技术资料

Cellular reprogramming from adult somatic cells into an embryonic cell-like state,termed induced pluripotency,has been achieved in several cell types. However,the ability to reprogram human amniotic epithelial cells (hAECs),an abundant cell source derived from discarded placental tissue,has only recently been investigated. Here we show that not only are hAECs easily reprogrammed into induced pluripotent stem cells (AE-iPSCs),but hAECs reprogram faster and more efficiently than adult and neonatal somatic dermal fibroblasts. Furthermore,AE-iPSCs express higher levels of NANOG and OCT4 compared to human foreskin fibroblast iPSCs (HFF1-iPSCs) and express decreased levels of genes associated with differentiation,including NEUROD1 and SOX17,markers of neuronal differentiation. To elucidate the mechanism behind the higher reprogramming efficiency of hAECs,we analyzed global DNA methylation,global histone acetylation,and the mitochondrial DNA A3243G point mutation. Whereas hAECs show no differences in global histone acetylation or mitochondrial point mutation accumulation compared to adult and neonatal dermal fibroblasts,hAECs demonstrate a decreased global DNA methylation compared to dermal fibroblasts. Likewise,quantitative gene expression analyses show that hAECs endogenously express OCT4,SOX2,KLF4,and c-MYC,all four factors used in cellular reprogramming. Thus,hAECs represent an ideal cell type for testing novel approaches for generating clinically viable iPSCs and offer significant advantages over postnatal cells that more likely may be contaminated by environmental exposures and infectious agents. View Publication

PURPOSE:
Human embryonic stem cells (hESC) hold a great potential for regenerative medicine because,in principle,they can differentiate into any cell type found in the human body. In addition,studying the effect of ionizing radiation (IR) on hESC may provide valuable information about the response of human cells to IR exposure in their most naive state,as well as the consequences of IR exposure on the development of organisms. However,the effect of IR,in particular radionuclide uptake,on the pluripotency,proliferation and survival of hESC has not been extensively studied.
METHODS:
In this study we treated cultured hESC with 5-[(125)I]iodo-2'-deoxyuridine ((125)IdU),a precursor of DNA synthesis. Then we measured the expansion of colonies and expression of pluripotency markers in hESC.
RESULTS:
We found that uptake of (125)IdU was similar in both hESC and HT1080 human fibrosarcoma cells. However,treatment with 0.1 μCi/ml (125)IdU for 24 hours resulted in complete death of the hESC population; whereas HT1080 cancer cells continued to grow. Treatment with a 10-fold lower dose (125)IdU (0.01 μCi/ml) resulted in colonies of hESC becoming less defined with numerous cells growing in monolayer outside of the colonies showing signs of differentiation. Then we analyzed the expression of pluripotency markers (octamer-binding transcription factor 4 [Oct-4] and stage-specific embryonic antigen-4 [SSEA4]) in the surviving hESC. We found that hESC in the surviving colonies expressed pluripotency markers at levels comparable with those in the non-treated controls.
CONCLUSIONS:
Our results provide important initial insights into the sensitivity of hESC to IR,and especially that produced by the decay of an internalized radionuclide. View Publication

The sodium-iodine symporter (NIS) is expressed on the cell membrane of many thyroid cancer cells,and is responsible for the radioactive iodine accumulation. However,treatment of anaplastic thyroid cancer is ineffective due to the low expression of NIS on cell membranes of these tumor cells. Human embryonic stem cells (ESCs) provide a potential vehicle to study the mechanisms of NIS expression regulation during differentiation. Human ESCs were maintained on feeder-independent culture conditions. RT-qPCR and immunocytochemistry were used to study differentiation marker expression,(125)I uptake to study NIS function. We designed a two-step protocol for human ESC differentiation into thyroid-like cells,as was previously done for mouse embryonic stem cells. First,we obtained definitive endoderm from human ESCs. Second,we directed differentiation of definitive endoderm cells into thyroid-like cells using various factors,with thyroid stimulating hormone (TSH) as the main differentiating factor. Expression of pluripotency,endoderm and thyroid markers and (125)I uptake were monitored throughout the differentiation steps. These approaches did not result in efficient induction of thyroid-like cells. We conclude that differentiation of human ESCs into thyroid cells cannot be induced by TSH media supplementation alone and most likely involves complicated developmental patterns that are yet to be understood. View Publication

Transcriptional profiling of differentiating human embryonic stem cells (hESCs) revealed that MIXL1-positive mesodermal precursors were enriched for transcripts encoding the G-protein-coupled APELIN receptor (APLNR). APLNR-positive cells,identified by binding of the fluoresceinated peptide ligand,APELIN (APLN),or an anti-APLNR mAb,were found in both posterior mesoderm and anterior mesendoderm populations and were enriched in hemangioblast colony-forming cells (Bl-CFC). The addition of APLN peptide to the media enhanced the growth of embryoid bodies (EBs),increased the expression of hematoendothelial genes in differentiating hESCs,and increased the frequency of Bl-CFCs by up to 10-fold. Furthermore,APLN peptide also synergized with VEGF to promote the growth of hESC-derived endothelial cells. These studies identified APLN as a novel growth factor for hESC-derived hematopoietic and endothelial cells. View Publication

Embryonic and induced pluripotent stem cells (IPSCs) derived from mammalian species are valuable tools for modeling human disease,including retinal degenerative eye diseases that result in visual loss. Restoration of vision has focused on transplantation of neural progenitor cells (NPCs) and retinal pigmented epithelium (RPE) to the retina. Here we used transgenic common marmoset (Callithrix jacchus) and human pluripotent stem cells carrying the enhanced green fluorescent protein (eGFP) reporter as a model system for retinal differentiation. Using suspension and subsequent adherent differentiation cultures,we observed spontaneous in vitro differentiation that included NPCs and cells with pigment granules characteristic of differentiated RPE. Retinal cells derived from human and common marmoset pluripotent stem cells provide potentially unlimited cell sources for testing safety and immune compatibility following autologous or allogeneic transplantation using nonhuman primates in early translational applications. 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

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

In guiding hES cell technology toward the clinic,one key issue to be addressed is to culture and maintain hES cells much more safely and economically in large scale. In order to avoid using mouse embryonic fibroblasts (MEFs) we isolated human fetal liver stromal cells (hFLSCs) from 14 weeks human fetal liver as new human feeder cells. hFLSCs feeders could maintain hES cells for 15 passages (about 100 days). Basic fibroblast growth factor (bFGF) is known to play an important role in promoting self-renewal of human embryonic stem (hES) cells. So,we established transgenic hFLSCs that stably express bFGF by lentiviral vectors. These transgenic human feeder cells--bFGF-hFLSCs maintained the properties of H9 hES cells without supplementing with any exogenous growth factors. H9 hES cells culturing under these conditions maintained all hES cell features after prolonged culture,including the developmental potential to differentiate into representative tissues of all three embryonic germ layers,unlimited and undifferentiated proliferative ability,and maintenance of normal karyotype. Our results demonstrated that bFGF-hFLSCs feeder cells were central to establishing the signaling network among bFGF,insulin-like growth factor 2 (IGF-2),and transforming growth factor β (TGF-β),thereby providing the framework in which hES cells were instructed to self-renew or to differentiate. We also found that the conditioned medium of bFGF-hFLSCs could maintain the H9 hES cells under feeder-free conditions without supplementing with bFGF. Taken together,bFGF-hFLSCs had great potential as feeders for maintaining pluripotent hES cell lines more safely and economically. View Publication

Induced pluripotent stem cells (iPSCs) offer immense potential for regenerative medicine and studies of disease and development. Somatic cell reprogramming involves epigenomic reconfiguration,conferring iPSCs with characteristics similar to embryonic stem (ES) cells. However,it remains unknown how complete the reestablishment of ES-cell-like DNA methylation patterns is throughout the genome. Here we report the first whole-genome profiles of DNA methylation at single-base resolution in five human iPSC lines,along with methylomes of ES cells,somatic cells,and differentiated iPSCs and ES cells. iPSCs show significant reprogramming variability,including somatic memory and aberrant reprogramming of DNA methylation. iPSCs share megabase-scale differentially methylated regions proximal to centromeres and telomeres that display incomplete reprogramming of non-CG methylation,and differences in CG methylation and histone modifications. Lastly,differentiation of iPSCs into trophoblast cells revealed that errors in reprogramming CG methylation are transmitted at a high frequency,providing an iPSC reprogramming signature that is maintained after differentiation. View Publication

More than 10 years after their first isolation,human embryonic stem cells are finally 'coming of age' in research and biotechnology applications as protocols for their differentiation and undifferentiated expansion in culture become robust and scalable,and validated commercial reagents become available. Production of human cardiomyocytes is now feasible on a daily basis for many laboratories with tissue culture expertise. An additional recent surge of interest resulting from the first production of human iPSCs (induced pluripotent stem cells) from somatic cells of patients now makes these technologies of even greater importance since it is likely that (genetic) cardiac disease phenotypes can be captured in the cardiac derivatives of these cells. Although cell therapy based on replacing cardiomyocytes lost or dysfunctional owing to cardiac disease are probably as far away as ever,biotechnology and pharmaceutical applications in safety pharmacology and drug discovery will probably impact this clinical area in the very near future. In the present paper,we review the cutting edge of this exciting area of translational research. View Publication

The aim of the study was to generate dopaminergic (DA) neurons from human embryonic stem cells (ESC) in vitro. It was shown that human ESCs are able to differentiated into DA neurons without co-culture with stromal cells. Terminal differentiation into DA neurons was reached by successive application of noggin and bFGF growth factors on collagen and matrigel substrates during 3-4 weeks. Differentiation efficiency was evaluated by the number of colonies with cells expressing tyrosine hydroxylase (TH),a DA neuron marker,and by the number of TH-positive cells in cell suspension using flow cytometry. No cells with pluripotent markers were detected in DA-differentiated cultures. It makes possible to propose that the protocol of human ESC differentiation might be applied to generate DA neurons for their transplantation into the animals modeling neurodegenerative (Parkinson) disease without the risk of tumor growth. View Publication

Human embryonic stem (hES) cells show an atypical cell-cycle regulation characterized by a high proliferation rate and a short G1 phase. In fact,a shortened G1 phase might protect ES cells from external signals inducing differentiation,as shown for certain stem cells. It has been suggested that self-renewal and pluripotency are intimately linked to cell-cycle regulation in ES cells,although little is known about the overall importance of the cell-cycle machinery in maintaining ES cell identity. An appealing model to address whether the acquisition of stem cell properties is linked to cell-cycle regulation emerged with the ability to generate induced pluripotent stem (iPS) cells by expression of defined transcription factors. Here,we show that the characteristic cell-cycle signature of hES cells is acquired as an early event in cell reprogramming. We demonstrate that induction of cell proliferation increases reprogramming efficiency,whereas cell-cycle arrest inhibits successful reprogramming. Furthermore,we show that cell-cycle arrest is sufficient to drive hES cells toward irreversible differentiation. Our results establish a link that intertwines the mechanisms of cell-cycle control with the mechanisms underlying the acquisition and maintenance of ES cell identity. View Publication