技术资料

Conventionally,researchers remove spontaneously differentiated areas in human pluripotent stem cell (hPSC) colonies by using a finely drawn glass pipette or a commercially available syringe needle. However,when extreme differentiation occurs,it is inefficient to purify the remaining undifferentiated cells,as these undifferentiated areas are too small to be isolated completely with the mechanical method. Antibodies can be utilized to purify the rare undifferentiated cells; however,this type of purification cannot be used in xeno-free culture systems. To avoid the loss of valuable hPSCs,we developed a novel method to isolate undifferentiated hPSCs from extremely differentiated colonies that could be easily adapted to xeno-free culture conditions. This protocol involves dissecting away differentiated areas,dissociating the remaining colony into clumps,seeding small clumps into new dishes,and picking undifferentiated colonies for expansion. Using this method,we routinely achieve completely undifferentiated colonies in one passage without the use of antibody-based purification. View Publication

Human embryonic stem cells (hESCs) are pluripotent cells derived from the embryo at the blastocyst stage. Their embryonic origin confers upon them the capacity to proliferate indefinitely in vitro while maintaining the capacity to differentiate into a large variety of cell types. Based on these properties of self-renewal and pluripotency,hESCs represent a unique source to generate a large quantity of certain specialized cell types with clinical interest for transplantation-based therapy. However,hESCs are usually grown in culture conditions using fetal bovine serum and mouse embryonic fibroblasts,two components that are not compatible with clinical applications. Consequently,the possibility to expand hESCs in serum-free and in feeder-free culture conditions is becoming a major challenge to deliver the clinical promises of hESCs. Here,we describe the basic principles of growing hESCs in a chemically defined medium (CDM) devoid of serum and feeders. View Publication

Induced pluripotent stem (iPS) cells have great potential for regenerative medicine and gene therapy. Thus far,iPS cells have typically been generated using integrating viral vectors expressing various reprogramming transcription factors; nonintegrating methods have been less effective and efficient. Because there is a significant risk of malignant transformation and cancer involved with the use of iPS cells,careful evaluation of transplanted iPS cells will be necessary in small and large animal studies before clinical application. Here,we have generated and characterized nonhuman primate iPS cells with the goal of evaluating iPS cell transplantation in a clinically relevant large animal model. We developed stable Phoenix-RD114-based packaging cell lines that produce OCT4,SOX2,c-MYC,and KLF4 (OSCK) expressing gammaretroviral vectors. Using these vectors in combination with small molecules,we were able to efficiently and reproducibly generate nonhuman primate iPS cells from pigtailed macaques (Macaca nemestrina). The established nonhuman primate iPS cells exhibited pluripotency and extensive self-renewal capacity. The facile and reproducible generation of nonhuman primate iPS cells using defined producer cells as a source of individual reprogramming factors should provide an important resource to optimize and evaluate iPS cell technology for studies involving stem cell biology and regenerative medicine. View Publication

To exploit the full potential of human pluripotent stem cells for regenerative medicine,developmental biology and drug discovery,defined culture conditions are needed. Media of known composition that maintain human embryonic stem (hES) cells have been developed,but finding chemically defined,robust substrata has proven difficult. We used an array of self-assembled monolayers to identify peptide surfaces that sustain pluripotent stem cell self-renewal. The effective substrates displayed heparin-binding peptides,which can interact with cell-surface glycosaminoglycans and could be used with a defined medium to culture hES cells for more than 3 months. The resulting cells maintained a normal karyotype and had high levels of pluripotency markers. The peptides supported growth of eight pluripotent cell lines on a variety of scaffolds. Our results indicate that synthetic substrates that recognize cell-surface glycans can facilitate the long-term culture of pluripotent stem cells. View Publication

Embryonic stem (ES) cells have been established as permanent lines of undifferentiated pluripotent cells from early mouse embryos. ES cells provide a unique system for the genetic manipulation and the creation of knockout strains of mice through gene targeting. By cultivation in vitro as 3D aggregates called embryoid bodies,ES cells can differentiate into derivatives of all 3 primary germ layers,including cardiomyocytes. Protocols for the in vitro differentiation of ES cells into cardiomyocytes representing all specialized cell types of the heart,such as atrial-like,ventricular-like,sinus nodal-like,and Purkinje-like cells,have been established. During differentiation,cardiac-specific genes as well as proteins,receptors,and ion channels are expressed in a developmental continuum,which closely recapitulates the developmental pattern of early cardiogenesis. Exploitation of ES cell-derived cardiomyocytes has facilitated the analysis of early cardiac development and has permitted in vitro gain-of-function" or "loss-of-function" genetic studies. Recently� View Publication

Hematopoietic stem cells (HSC) are tightly regulated through,as yet,undefined mechanisms that balance self-renewal and differentiation. We have identified a role for the transcriptional coactivators CREB-binding protein (CBP) and p300 in such HSC fate decisions. A full dose of CBP,but not p300,is crucial for HSC self-renewal. Conversely,p300,but not CBP,is essential for proper hematopoietic differentiation. Furthermore,in chimeric mice,hematologic malignancies emerged from both CBP(-/-) and p300(-/-) cell populations. Thus,CBP and p300 play essential but distinct roles in maintaining normal hematopoiesis,and,in mice,both are required for preventing hematologic tumorigenesis. View Publication

The signal transducer Stat5 plays a key role in the regulation of hematopoietic differentiation and hematopoietic stem cell function. To evaluate the effects of Stat5 signaling in the earliest hematopoietic progenitors,we have generated an embryonic stem cell line in which Stat5 signaling can be induced with doxycycline. Ectopic Stat5 activation at the point of origin of the hematopoietic lineage (from day 4 to day 6 of embryoid body differentiation) significantly enhances the number of hematopoietic progenitors with colony-forming potential. It does so without significantly altering total numbers or apoptosis of hematopoietic cells,suggesting a cell-intrinsic effect of Stat5 on either the developmental potential or clonogenicity of this population. From day-6 embryoid bodies,under the influence of Stat5 signaling,a population of semiadherent cells can be expanded on OP9 stromal cells that is comprised of primitive hematopoietic blast cells with ongoing,mainly myeloid,differentiation. When these cells are injected into lethally irradiated mice,they engraft transiently in a doxycycline-dependent manner. These results demonstrate that the hematopoietic commitment of embryonic stem cells may be augmented by a Stat5-mediated signal,and highlight the utility of manipulating individual components of signaling pathways for engineering tissue-specific differentiation of stem cells. View Publication

Bone marrow-derived mesenchymal stem cells (MSC) have been defined as primitive,undifferentiated cells,capable of self-renewal and with the ability to give rise to different cell lineages,including adipocytes,osteocytes,fibroblasts,chondrocytes,and myoblasts. MSC are key components of the hematopoietic microenvironment. Several studies,including some from our own group,suggest that important quantitative and functional alterations are present in the stroma of patients with myelodysplasia (MDS). However,in most of such studies the stroma has been analyzed as a complex network of different cell types and molecules,thus it has been difficult to identify and characterize the cell(s) type(s) that is (are) altered in MDS. In the present study,we have focused on the biological characterization of MSC from MDS. As a first approach,we have quantified their numbers in bone marrow,and have worked on their phenotypic (morphology and immunophenotype) and cytogenetic properties. MSC were obtained by a negative selection procedure and cultured in a MSC liquid culture medium. In terms of morphology,as well as the expression of certain cell markers,no differences were observed between MSC from MDS patients and those derived from normal marrow. In both cases,MSC expressed CD29,CD90,CD105 and Prolyl-4-hydroxylase; in contrast,they did not express CD14,CD34,CD68,or alkaline phosphatase. Interestingly,in five out of nine MDS patients,MSC developed in culture showed cytogenetic abnormalities,usually involving the loss of chromosomal material. All those five cases also showed cytogenetic abnormalities in their hematopoietic cells. Interestingly,in some cases there was a complete lack of overlap between the karyotypes of hematopoietic cells and MSC. To the best of our knowledge,the present study is the first in which a pure population of MSC from MDS patients is analyzed in terms of their whole karyotype and demonstrates that in a significant proportion of patients,MSC are cytogenetically abnormal. Although the reason of this is still unclear,such alterations may have an impact on the physiology of these cells. Further studies are needed to assess the functional integrity of MDS-derived MSC. View Publication

Stem cell-based tissue engineering is a promising technology in the effort to create functional tissues of choice. To establish an efficient approach for generating hematopoietic cell lineages directly from embryonic stem (ES) cells and to study the effects of three-dimensional (3D) biomaterials on ES cell differentiation,we cultured mouse ES cells on 3D,highly porous,biomimetic scaffolds. Cell differentiation was evaluated by microscopy and flow cytometry analysis with a variety of hematopoiesis- specific markers. Our data indicate that ES cells differentiated on porous 3D scaffold structures developed embryoid bodies (EBs) similar to those in traditional two-dimensional (2D) cultures; however,unlike 2D differentiation,these EBs integrated with the scaffold and appeared embedded in a network of extracellular matrix. Most significantly,the efficiency of hematopoietic precursor cell (HPC) generation on 3D,as indicated by the expression of various HPC-specific surface markers (CD34,Sca-1,Flk-1,and c-Kit) and colony-forming cell (CFC) assays,was reproducibly increased (about 2-fold) over their 2D counterparts. Comparison of static and dynamic 3D cultures demonstrated that spinner flask technology also contributed to the higher hematopoietic differentiation efficiency of ES cells seeded on scaffolds. Continued differentiation of 3D-derived HPCs into the myeloid lineage demonstrated increased efficiency (2-fold) of generating myeloid compared with differentiation from 2D-derived HPCs. View Publication

The beta-globin locus control region (LCR) is a large DNA element that is required for high-level expression of beta-like globin genes from the endogenous mouse locus or in transgenic mice carrying the human beta-globin locus. The LCR encompasses 6 DNaseI hypersensitive sites (HSs) that bind transcription factors. These HSs each contain a core of a few hundred base pairs (bp) that has most of the functional activity and exhibits high interspecies sequence homology. Adjoining the cores are 500- to 1000-bp flanks" with weaker functional activity and lower interspecies homology. Studies of human beta-globin transgenes and of the endogenous murine locus show that deletion of an entire HS (core plus flanks) moderately suppresses expression. However� View Publication

OBJECTIVE: Various preparative protocols have been proposed for the acquisition and cultivation of mesenchymal stem cells (MSC). Whereas surface antigen markers have failed to precisely define this population,microarray analysis might provide a better tool for characterization of MSC. METHODS: In this study,we have analyzed global gene expression profiles of human MSC isolated from adipose tissue (AT),from umbilical cord blood (CB),and from bone marrow (BM) under two growth conditions and have compared them to terminally differentiated human fibroblasts (HS68). Profiles were compared using our Human Genome Microarray representing 51.144 different cDNA clones. RESULTS: Cultured with the appropriate conditions,osteogenic and adipogenic differentiation could be confirmed in all MSC preparations but not in fibroblasts. No phenotypic differences were observed by flow cytometry using a panel of 22 surface antigen markers. Whereas MSC derived from different donors using the same culture procedure yielded a consistent and reproducible gene expression profile,many genes were differentially expressed in MSC from different ontogenetic sources or from different culture conditions. Twenty-five genes were overlapping and upregulated in all MSC preparations from AT,CB,and BM as compared to HS68 fibroblasts. These genes included fibronectin,ECM2,glypican-4,ID1,NF1B,HOXA5,and HOXB6. Many genes upregulated in MSC are involved in extracellular matrix,morphogenesis,and development,whereas several inhibitors of the Wnt pathway (DKK1,DKK3,SFRP1) were highly expressed in fibroblasts. CONCLUSION: Our results have provided a foundation for a more reproducible and reliable quality control using genotypic analysis for defining MSC. View Publication

We have established a system for directed differentiation of human embryonic stem (hES) cells into myeloid dendritic cells (DCs). As a first step,we induced hemopoietic differentiation by coculture of hES cells with OP9 stromal cells,and then,expanded myeloid cells with GM-CSF using a feeder-free culture system. Myeloid cells had a CD4+CD11b+CD11c+CD16+CD123(low)HLA-DR- phenotype,expressed myeloperoxidase,and included a population of M-CSFR+ monocyte-lineage committed cells. Further culture of myeloid cells in serum-free medium with GM-CSF and IL-4 generated cells that had typical dendritic morphology; expressed high levels of MHC class I and II molecules,CD1a,CD11c,CD80,CD86,DC-SIGN,and CD40; and were capable of Ag processing,triggering naive T cells in MLR,and presenting Ags to specific T cell clones through the MHC class I pathway. Incubation of DCs with A23187 calcium ionophore for 48 h induced an expression of mature DC markers CD83 and fascin. The combination of GM-CSF with IL-4 provided the best conditions for DC differentiation. DCs obtained with GM-CSF and TNF-alpha coexpressed a high level of CD14,and had low stimulatory capacity in MLR. These data clearly demonstrate that hES cells can be used as a novel and unique source of hemopoietic and DC precursors as well as DCs at different stages of maturation to address essential questions of DC development and biology. In addition,because ES cells can be expanded without limit,they can be seen as a potential scalable source of cells for DC vaccines or DC-mediated induction of immune tolerance. View Publication