in mouse ES cells leads not only to up-regulation of mesodermal and endodermal cell markers but also to downregulation of neuroectodermal markers. These findings demonstrate the importance of Nodal's influence on the differentiation of pluripotent cells to all three of the primary germ layers. Accordingly, altering expression of factors responsible for cell differentiation in the intact embryo provides an approach for directing ES cell fates in vitro toward therapeutically useful cell types.     

A cDNA-based random RNA interference library for functional genetic screens in embryonic stem cells

To facilitate high-throughput functional genetic screens in embryonic stem cells, a simple and efficient system to construct cDNA-based random RNA interference (RNAi) library was developed in the study. Previous studies have demonstrated that sequence-specific gene silencing could be induced by long double-stranded RNA (dsRNA) in mouse embryos, mouse oocytes, embryonic stem cells, and other mammalian cells. Based on these findings, a dsRNA-expressing RNAi vector system was designed. This study provided evidence that the vector design could induce efficient knockdown of expression of both exogenous egfp gene and endogenous MTM1 gene in mouse embryonic stem cells. A random RNAi library was established by cloning enzyme-digested cDNA of mouse embryonic stem (ES) cells into the BamHI site of the convergent dual promoter RNAi vector. Sequencing of 20 randomly selected clones from the library showed that 17 contained inserts and that all of them were unique sequences. A functional genetic screen of genes involving in self-renewal and differentiation with the random RNAi library identified ubiquitin. The ubiquitin knockdown ES cell line generated 20%-30% of undifferentiated colonies in the absence of leukemia inhibitor factor, whereas parental ES cells and control vector pDCont transfectants produced less than 5% of colonies of undifferentiated cells, suggesting that ubiquitin plays a role in ES cell differentiation. The random RNAi library provides a useful tool for investigation of molecular mechanisms of cellular development and differentiation.     

人胚胎干细胞接种在鼠尾胶原包被培养板上定向分化为血管内皮细胞

背景：胚胎干细胞在体外可诱导分化为血管内皮细胞,进而形成血管,因而成为血管组织工程理想的种子细胞来源之一。 目的：探讨建立定向诱导人胚胎干细胞向血管内皮细胞分化的方法。 方法：在小鼠胚胎成纤维细胞饲养层上培养人胚胎干细胞H1,将H1细胞团块转移到鼠尾胶原包被的培养板,贴壁24- 48 h后,培养基换为含不同辅助因子和内皮细胞生长添加剂的EGM-2内皮细胞培养基。 结果与结论：①在EGM-2内皮细胞培养基诱导下,细胞逐步表达内皮细胞特异性标记基因VEGFR-2、PECAM1、vWF、CD34、VE-cadherin、GATA-2。②分化细胞表达内皮细胞特异性标记VE-cadherin、CD31。③分化细胞具有吞噬低密度脂蛋白功能。说明将人胚胎干细胞接种在鼠尾胶原包被培养板上,通过EGM-2内皮培养体系诱导,可直接分化为功能性血管内皮细胞。为研究胞外基质对诱导胚胎干细胞血管内皮细胞分化的作用以及相关信号分子机制打下了基础。     

Embryonic stem cells: prospects for developmental biology and cell therapy

Stem cells represent natural units of embryonic development and tissue regeneration. Embryonic stem (ES) cells, in particular, possess a nearly unlimited self-renewal capacity and developmental potential to differentiate into virtually any cell type of an organism. Mouse ES cells, which are established as permanent cell lines from early embryos, can be regarded as a versatile biological system that has led to major advances in cell and developmental biology. Human ES cell lines, which have recently been derived, may additionally serve as an unlimited source of cells for regenerative medicine. Before therapeutic applications can be realized, important problems must be resolved. Ethical issues surround the derivation of human ES cells from in vitro fertilized blastocysts. Current techniques for directed differentiation into somatic cell populations remain inefficient and yield heterogeneous cell populations. Transplanted ES cell progeny may not function normally in organs, might retain tumorigenic potential, and could be rejected immunologically. The number of human ES cell lines available for research may also be insufficient to adequately determine their therapeutic potential. Recent molecular and cellular advances with mouse ES cells, however, portend the successful use of these cells in therapeutics. This review therefore focuses both on mouse and human ES cells with respect to in vitro propagation and differentiation as well as their use in basic cell and developmental biology and toxicology and presents prospects for human ES cells in tissue regeneration and transplantation.     

Sonic hedgehog and other soluble factors from differentiating embryoid bodies inhibit pancreas development

Success of cell-replacement therapy for diabetes will largely depend on the establishment of alternative sources of pancreatic islet grafts. Embryonic stem (ES) cell differentiation toward pancreatic insulin-producing cells offers such perspectives, but there are still many challenges to overcome. Our previous studies suggested that the limited amount of insulin-positive cells derived from ES cells is related to the activation of pancreas inhibitory signals. To confirm this hypothesis, we report here that exposure of mouse embryonic pancreas explants to soluble factors from embryoid bodies (EBs) inhibits growth, morphogenesis, and endocrine and exocrine differentiation as evaluated by explant size and mRNA and protein expression. Sonic Hedgehog (Shh), an established pancreas repressor both at early and late developmental stages, was produced and secreted by EBs, and participated in the inhibitory effect by inducing its target Gli1 in the explants. Inhibition of Hedgehog pathway rescued the differentiation of Insulin-positive cells in the explants. In contrast to pancreatic cells, hepatic progenitors exposed to EB-conditioned medium showed improved differentiation of albumin-positive cells. In a model system of ES cell differentiation in vitro, we found that definitive endoderm induction by serum removal or activin A treatment further increased Hedgehog production and activity in EBs. Concomitantly, downregulation of the pancreas marker Pdx1 was recorded in activin-treated EBs, a phenomenon that was prevented by antagonizing Hedgehog signaling with Hedgehog interacting protein. These data strongly suggest that Hedgehog production in EBs limits pancreatic fate acquisition and forms a major obstacle in the specification of pancreatic cells from ES-derived definitive endoderm. Disclosure of potential conflicts of interest is found at the end of this article.     

The differentiation of embryonic stem cells seeded on electrospun nanofibers into neural lineages

Due to advances in stem cell biology, embryonic stem (ES) cells can be induced to differentiate into a particular mature cell lineage when cultured as embryoid bodies. Although transplantation of ES cells-derived neural progenitor cells has been demonstrated with some success for either spinal cord injury repair in small animal model, control of ES cell differentiation into complex, viable, higher ordered tissues is still challenging. Mouse ES cells have been induced to become neural progenitors by adding retinoic acid to embryoid body cultures for 4 days. In this study, we examine the use of electrospun biodegradable polymers as scaffolds not only for enhancing the differentiation of mouse ES cells into neural lineages but also for promoting and guiding the neurite outgrowth. A combination of electrospun fiber scaffolds and ES cells-derived neural progenitor cells could lead to the development of a better strategy for nerve injury repair.     

The effect of recombinant E-cadherin substratum on the differentiation of endoderm-derived hepatocyte-like cells from embryonic stem cells

Generation of specific lineages of cells from embryonic stem (ES) cells is pre-requisite to use these cells in pre-clinical applications. Here, we developed a recombinant E-cadherin substratum for generation of hepatic progenitor populations at single cell level. This artificial acellular feeder layer supports the stepwise differentiation of ES cells to cells with characteristics of definitive endoderm, hepatic progenitor cells, and finally cells with phenotypic and functional characteristics of hepatocytes. The efficient differentiation of hepatic endoderm cells (approximately 55%) together with the absence of neuroectoderm and mesoderm markers suggests the selective induction of endoderm differentiation. The co-expression of E-cahderin and alpha-fetoprotein (approximately 98%) suggests the important role of E-cadherin as a surface marker for the enrichment of hepatic progenitor cells. With extensive expansion, approximately 92% albumin expressing cells can be achieved without any enzymatic stress and cell sorting. Furthermore, these mouse ES cell-derived hepatocyte-like cells showed higher morphological similarities to primary hepatocytes. In conclusion, we demonstrated that E-cadherin substratum can guide differentiation of ES cells into endoderm-derived hepatocyte-like cells. This recombinant extracellular matrix could be effectively used as an in vitro model for studying the mechanisms of early stages of liver development even at single cell level.