The absence of SIR2alpha protein has no effect on global gene silencing in mouse embryonic stem cells

The yeast sir2 gene plays a central role in mediating gene silencing and DNA repair in this organism. The mouse sir2alpha gene is closely related to its yeast homologue and encodes a nuclear protein expressed at particularly high levels in embryonic stem (ES) cells. We used homologous recombination to create ES cells null for sir2alpha and found that these cells did not have elevated levels of acetylated histones and did not ectopically express silent genes. Unlike yeast sir2 mutants, our sir2alpha null ES cells had normal sensitivity to insults such as ionizing radiation and heat shock, and they were able to silence invading retroviruses normally. These sir2alpha null cells were able to differentiate in culture normally. Our results failed to provide evidence that the mammalian SIR2alpha protein plays a role in gene silencing and suggest that the physiological substrate(s) for the SIR2alpha deacetylase may be nuclear proteins other than histones.     

Spontaneous differentiation of mouse embryonic stem cells in vitro: characterization by global gene expression profiles

We characterized the temporal gene expression changes during four weeks of spontaneous differentiation of mouse ES cells in a monolayer culture in order to obtain better insight into the differentiation process. The overall gene expression pattern was changed dramatically during the first two weeks of spontaneous differentiation, but stabilized after the second week. Most of the genes regulated within the first two weeks of spontaneous differentiation were genes related to development including morphogenesis, cell differentiation, embryonic development, pattern specification, mesoderm development, post-embryonic development, and blastocyst development. While most of the ectoderm lineage related genes were down-regulated, genes related to the mesoderm or endoderm lineage were up-regulated through the first week and second week, respectively. This study revealed that the development of ectoderm lineage is a recessive process during the spontaneous differentiation of mouse ES cells in monolayer culture. Our time-course characterization might provide a useful time line for directed differentiation of mouse ES cells.     

In vitro differentiation and maturation of mouse embryonic stem cells into hepatocytes

It is difficult to induce the maturation of embryonic stem (ES) cells into hepatocytes in vitro. We previously reported that Thy1-positive mesenchymal cells derived from the mouse fetal liver promote the maturation of hepatic progenitor cells. Here, we isolated alpha-fetoprotein (AFP)-producing cells from mouse ES cells for subsequent differentiation into hepatocytes in vitro by coculture with Thy1-positive cells. ES cells expressing green fluorescent protein (GFP) under the control of an AFP promoter were cultured under serum- and feeder layer-free culture conditions. The proportion of GFP-positive cells plateaued at 41.6 +/- 12.2% (means +/- SD) by day 7. GFP-positive cells, isolated by flow cytometry, were cultured in the presence or absence of Thy1-positive cells as a feeder layer. Isolated GFP-positive cells were stained for AFP, Foxa2, and albumin. The expression of mRNAs encoding tyrosine amino transferase, tryptophan 2,3-dioxygenase, and glucose-6-phosphatase were only detected following coculture with Thy1-positive cells. Following coculture with Thy1-positive cells, the isolated cells produced and stored glycogen. Ammonia clearance activity was also enhanced following coculture. Electron microscopic analysis indicated that the cocultured cells exhibited the morphologic features of mature hepatocytes. In conclusion, coculture with Thy1-positive cells in vitro induced the maturation of AFP-producing cells isolated from ES cell cultures into hepatocytes.     

The effect of extracellular matrix on the differentiation of mouse embryonic stem cells

Embryonic stem cells (ESCs) are promising research materials to investigate cell fate determination since they have the capability to differentiate. Stem cell differentiation has been extensively studied with various microenvironment mimicking structures to modify cellular dynamics associated with the cell-extracellular matrix (ECM) interactions and cell-cell communications. In the current study, our aim was to determine the effect of microenvironmental proteins with different concentrations on the capacity and differentiation capability of mouse ESCs (mESCs), combining the biochemical assays, imaging techniques, Fourier transform infrared (FTIR) spectroscopy, and unsupervised multivariate analysis. Based on our data, coating the surface of mESCs with Matrigel, used as an acellular matrix substrate, resulted in morphological and biochemical changes. mESCs exhibited alterations in their phenotype after growing on the Matrigel-coated surfaces, including their differentiation capacity, cell cycle phase pattern, membrane fluidity, and metabolic activities. In conclusion, mESCs can be stimulated physiologically, chemically, or mechanically to convert them a new phenotype. Thus, identification of ESCs’ behavior in the acellular microenvironment could be vital to elucidate the mechanism of diseases. It might also be promising to control the cell fate in the field of tissue engineering.     

Lithium influences differentiation and tissue-specific gene expression of mouse embryonic stem (ES) cells in vitro

The effects of lithium chloride (LiCl) on differentiation of mouse embryonic stem (ES) cells were investigated in order to evaluate the ES cell test (EST) used in a European Union validation study for screening of embryotoxic agents in vitro. We show that LiCl inhibited concentration-dependently the differentiation of ES cells into cardiac and myogenic cells. Whereas the inhibition of cardiac differentiation by high concentrations of LiCl was obvious at day 5 + 5, decreased skeletal muscle cell differentiation was observed only at day 5 + 8. Semi-quantitative RT-PCR analyses revealed significantly lower levels of mRNA encoding cardiac-specific alpha-myosin heavy chain and skeletal muscle-specific myoD. By morphological investigation, an influence of lithium on neuronal differentiation was not evident. However, mRNA levels of genes encoding synaptophysin and the 160 kDa neurofilament protein were increased by high LiCl concentrations, whereas mRNA levels of mash-1 and Engrailed-1 were decreased, suggesting a specific influence of lithium on neuronal differentiation. Furthermore, LiCl treatment resulted in a slight, but non-significant increase of beta-catenin levels in ES cell-derived embryoid bodies. Our results demonstrate that the ES cell test, EST may be suitable to detect inhibitory effects of test compounds especially on cardiac differentiation, whereas effects on neuronal cells would not be detected. Therefore, we propose that morphological analyses of cardiac differentiation alone are insufficient to detect embryotoxic effects. The assay of other cell lineages at different developmental stages, and expression analyses of tissue-specific genes should also be employed.     

In vitro differentiation of mouse embryonic stem cells after activation by retinoic acid

Embryonic stem (ES) cells are pluripotent cells isolated from the inner cell mass of blastocysts. ES cells are able to differentiate into the three primitive layers (endoderm, mesoderm, and ectoderm) of the organism, including the germline. In recent reports mouse ES cells have been successfully applied in the treatment of spinal cord injury, hereditary myelin disorder of the central nervous system, and diabetes mellitus. In this study, we investigated the induction of mouse ES cell differentiation, using culture of embryoid bodies (EBs) into the diverse tissues. EBs were formed by culturing ES cells (129/SV strain) in DMEM supplemented with 10% FBS, in the absence of feeder cells and leukemia inhibitory factor (LF). EBs were induced to differentiate by treatment with retinoic acid (RA). In control medium (non-RA medium) beating muscles, blood vessels, hemocytes, and cartilages were frequently observed in EBs. Moreover, when EBs were cultured in medium including RA (5 x 10(-8) M, and 5 x 10(-9) M), differentiation of the optic vesicle, lens, retina, and neural groove was observed. In this study we demonstrated that an efficient system for inducing the differentiation of ES cells using EBs.     

Osteoblastic differentiation of monkey embryonic stem cells in vitro

Monkey embryonic stem (ES) cell is a useful tool for preclinical studies of regenerative medicine. In this paper, we investigated whether monkey ES cells can be differentiated into osteoblasts in vitro using factors known to promote osteogenesis. We prepared embryoid bodies (EB) in the presence of retinoic acid (RA) and subsequently differentiated in the medium containing either dexamethasone (DEX) or bone morphogenetic protein (BMP)-2 in addition to osteogenic supplements (OS), specifically ascorbic acid and beta-glycerophosphate. RA treatment during EB formation induced osteoblastic marker genes, such as collagen type 1, osteopontin, and Cbfa1. For the expression of osteocalcin, however, cultivation with medium containing either DEX or BMP-2 in addition to OS was required. These results showed that osteoblasts could be derived from monkey ES cells in vitro and BMP-2 + OS was effective to induce calcification.     

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.     

In vitro differentiation of male mouse embryonic stem cells into both presumptive sperm cells and oocytes

Pioneer work in male mouse embryonic stem (ES) cells differentiation into germ cells (GC) showed generations of male or female gametes in separate experiments, using genetically manipulated or preselected ES cells. In an attempt to produce both types of gametes from male mouse ES cells without any genetic manipulation or preselection, we induce the differentiation by retinoic acid (RA) within nonadherent embryoid bodies (EB). It seems that gamete-like cell formation occurs in the correct manner based on the expression of early and late GC-specific genes such as Oct-4, Mvh, Stella, Dazl, Piwil 2, Pdrd 1, Rex 14, Rnf 17, Bmp8b, Acrosin, Stra-8, Haprin, LH-R, Gdf9, Zp3, Zp2, Sycp1, and Sycp3. Immunofluorescence analysis of morphologically well-formed GC and presumptive gametes showed positive labeling for SSEA1, Oct-4, EMA-1, FE-J1, Dazl, Fragilis, Mvh, Acrosin, and acetylated alpha-tubulin. Conventional cytogenetic and FISH analysis indicated a chromosome reduction in ES-derived GC. Our data suggest that ES cells with XY chromosomes can produce under the same experimental conditions both types of presumptive gametes, and this production depends on their positional and temporal information within the EB context.     

Enhanced gene trapping in mouse embryonic stem cells

Gene trapping is used to introduce insertional mutations into genes of mouse embryonic stem cells (ESCs). It is performed with gene trap vectors that simultaneously mutate and report the expression of the endogenous gene at the site of insertion and provide a DNA tag for rapid identification of the disrupted gene. Gene traps have been employed worldwide to assemble libraries of mouse ESC lines harboring mutations in single genes, which can be used to make mutant mice. However, most of the employed gene trap vectors require gene expression for reporting a gene trap event and therefore genes that are poorly expressed may be under-represented in the existing libraries. To address this problem, we have developed a novel class of gene trap vectors that can induce gene expression at insertion sites, thereby bypassing the problem of intrinsic poor expression. We show here that the insertion of the osteopontin enhancer into several conventional gene trap vectors significantly increases the gene trapping efficiency in high-throughput screens and facilitates the recovery of poorly expressed genes.     

Signaling pathways regulating proliferation of mouse embryonic stem cells

Mouse embryonic stem (MES) cells possess joint abilities for unlimited proliferation and maintenance of pluripotency during long-term cultivation. The regulation of the cell cycle of these cells is of great interest. This review is focused on the regulation of the cell cycle of these cells via different signaling pathways (LIF-STAT3, PI3K-Akt, Wnt-β-catenin). The mechanisms underlying the unlimited proliferation of MES cells and their inability to long-term block of proliferation in response to DNA-damaging and stress factors are discussed. The functioning of negative (cyclin-kinase inhibitors and Rb) and positive (cyclin-kinase complexes and E2F factors) cell cycle regulators are also the topics of this survey. Permanent mitogenic stimuli are thought to prevent the induction of apoptosis; in any case, agents which cause a prolonged halt to proliferation without stimulating the onset of differentiation or the induction of apoptosis are currently unknown. Special concern is given to the role of the Wnt signaling pathway in sustaining the pluripotent state of MES cells. Cell cycle regulation by downstream targets of LIF-STAT3, PI3-kinase and Wnt-β-catenin pathways is discussed in light of the cooperative action of these pathways in the maintenance of undifferentiated states of MES cells.