技术资料

Endoplasmic reticulum (ER) stress occurs during early embryonic development. The aim of this study is to determine whether ER stress occurs during human embryonic stem cell differentiation induced by retinoic acid (RA). H9 human embryonic stem cells were subjected to RA treatment for up to 29. days to induce differentiation. HEK293 cells were treated with RA as a control. The results demonstrate that several ER stress-responsive genes are differentially regulated in H9 and HEK293 cells in response to 5. days of RA treatment. GRP78/Bip was upregulated in H9 cells but downregulated in HEK293 cells. eIF2?? was downregulated in H9 cells but not in HEK293 cells. Phosphorylation of eIF2?? was downregulated in H9 cells but upregulated in HEK293 cells. XBP-1 was downregulated immediately after RA treatment in H9 cells,but its downregulation was much slower in HEK293 cells. Additionally,two ER-resident E3 ubiquitin ligases,gp78 and Hrd1,were both upregulated in H9 cells following 5. days of exposure to RA. Moreover,the protein Bcl2 was undetectable in H9 cells and H9-derived cells but was expressed in HEK293 cells,and it expression in the two types of cells was unaltered by RA treatment. In H9 cells treated with RA for 29. days,GRP78/Bip,XBP-1 and Bcl2 were all upregulated. These results suggest that ER stress is involved in H9 cell differentiation induced by RA. ?? 2011 Elsevier Inc. View Publication

Human embryonic stem (hES) cells have the dual ability to self-renew and differentiate into specialized cell types. However,in order to realize the full potential of these cells it is important to understand how the genes responsible for their unique characteristics are regulated. In this study we examine the regulation of the tropomyosin-related kinase (TRK) genes which encode for receptors important in hES cell survival and self-renewal. Although the TRK genes have been studied in many neuronal cell types,the regulation of these genes in hES cells is unclear. Our study demonstrates a novel regulatory relationship between the TRKC gene and the transcription factor SOX2. Our results found that hES cells highly express full-length and truncated forms of the TRKC gene. However,examination of the related TRKB gene showed a lower overall expression of both full-length and truncated forms. Through RNA interference,we knocked down expression levels of SOX2 in hES cells and examined the expression of TRKC,as well as TRKB. Upon loss of SOX2 we found that TRKC mRNA levels were significantly downregulated but TRKB levels remained unchanged,demonstrating an important regulatory dependence on SOX2 by TRKC. We also found that TRKC protein levels were also decreased after SOX2 knock down. Further analysis found the regulatory region of TRKC to be highly conserved among many mammals with potential SOX binding motifs. We confirmed a specific binding motif as a site that SOX2 utilizes to directly interact with the TRKC regulatory region. In addition,we found that SOX2 drives expression of the TRKC gene by activating a luciferase reporter construct containing the TRKC regulatory region and the SOX binding motif. View Publication

Embryonic stem cell (ESC) identity and self-renewal is maintained by extrinsic signaling pathways and intrinsic gene regulatory networks. Here,we show that three members of the Ccr4-Not complex,Cnot1,Cnot2,and Cnot3,play critical roles in maintaining mouse and human ESC identity as a protein complex and inhibit differentiation into the extraembryonic lineages. Enriched in the inner cell mass of blastocysts,these Cnot genes are highly expressed in ESC and downregulated during differentiation. In mouse ESCs,Cnot1,Cnot2,and Cnot3 are important for maintenance in both normal conditions and the 2i/LIF medium that supports the ground state pluripotency. Genetic analysis indicated that they do not act through known self-renewal pathways or core transcription factors. Instead,they repress the expression of early trophectoderm (TE) transcription factors such as Cdx2. Importantly,these Cnot genes are also necessary for the maintenance of human ESCs,and silencing them mainly lead to TE and primitive endoderm differentiation. Together,our results indicate that Cnot1,Cnot2,and Cnot3 represent a novel component of the core self-renewal and pluripotency circuitry conserved in mouse and human ESCs. View Publication

Precise,robust and scalable directed differentiation of pluripotent stem cells is an important goal with respect to disease modeling or future therapies. Using the AggreWell™400 system we have standardized the differentiation of human embryonic and induced pluripotent stem cells to a neuronal fate using defined conditions. This allows reproducibility in replicate experiments and facilitates the direct comparison of cell lines. Since the starting point for EB formation is a single cell suspension,this protocol is suitable for standard and novel methods of pluripotent stem cell culture. Moreover,an intermediate population of neural precursor cells,which are routinely textgreater95% NCAM(pos) and Tra-1-60(neg) by FACS analysis,may be expanded and frozen prior to differentiation allowing a convenient starting point for downstream experiments. View Publication

Human embryonic stem cell-derived dendritic cells (hESC-DCs) may potentially provide a platform to generate off-the-shelf" therapeutic cancer vaccines. To apply hESC-DCs for cancer immunotherapy in a semiallogeneic setting� View Publication

The mechanisms by which human embryonic stem cells (hESC) differentiate to endodermal lineage have not been extensively studied. Mathematical models can aid in the identification of mechanistic information. In this work we use a population-based modeling approach to understand the mechanism of endoderm induction in hESC,performed experimentally with exposure to Activin A and Activin A supplemented with growth factors (basic fibroblast growth factor (FGF2) and bone morphogenetic protein 4 (BMP4)). The differentiating cell population is analyzed daily for cellular growth,cell death,and expression of the endoderm proteins Sox17 and CXCR4. The stochastic model starts with a population of undifferentiated cells,wherefrom it evolves in time by assigning each cell a propensity to proliferate,die and differentiate using certain user defined rules. Twelve alternate mechanisms which might describe the observed dynamics were simulated,and an ensemble parameter estimation was performed on each mechanism. A comparison of the quality of agreement of experimental data with simulations for several competing mechanisms led to the identification of one which adequately describes the observed dynamics under both induction conditions. The results indicate that hESC commitment to endoderm occurs through an intermediate mesendoderm germ layer which further differentiates into mesoderm and endoderm,and that during induction proliferation of the endoderm germ layer is promoted. Furthermore,our model suggests that CXCR4 is expressed in mesendoderm and endoderm,but is not expressed in mesoderm. Comparison between the two induction conditions indicates that supplementing FGF2 and BMP4 to Activin A enhances the kinetics of differentiation than Activin A alone. This mechanistic information can aid in the derivation of functional,mature cells from their progenitors. While applied to initial endoderm commitment of hESC,the model is general enough to be applicable either to a system of adult stem cells or later stages of ESC differentiation. View Publication

Human embryonic stem cells (hESCs) require specific niches for adhesion,expansion,and lineage-specific differentiation. In this study,we showed that a membrane substrate offers better tissue niches for hESC attachment,spreading,proliferation,and differentiation. The cell doubling time was shortened from 46.3±5.7 h for hESCs grown on solid substrates to 25.6±2.6 h for those on polyester (PE) membrane substrates with pore size of 0.4 μm. In addition,we observed an increase of approximately five- to ninefold of definitive endoderm marker gene expression in hESCs differentiated on PE or polyethylene terephthalate membrane substrates. Global gene expression analysis revealed upregulated expressions of a number of extracellular matrix and cell adhesion molecules in hESCs grown on membrane substrates. Further,an enhanced nuclear translocation of β-catenin was detected in these cells. These observations suggested the augmentation of Wnt signaling in hESCs grown on membrane substrates. These results also demonstrated that a membrane substrate can offer better physicochemical cues for enhancing in vitro hESC attachment,proliferation,and differentiation. View Publication

The glycogen synthase kinase 3 (GSK3) inhibitor,6-bromoindirubin-3'-oxime (BIO),is a key regulator of many signaling pathways to maintain pluripotency of human and mouse embryonic stem cells (ESCs). However,the effect of BIO on derivation of dairy goat male germline stem cells (mGSCs) remains unclear. The objectives of this study were to investigate whether BIO influences derivation of dairy goat mGSCs. Dairy goat mGSCs were cultured in mTeSR containing BIO medium and its effects on the proliferation ability of goat mGSCs (derived from goats ≤2 mo of age) were evaluated by 5-Bromo-2-deoxyuridine (BrdU) incorporation and alkaline phosphatase (AP) staining. Furthermore,its effects on maintenance of the undifferentiated state of mGSCs in late passages of cultures,as well as the capacity of mGSCs to differentiate into embryoid bodies (EBs) were examined. The presence of BIO increased the mitosis index and the number of AP positive colonies,as well as expression of pluripotent markers,Oct4,Nanog,Sox2,C-myc,Klf4,E-cadherin,and the proliferative markers,Pcna and C-myc. In contrast,there was no significant change in expression of apoptosis markers,P53,P21 and cyclin-related genes (Cyclin A,CDK2,Cyclin D1),as determined by RT-PCR analysis. When mGSCs were cultured in mTeSR medium containing BIO,EBs were formed,which were capable of further differentiating into various cell types found in the three embryonic germ layers,as determined by immunofluorescence and/or histologic staining. In conclusion,adding BIO to cultures BIO significantly promoted establishment of goat mGSC colonies and maintained their undifferentiated state. View Publication

In this unit,we describe a simple coculture-free method for obtaining mast cells from mouse and human embryonic stem (ES) cells. Much of our knowledge regarding the mechanisms by which mast cells are activated comes from studies of mouse bone marrow-derived mast cells. Studies of human mast cells have been hampered by the limited sources from which they can be cultured,the difficulty in introducing specific genetic changes into these cells,and differences between established cultures that reflect the unique genetic makeup of the tissue donor. Derivation of mast cells from embryonic stem cells addresses these limitations. ES-derived mast cells can be generated in numbers sufficient for studies of the pathways involved in mast cell effector functions. These ES cell-derived mast cells respond to antigens and other stimuli by releasing histamine,cytokines,lipids,and other bioactive mediators. The derivation of human mast cells from ES cells carrying mutations introduced by homologous recombination should provide a novel means of testing the function of genes in both the development and the effector functions of mast cells. View Publication

Embryonic stem cells (ESCs) are unique cells,which have the ability to differentiate into all cell types that comprise the adult organism. Furthermore,ESCs can infinitely self-renew under optimized conditions. These features place human ESCs (hESCs) in a position where these cells can be exploited for tissue engineering and regenerative medicine approaches in treating human degenerative disorders. However,cell therapy approaches will require large amounts of clinically useable cells,not typically achievable using standard static cell culture methods. Here,we describe a method wherein clinically relevant numbers of hESCs can be generated in a cost and time effective manner. View Publication

The differentiation of human embryonic stem cells (hESCs) and human-induced pluripotent stem cells (hiPSCs) towards functional neurons particularly hold great potential for the cell-based replacement therapy in neurodegenerative diseases. Here,we describe a stepwise differentiation protocol that mimics the early stage of neural development in human to promote the generation of neuroprogenitors at a high yield. Both the hESCs and hiPSCs are initially cultured in an optimized feeder-free condition,which offer an efficient formation of aggregates. To specify the neuroectodermal specification,these aggregates are differentiated in a defined neural induction medium to develop into neural rosettes-like structures. The rosettes are expanded into free-floating sphere and can be further propagated or developed into variety of neuronal subtypes. View Publication

Substrates used to culture human embryonic stem cells (hESCs) are typically 2-dimensional (2-D) in nature,with limited ability to recapitulate in vivo-like 3-dimensional (3-D) microenvironments. We examined critical determinants of hESC self-renewal in poly-d-lysine-pretreated synthetic polymer-based substrates with variable microgeometries,including planar 2-D films,macroporous 3-D sponges,and microfibrous 3-D fiber mats. Completely synthetic 2-D substrates and 3-D macroporous scaffolds failed to retain hESCs or support self-renewal or differentiation. However,synthetic microfibrous geometries made from electrospun polymer fibers were found to promote cell adhesion,viability,proliferation,self-renewal,and directed differentiation of hESCs in the absence of any exogenous matrix proteins. Mechanistic studies of hESC adhesion within microfibrous scaffolds indicated that enhanced cell confinement in such geometries increased cell-cell contacts and altered colony organization. Moreover,the microfibrous scaffolds also induced hESCs to deposit and organize extracellular matrix proteins like laminin such that the distribution of laminin was more closely associated with the cells than the Matrigel treatment,where the laminin remained associated with the coated fibers. The production of and binding to laminin was critical for formation of viable hESC colonies on synthetic fibrous scaffolds. Thus,synthetic substrates with specific 3-D microgeometries can support hESC colony formation,self-renewal,and directed differentiation to multiple lineages while obviating the stringent needs for complex,exogenous matrices. Similar scaffolds could serve as tools for developmental biology studies in 3-D and for stem cell differentiation in situ and transplantation using defined humanized conditions. View Publication