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

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Identification of cancer stem cells is crucial for advancing cancer biology and therapy. Several markers including CD24,CD44,CD117,CD133,the G subfamily of ATP-binding cassette transporters (ABCG),epithelial specific antigen (ESA) and aldehyde dehydrogenase (ALDH) are used to identify and investigate human epithelial cancer stem cells in the literature. We have now systemically analyzed and compared the expression of these markers in fresh ovarian epithelial carcinomas. Although the expression levels of these markers were unexpectedly variable and partially overlapping in fresh ovarian cancer cells from different donors,we reliably detected important levels of CD133 and ALDH in the majority of fresh ovarian cancer. Furthermore,most of these stem cell markers including CD133 and ALDH were gradually lost following in vitro passage of primary tumor cells. However,the expression of ALDH and CD133,but not CD24,CD44 and CD117,could be partially rescued by the in vitro serum-free and sphere cultures and by the in vivo passage in the immune-deficient xenografts. ALDH+ and CD133+ cells formed three-dimensional spheres more efficiently than their negative counterparts. These sphere-forming cells expressed high levels of stem cell core gene transcripts and could be expanded and form additional spheres in long-term culture. ALDH+,CD133+ and ALDH+ CD133+ cells from fresh tumors developed larger tumors more rapidly than their negative counterparts. This property was preserved in the xenografted tumors. Altogether,the data suggest that ALDH+ and CD133+ cells are enriched with ovarian cancer-initiating (stem) cells and that ALDH and CD133 may be widely used as reliable markers to investigate ovarian cancer stem cell biology. View Publication

Fibroblast growth factor receptor 1 (Fgfr1) gene knockout impairs cardiomyocyte differentiation in murine embryonic stem cells (mESC). Here,various chemical compounds able to enhance cardiomyocyte differentiation in mESC [including dimethylsulfoxide,ascorbic acid (vitC),free radicals and reactive oxygen species] were tested for their ability to rescue the cardiomyogenic potential of Fgfr1(-/-) mESC. Among them,only the reduced form of vitC,l-ascorbic acid,was able to recover beating cell differentiation in Fgfr1(-/-) mESC. The appearance of contracting cells was paralleled by the expression of early and late cardiac gene markers,thus suggesting their identity as cardiomyocytes. In the attempt to elucidate the mechanism of action of vitC on Fgfr1(-/-) mESC,we analyzed several parameters related to the intracellular redox state,such as reactive oxygen species content,Nox4 expression,and superoxide dismutase activity. The results did not show any relationship between the antioxidant capacity of vitC and cardiomyocyte differentiation in Fgfr1(-/-) mESC. No correlation was found also for the ability of vitC to modulate the expression of pluripotency genes. Then,we tested the hypothesis that vitC was acting as a prolyl hydroxylase cofactor by maintaining iron in a reduced state. We first analyze hypoxia inducible factor (HIF)-1α mRNA and protein levels that were found to be slightly upregulated in Fgfr1(-/-) cells. We treated mESC with Fe(2+) or the HIF inhibitor CAY10585 during the first phases of the differentiation process and,similar to vitC,the two compounds were able to rescue cardiomyocyte formation in Fgfr1(-/-) mESC,thus implicating HIF-1α modulation in Fgfr1-dependent cardiomyogenesis. View Publication

FTIR micro-spectroscopy is a sensitive,non-destructive and label-free method offering diffraction-limited resolution with high signal-to-noise ratios when combined with a synchrotron radiation source. The vibrational signature of individual cells was used to validate an alternative strategy for reprogramming induced pluripotent stem cells generated from amniocytes. The iPSC lines PB09 and PB10,were reprogrammed from the same amniocyte cell line using respectively the Oct54,Sox2,Lin28,and Nanog and the Oct4 and Sox2 transcription factor cocktail. We show that cells reprogrammed by the two different sets of transfection factors have similar spectral signatures after reprogramming,except for a small subpopulation of cells in one of the cell lines. Mapping HeLa cells at subcellular resolution,we show that the Golgi apparatus,the cytoplasm and the nucleus have a specific spectral signature. The CH(3):CH(2) ratio is the highest in the nucleus and the lowest in the Golgi apparatus/endoplasmic reticulum,in agreement with the membrane composition of these organelles. This is confirmed by specific staining of the organelles with fluorescent dyes. Subcellular differentiation of cell compartments is also demonstrated in living cells. View Publication

Pluripotent stem cells have the potential to become most of the cell types that make up an organism. However,the signals that trigger these cells to turn into neurons rather than lung cells or muscle cells,for example,are not fully understood. Proteins called growth factors are known to have a role in this process,as are transcription factors,but it is not clear if other factors are also involved. In an attempt to identify additional mechanisms that could contribute to the formation of neurons,Sun et al. screened more than 2,000 small molecules for their ability to transform mouse pluripotent stem cells into neurons in cell culture. Surprisingly,they found that a compound called selamectin,which is used to treat parasitic flatworm infections,also triggered stem cells to turn into neurons. Selamectin works by blocking a particular type of ion channel in flatworms,but this ion channel is not found in vertebrates,which means that selamectin must be promoting the formation of neurons in mice via a different mechanism. Given that a drug related to selamectin is known to act on a subtype of receptors for the neurotransmitter GABA,Sun et al. wondered whether these receptors—known as GABAA receptors—might also underlie the effects of selamectin. Consistent with this idea,drugs that increased GABAA activity stimulated the formation of neurons,whereas drugs that reduced GABAA function blocked the effects of selamectin. In addition,Sun et al. showed that selamectin triggers human embryonic stem cells to become neurons,and that it also promotes the formation of new neurons in developing zebrafish in vivo. As well as revealing an additional mechanism for the formation of neurons from stem cells,the screening technique introduced by Sun et al. could help to identify further pro-neuronal molecules,which could aid the treatment of neurodevelopmental and neurodegenerative disorders. DOI: [http://dx.doi.org/10.7554/eLife.00508.002][1] [1]: /lookup/doi/10.7554/eLife.00508.002 View Publication

The development of strategies to eradicate primary human acute myelogenous leukemia (AML) cells is a major challenge to the leukemia research field. In particular,primitive leukemia cells,often termed leukemia stem cells,are typically refractory to many forms of therapy. To investigate improved strategies for targeting of human AML cells we compared the molecular mechanisms regulating oxidative state in primitive (CD34(+)) leukemic versus normal specimens. Our data indicate that CD34(+) AML cells have elevated expression of multiple glutathione pathway regulatory proteins,presumably as a mechanism to compensate for increased oxidative stress in leukemic cells. Consistent with this observation,CD34(+) AML cells have lower levels of reduced glutathione and increased levels of oxidized glutathione compared with normal CD34(+) cells. These findings led us to hypothesize that AML cells will be hypersensitive to inhibition of glutathione metabolism. To test this premise,we identified compounds such as parthenolide (PTL) or piperlongumine that induce almost complete glutathione depletion and severe cell death in CD34(+) AML cells. Importantly,these compounds only induce limited and transient glutathione depletion as well as significantly less toxicity in normal CD34(+) cells. We further determined that PTL perturbs glutathione homeostasis by a multifactorial mechanism,which includes inhibiting key glutathione metabolic enzymes (GCLC and GPX1),as well as direct depletion of glutathione. These findings demonstrate that primitive leukemia cells are uniquely sensitive to agents that target aberrant glutathione metabolism,an intrinsic property of primary human AML cells. View Publication

Human embryonic stem cells (hESCs) and induced pluripotent stem cells (hiPSCs) can differentiate to cardiomyocytes in vitro,offering unique opportunities to investigate cardiac development and disease as well as providing a platform to perform drug and toxicity tests. Initial cardiac differentiation methods were based on either inductive co-culture or aggregation as embryoid bodies,often in the presence of fetal calf serum. More recently,monolayer differentiation protocols have evolved as feasible alternatives and are often performed in completely defined culture medium and substrates. Thus,our ability to efficiently and reproducibly generate cardiomyocytes from multiple different hESC and hiPSC lines has improved significantly.We have developed a directed differentiation monolayer protocol that can be used to generate cultures comprising ˜50% cardiomyocytes,in which both the culture of the undifferentiated human pluripotent stem cells (hPSCs) and the differentiation procedure itself are defined and serum-free. The differentiation method is also effective for hPSCs maintained in other culture systems. In this chapter,we outline the differentiation protocol and describe methods to assess cardiac differentiation efficiency as well as to identify and quantify the yield of cardiomyocytes. View Publication

Induced pluripotent stem cells (iPSCs) are an essential tool for modeling how causal genetic variants impact cellular function in disease,as well as an emerging source of tissue for regenerative medicine. The preparation of somatic cells,their reprogramming and the subsequent verification of iPSC pluripotency are laborious,manual processes limiting the scale and reproducibility of this technology. Here we describe a modular,robotic platform for iPSC reprogramming enabling automated,high-throughput conversion of skin biopsies into iPSCs and differentiated cells with minimal manual intervention. We demonstrate that automated reprogramming and the pooled selection of polyclonal pluripotent cells results in high-quality,stable iPSCs. These lines display less line-to-line variation than either manually produced lines or lines produced through automation followed by single-colony subcloning. The robotic platform we describe will enable the application of iPSCs to population-scale biomedical problems including the study of complex genetic diseases and the development of personalized medicines. View Publication

Understanding the root causes of autoimmune diseases is hampered by the inability to access relevant human tissues and identify the time of disease onset. To examine the interaction of immune cells and their cellular targets in type 1 diabetes,we differentiated human induced pluripotent stem cells into pancreatic endocrine cells,including $\beta$ cells. Here,we describe an in vitro platform that models features of human type 1 diabetes using stress-induced patient-derived endocrine cells and autologous immune cells. We demonstrate a cell-type-specific response by autologous immune cells against induced pluripotent stem cell-derived $\beta$ cells,along with a reduced effect on $\alpha$ cells. This approach represents a path to developing disease models that use patient-derived cells to predict the outcome of an autoimmune response. View Publication

Cardiovascular calcification is the lead predictor of cardiovascular events and the top cause of morbidity and mortality worldwide. To date,only invasive surgical options are available to treat cardiovascular calcification despite the growing understanding of underlying pathological mechanisms. Key players in vascular calcification are vascular smooth muscle cells (SMCs),which transform into calcifying SMCs and secrete mineralizing extracellular vesicles that form microcalcifications,subsequently increasing plaque instability and consequential plaque rupture. There is an increasing,practical need for a large scale and inexhaustible source of functional SMCs. Here we describe an induced pluripotent stem cell (iPSC)-derived model of SMCs by differentiating iPSCs toward SMCs to study the pathogenesis of vascular calcification. Specifically,we characterize the proteome during iPSC differentiation to better understand the cellular dynamics during this process. First,we differentiated human iPSCs toward an induced-SMC (iSMC) phenotype in a 10-day protocol. The success of iSMC differentiation was demonstrated through morphological analysis,immunofluorescent staining,flow cytometry,and proteomics characterization. Proteomics was performed throughout the entire differentiation time course to provide a robust,well-defined starting and ending cell population. Proteomics data verified iPSC differentiation to iSMCs,and functional enrichment of proteins on different days showed the key pathways changing during iSMC development. Proteomics comparison with primary human SMCs showed a high correlation with iSMCs. After iSMC differentiation,we initiated calcification in the iSMCs by culturing the cells in osteogenic media for 17 days. Calcification was verified using Alizarin Red S staining and proteomics data analysis. This study presents an inexhaustible source of functional vascular SMCs and calcifying vascular SMCs to create an in vitro model of vascular calcification in osteogenic conditions,with high potential for future applications in cardiovascular calcification research. View Publication