搜索结果: 'methocult media formulations for mouse hematopoietic cells serum containing'

Somatic cells can be reprogrammed into induced pluripotent stem cells (iPSCs) by defined factors. However,the low efficiency and slow kinetics of the reprogramming process have hampered progress with this technology. Here we report that a natural compound,vitamin C (Vc),enhances iPSC generation from both mouse and human somatic cells. Vc acts at least in part by alleviating cell senescence,a recently identified roadblock for reprogramming. In addition,Vc accelerates gene expression changes and promotes the transition of pre-iPSC colonies to a fully reprogrammed state. Our results therefore highlight a straightforward method for improving the speed and efficiency of iPSC generation and provide additional insights into the mechanistic basis of the reprogramming process. View Publication

To search for genes that promote hematopoietic development from human embryonic stem cells (hESCs) and induced pluripotent stem cells (iPSCs),we overexpressed several known hematopoietic regulator genes in hESC/iPSC-derived CD34(+)CD43(-) endothelial cells (ECs) enriched in hemogenic endothelium (HE). Among the genes tested,only Sox17,a gene encoding a transcription factor of the SOX family,promoted cell growth and supported expansion of CD34(+)CD43(+)CD45(-/low) cells expressing the HE marker VE-cadherin. SOX17 was expressed at high levels in CD34(+)CD43(-) ECs compared with low levels in CD34(+)CD43(+)CD45(-) pre-hematopoietic progenitor cells (pre-HPCs) and CD34(+)CD43(+)CD45(+) HPCs. Sox17-overexpressing cells formed semiadherent cell aggregates and generated few hematopoietic progenies. However,they retained hemogenic potential and gave rise to hematopoietic progenies on inactivation of Sox17. Global gene-expression analyses revealed that the CD34(+)CD43(+)CD45(-/low) cells expanded on overexpression of Sox17 are HE-like cells developmentally placed between ECs and pre-HPCs. Sox17 overexpression also reprogrammed both pre-HPCs and HPCs into HE-like cells. Genome-wide mapping of Sox17-binding sites revealed that Sox17 activates the transcription of key regulator genes for vasculogenesis,hematopoiesis,and erythrocyte differentiation directly. Depletion of SOX17 in CD34(+)CD43(-) ECs severely compromised their hemogenic activity. These findings suggest that SOX17 plays a key role in priming hemogenic potential in ECs,thereby regulating hematopoietic development from hESCs/iPSCs. View Publication

Differentiating embryonic stem (ES) cells are an increasingly important source of hematopoietic progenitors,useful for both basic research and clinical applications. Besides their characterization in colony assays,protocols exist for the cultivation of lymphoid,myeloid,and erythroid cells. With the possible exception of mast cells,however,long-term expansion of pure hematopoietic progenitors from ES cells has not been possible without immortalization caused by overexpression of exogenous genes. Here,we describe for the first time an efficient yet easy strategy to generate mass cultures of pure,immature erythroid progenitors from mouse ES cells (ES-EPs),using serum-free medium plus recombinant cytokines and hormones. ES-EPs represent long-lived,adult,definitive erythroid progenitors that resemble immature erythroid cells expanding in vivo during stress erythropoiesis. When exposed to terminal differentiation conditions,ES-EPs differentiated into mature,enucleated erythrocytes. Importantly,ES-EPs injected into mice did not exhibit tumorigenic potential but differentiated into normal erythrocytes. Both the virtually unlimited supply of cells and the defined culture conditions render our system a valuable tool for the analysis of factors influencing proliferation and maturation of erythroid progenitors. In addition,the system allows detailed characterization of processes during erythroid proliferation and differentiation using wild-type (wt) and genetically modified ES cells. View Publication

It is often predicted that stem cells divide asymmetrically,creating a daughter cell that maintains the stem-cell capacity,and 1 daughter cell committed to differentiation. While asymmetric stem-cell divisions have been proven to occur in model organisms (eg,in Drosophila),it remains illusive whether primitive hematopoietic cells in mammals actually can divide asymmetrically. In our experiments we have challenged this question and analyzed the developmental capacity of separated offspring of primitive human hematopoietic cells at a single-cell level. We show for the first time that the vast majority of the most primitive,in vitro-detectable human hematopoietic cells give rise to daughter cells adopting different cell fates; 1 inheriting the developmental capacity of the mother cell,and 1 becoming more specified. In contrast,approximately half of the committed progenitor cells studied gave rise to daughter cells,both of which adopted the cell fate of their mother. Although our data are compatible with the model of asymmetric cell division,other mechanisms of cell fate specification are discussed. In addition,we describe a novel human hematopoietic progenitor cell that has the capacity to form natural killer (NK) cells as well as macrophages,but not cells of other myeloid lineages. View Publication

Gene therapy for a wide variety of disorders would be greatly enhanced by the development of vectors that could be targeted for gene delivery to specific populations of cells. We describe here high-efficiency targeted transduction based on a novel targeting strategy that exploits the ability of retroviruses to incorporate host cell proteins into the surface of the viral particle as they bud through the plasma membrane. Ecotropic retroviral particles produced in cells engineered to express the membrane-bound form of stem cell factor (mbSCF) transduce both human cell lines and primary cells with high efficiency in a strictly c-kit (SCF receptor)-dependent fashion. The availability of efficient targeted vectors provides a platform for the development of a new generation of therapies using in vivo gene delivery. View Publication

The signals that control the regenerative ability of hematopoietic stem cells (HSCs) in response to damage are unknown. Here,we demonstrate that downstream activation of the Hedgehog (Hh) signaling pathway induces cycling and expansion of primitive bone marrow hematopoietic cells under homeostatic conditions and during acute regeneration. However,this effect is at the expense of HSC function,because continued Hh activation during regeneration represses expression of specific cell cycle regulators,leading to HSC exhaustion. In vivo treatment with an inhibitor of the Hh pathway rescues these transcriptional and functional defects in HSCs. Our study establishes Hh signaling as a regulator of the HSC cell cycle machinery that balances hematopoietic homeostasis and regeneration in vivo. View Publication

Defining how cancer-associated mutations perturb signaling networks in stem/progenitor populations that are integral to tumor formation and maintenance is a fundamental problem with biologic and clinical implications. Point mutations in RAS genes contribute to many cancers,including myeloid malignancies. We investigated the effects of an oncogenic Kras(G12D) allele on phosphorylated signaling molecules in primary c-kit(+) lin(-/low) hematopoietic stem/progenitor cells. Comparison of wild-type and Kras(G12D) c-kit(+) lin(-/low) cells shows that K-Ras(G12D) expression causes hyperproliferation in vivo and results in abnormal levels of phosphorylated STAT5,ERK,and S6 under basal and stimulated conditions. Whereas Kras(G12D) cells demonstrate hyperactive signaling after exposure to granulocyte-macrophage colony-stimulating factor,we unexpectedly observe a paradoxical attenuation of ERK and S6 phosphorylation in response to stem cell factor. These studies provide direct biochemical evidence that cancer stem/progenitor cells remodel signaling networks in response to oncogenic stress and demonstrate that multi-parameter flow cytometry can be used to monitor the effects of targeted therapeutics in vivo. This strategy has broad implications for defining the architecture of signaling networks in primary cancer cells and for implementing stem cell-targeted interventions. View Publication

Adipose tissue is an abundantly available source of proliferative and multipotent mesenchymal stem cells with promising potential for regenerative therapeutics. We previously demonstrated that both human and mouse adipose-derived stem cells (ASCs) can be reprogrammed into induced pluripotent stem cells (iPSCs) with efficiencies higher than those that have been reported for other cell types. The ASC-derived iPSCs can be generated in a feeder-independent manner,representing a unique model to study reprogramming and an important step toward establishing a safe,clinical grade of cells for therapeutic use. In this study,we provide a detailed protocol for isolation,preparation and transformation of ASCs from fat tissue into mouse iPSCs in feeder-free conditions and human iPSCs using feeder-dependent or feeder/xenobiotic-free processes. This protocol also describes how ASCs can be used as feeder cells for maintenance of other pluripotent stem cells. ASC derivation is rapid and can be completed in textless1 week,with mouse and human iPS reprogramming times averaging 1.5 and 2.5 weeks,respectively. View Publication

In previous reports,we have demonstrated that only direct cell-cell contact with stromal cells,such as the murine stromal cell line AFT024,was able to alter the cell division kinetics and self-renewing capacity of hematopoietic progenitor cells (HPC). Because beta(1)-integrins were shown to be crucial for the interaction of HPC with the bone marrow microenvironment,we have studied the role of beta(1)-integrins in the regulation of self-renewing cell divisions. For this purpose,we used primary human mesenchymal stromal (MS) cells as in vitro surrogate niche and monitored the division history and subsequent functional fate of individually plated CD34(+)133(+) cells in the absence or presence of an anti-beta(1)-integrin blocking antibody by time-lapse microscopy and subsequent long-term culture-initiating cell (LTC-IC) assays. beta(1)-Integrin-mediated contact with MS cells significantly increased the proportion of asymmetrically dividing cells and led to a substantial increase of LTC-IC. Provided that beta(1)-integrin-mediated contact was available within the first 72 hours,human MS cells were able to recruit HPC into cell cycle and accelerate their division kinetics without loss of stem cell function. Activation of beta(1)-integrins by ligands alone (e.g.,fibronectin and vascular cell adhesion molecule-1) was not sufficient to alter the cell division symmetry and promote self-renewal of HPC,thus indicating an indirect effect. These results have provided evidence that primary human MS cells are able to induce self-renewing divisions of HPC by a beta(1)-integrin-dependent mechanism. View Publication

Autosomal recessive osteopetrosis (ARO) is a group of genetic disorders that involve defects that preclude the normal function of osteoclasts,which differentiate from hematopoietic precursors. In half of human cases,ARO is the result of mutations in the TCIRG1 gene,which codes for a subunit of the vacuolar proton pump that plays a fundamental role in the acidification of the cell-bone interface. Functional mutations of this pump severely impair the resorption of bone mineral. Although postnatal hematopoietic stem cell transplantation can partially rescue the hematological phenotype of ARO,other stigmata of the disease,such as secondary neurological and growth defects,are not reversed. For this reason,ARO is a paradigm for genetic diseases that would benefit from effective prenatal treatment. Using the oc/oc mutant mouse,a murine model whose osteopetrotic phenotype closely recapitulates human TCIRG1-dependent ARO,we report that in utero transplantation of adult bone marrow hematopoietic stem cells can correct the ARO phenotype in a limited number of mice. Here we report that in utero injection of allogeneic fetal liver cells,which include hematopoietic stem cells,into oc/oc mouse fetuses at 13.5 days post coitum produces a high level of engraftment,and the oc/oc phenotype is completely rescued in a high percentage of these mice. Therefore,oc/oc pathology appears to be particularly sensitive to this form of early treatment of the ARO genetic disorder. View Publication

GATA-2 is an essential transcription factor in the hematopoietic system that is expressed in hematopoietic stem cells (HSCs) and progenitors. Complete deficiency of GATA-2 in the mouse leads to severe anemia and embryonic lethality. The role of GATA-2 and dosage effects of this transcription factor in HSC development within the embryo and adult are largely unexplored. Here we examined the effects of GATA-2 gene dosage on the generation and expansion of HSCs in several hematopoietic sites throughout mouse development. We show that a haploid dose of GATA-2 severely reduces production and expansion of HSCs specifically in the aorta-gonad-mesonephros region (which autonomously generates the first HSCs),whereas quantitative reduction of HSCs is minimal or unchanged in yolk sac,fetal liver,and adult bone marrow. However,HSCs in all these ontogenically distinct anatomical sites are qualitatively defective in serial or competitive transplantation assays. Also,cytotoxic drug-induced regeneration studies show a clear GATA-2 dose-related proliferation defect in adult bone marrow. Thus,GATA-2 plays at least two functionally distinct roles during ontogeny of HSCs: the production and expansion of HSCs in the aorta-gonad-mesonephros and the proliferation of HSCs in the adult bone marrow. View Publication