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

There are many reports of defined culture systems for the propagation of human embryonic stem cells in the absence of feeder cell support,but no previous study has undertaken a multi-laboratory comparison of these diverse methodologies. In this study,five separate laboratories,each with experience in human embryonic stem cell culture,used a panel of ten embryonic stem cell lines (including WA09 as an index cell line common to all laboratories) to assess eight cell culture methods,with propagation in the presence of Knockout Serum Replacer,FGF-2,and mouse embryonic fibroblast feeder cell layers serving as a positive control. The cultures were assessed for up to ten passages for attachment,death,and differentiated morphology by phase contrast microscopy,for growth by serial cell counts,and for maintenance of stem cell surface marker expression by flow cytometry. Of the eight culture systems,only the control and those based on two commercial media,mTeSR1 and STEMPRO,supported maintenance of most cell lines for ten passages. Cultures grown in the remaining media failed before this point due to lack of attachment,cell death,or overt cell differentiation. Possible explanations for relative success of the commercial formulations in this study,and the lack of success with other formulations from academic groups compared to previously published results,include: the complex combination of growth factors present in the commercial preparations; improved development,manufacture,and quality control in the commercial products; differences in epigenetic adaptation to culture in vitro between different ES cell lines grown in different laboratories. View Publication

The mechanisms ensuring the long-term self-renewal of human embryonic stem cells are still only partly understood,limiting their use in cellular therapies. Here we found that increased activity of the RB cell cycle inhibitor in human embryonic stem cells induces cell cycle arrest,differentiation and cell death. Conversely,inactivation of the entire RB family (RB,p107 and p130) in human embryonic stem cells triggers G2/M arrest and cell death through functional activation of the p53 pathway and the cell cycle inhibitor p21. Differences in E2F target gene activation upon loss of RB family function between human embryonic stem cells,mouse embryonic stem cells and human fibroblasts underscore key differences in the cell cycle regulatory networks of human embryonic stem cells. Finally,loss of RB family function promotes genomic instability in both human and mouse embryonic stem cells,uncoupling cell cycle defects from chromosomal instability. These experiments indicate that a homeostatic level of RB activity is essential for the self-renewal and the survival of human embryonic stem cells. View Publication

Human tumor vessels express tumor vascular markers (TVM),proteins that are not expressed in normal blood vessels. Antibodies targeting TVMs could act as potent therapeutics. Unfortunately,preclinical in vivo studies testing anti-human TVM therapies have been difficult to do due to a lack of in vivo models with confirmed expression of human TVMs. We therefore evaluated TVM expression in a human embryonic stem cell-derived teratoma (hESCT) tumor model previously shown to have human vessels. We now report that in the presence of tumor cells,hESCT tumor vessels express human TVMs. The addition of mouse embryonic fibroblasts and human tumor endothelial cells significantly increases the number of human tumor vessels. TVM induction is mostly tumor-type-specific with ovarian cancer cells inducing primarily ovarian TVMs,whereas breast cancer cells induce breast cancer specific TVMs. We show the use of this model to test an anti-human specific TVM immunotherapeutics; anti-human Thy1 TVM immunotherapy results in central tumor necrosis and a three-fold reduction in human tumor vascular density. Finally,we tested the ability of the hESCT model,with human tumor vascular niche,to enhance the engraftment rate of primary human ovarian cancer stem-like cells (CSC). ALDH(+) CSC from patients (n = 6) engrafted in hESCT within 4 to 12 weeks whereas none engrafted in the flank. ALDH(-) ovarian cancer cells showed no engraftment in the hESCT or flank (n = 3). Thus,this model represents a useful tool to test anti-human TVM therapy and evaluate in vivo human CSC tumor biology. View Publication

The ability to yield glucose-responsive pancreatic beta-cells from human pluripotent stem cells in vitro will facilitate the development of the cell replacement therapies for the treatment of Type 1 Diabetes. Here,through the sequential in vitro targeting of selected signaling pathways,we have developed an abbreviated five-stage protocol (25-30 days) to generate human Embryonic Stem Cell-Derived Beta-like Cells (ES-DBCs). We showed that Geltrex,as an extracellular matrix,could support the generation of ES-DBCs more efficiently than that of the previously described culture systems. The activation of FGF and Retinoic Acid along with the inhibition of BMP,SHH and TGF-beta led to the generation of 75% NKX6.1+/NGN3+ Endocrine Progenitors. The inhibition of Notch and tyrosine kinase receptor AXL,and the treatment with Exendin-4 and T3 in the final stage resulted in 35% mono-hormonal insulin positive cells,1% insulin and glucagon positive cells and 30% insulin and NKX6.1 co-expressing cells. Functionally,ES-DBCs were responsive to high glucose in static incubation and perifusion studies,and could secrete insulin in response to successive glucose stimulations. Mitochondrial metabolic flux analyses using Seahorse demonstrated that the ES-DBCs could efficiently metabolize glucose and generate intracellular signals to trigger insulin secretion. In conclusion,targeting selected signaling pathways for 25-30 days was sufficient to generate ES-DBCs in vitro. The ability of ES-DBCs to secrete insulin in response to glucose renders them a promising model for the in vitro screening of drugs,small molecules or genes that may have potential to influence beta-cell function. View Publication

The transcription factor Runx1/AML1 is an important regulator of hematopoiesis and is critically required for the generation of the first definitive hematopoietic stem cells (HSCs) in the major vasculature of the mouse embryo. As a pivotal factor in HSC ontogeny,its transcriptional regulation is of high interest but is largely undefined. In this study,we used a combination of comparative genomics and chromatin analysis to identify a highly conserved 531-bp enhancer located at position + 23.5 in the first intron of the 224-kb mouse Runx1 gene. We show that this enhancer contributes to the early hematopoietic expression of Runx1. Transcription factor binding in vivo and analysis of the mutated enhancer in transient transgenic mouse embryos implicate Gata2 and Ets proteins as critical factors for its function. We also show that the SCL/Lmo2/Ldb-1 complex is recruited to the enhancer in vivo. Importantly,transplantation experiments demonstrate that the intronic Runx1 enhancer targets all definitive HSCs in the mouse embryo,suggesting that it functions as a crucial cis-regulatory element that integrates the Gata,Ets,and SCL transcriptional networks to initiate HSC generation. View Publication

The human ATP-binding cassette superfamily G (White) member 2 (ABCG2) gene and its murine homologue breast cancer resistance protein 1 (Bcrp1) are recently described ATP-binding cassette transporters associated with drug resistance in tumor cell lines,including the MCF-7 cell line,selected for its resistance to mitoxantrone (MCF-7/MitoR). Infection of MCF-7 cells with the retroviral vector containing ABCG2 cDNA (G1-ABCG2) resulted in cells (MCF-7/ABCG2) that were resistant to mitoxantrone at levels similar to those observed in MCF-7/MitoR cells. Previous studies have shown that pluripotent hematopoietic stem cells overexpress the multidrug-resistant transport (MDR1) gene and efflux rhodamine,a substrate for the MDR1 transporter. Other studies have identified a primitive hematopoietic stem cell population,or side population (SP) cells,which are identified by their efflux of the fluorescent dye,Hoechst 33342. In an attempt to identify the transport genes responsible for this phenotype,we examined the uptake of Hoechst 33342 into MCF-7,MCF-7/MitoR,and MCF-7 cells infected with a retroviral vector expressing the ABCG2 gene (MCF-7/ABCG2). MCF-7/MitoR cells as well as MCF-7/ABCG2 cells demonstrated lower levels of Hoechst 33342 uptake compared with the parental MCF-7 cells. We also examined the level of the mouse Bcrp1 RNA in SP cells and non-SP cells isolated from mouse hematopoietic cells. Mouse SP cells expressed relatively high levels of Bcrp1 mRNA relative to non-SP cells. These results suggest that Hoechst 33342 is a substrate for the ABCG2 transporter and that ABCG2/Bcrp1 expression may serve as a marker for hematopoietic stem cells in hematopoietic cells. View Publication

Hematotoxicity is a significant issue for drug safety and can result from direct cytotoxicity toward circulating mature blood cell types as well as targeting of immature blood-forming stem cells/progenitor cells in the bone marrow. In vitro models for understanding and investigating the hematotoxicity potential of new test items/drugs are critical in early preclinical drug development. The traditional method,colony forming unit (CFU) assay,is commonly used and has been validated as a method for hematotoxicity screening. The CFU assay has multiple limitations for its application in investigative work. In this paper,we describe a detailed protocol for a liquid-culture,microplate-based in vitro hematotoxicity assay to evaluate lineage-specific (myeloid,erythroid,and megakaryocytic) hematotoxicity at different stages of differentiation. This assay has multiple advantages over the traditional CFU assay,including being suitable for high-throughput screening and flexible enough to allow inclusion of additional endpoints for mechanistic studies. Therefore,it is an extremely useful tool for scientists in pharmaceutical discovery and development. {\textcopyright} 2018 by John Wiley & Sons,Inc. View Publication

Although hematopoietic stem cells (HSC) are the best characterized and the most clinically used adult stem cells,efforts are still needed to understand how to best ex vivo expand these cells. Here we present our unexpected finding that OCT4 is involved in the enhancement of cytokine-induced expansion capabilities of human cord blood (CB) HSC. Activation of OCT4 by Oct4-activating compound 1 (OAC1) in CB CD34(+) cells enhanced ex vivo expansion of HSC,as determined by a rigorously defined set of markers for human HSC,and in vivo short-term and long-term repopulating ability in NSG mice. Limiting dilution analysis revealed that OAC1 treatment resulted in 3.5-fold increase in the number of SCID repopulating cells (SRCs) compared with that in day 0 uncultured CD34(+) cells and 6.3-fold increase compared with that in cells treated with control vehicle. Hematopoietic progenitor cells,as assessed by in vitro colony formation,were also enhanced. Furthermore,we showed that OAC1 treatment led to OCT4-mediated upregulation of HOXB4. Consistently,siRNA-mediated knockdown of HOXB4 expression suppressed effects of OAC1 on ex vivo expansion of HSC. Our study has identified the OCT4-HOXB4 axis in ex vivo expansion of human CB HSC. View Publication

The anti-My-10 mouse monoclonal antibody was raised against the immature human myeloid cell line KG-1a and was selected for nonreactivity with mature human granulocytes. Anti-My-10 immunoprecipitated a KG-1a cell surface protein with an apparent Mr of approximately 115 kD. We describe the binding of this antibody to human hematopoietic cell types and show that My-10 is expressed specifically on immature normal human marrow cells,including hematopoietic progenitor cells. My-10 is also expressed by leukemic marrow cells from a subpopulation of patients. Thus,this antibody allows the identification and purification of hematopoietic progenitor cells from normal human marrow and the subclassification of leukemia. View Publication

It has been shown that genetic inhibition of p53 leads to enhanced proliferation of hematopoietic stem cells (HSCs). This could,in theory,contribute to the increased frequency of tumor development observed in p53-deficient mice and humans. In our previous work,we identified chemical p53 inhibitors (PFTs) that suppress the transactivation function of p53 and protect cultured cells and mice from death induced by gamma irradiation (IR). Here we found that when applied to bone marrow cells in vitro or injected into mice,PFTb impeded IR-induced reduction of hematopoietic stem cell (HSC) and hematopoietic progenitor cell (HPC) population sizes. In addition,we showed that PFTb stimulated HSC and HPC proliferation in the absence of IR in vitro and in vivo and mobilized HSCs to the peripheral blood. Importantly,however,PFTb treatment did not affect the timing or frequency of tumor development in irradiated p53 heterozygous mice used as a model for determination of carcinogenicity. Thus,although PFTb administration led to increased numbers of HSCs and HPCs,it was not carcinogenic in mice. These findings suggest that chemical p53 inhibitors may be clinically useful as safe and effective stimulators of hematopoiesis. View Publication

The superiority of dendritic cells (DCs) as antigen-presenting cells has been exploited in numerous clinical trials,where generally monocyte-derived DCs (Mo-DCs) are injected to induce immunity in patients with cancer or infectious diseases. Despite promising expansion of antigen-specific T cells,the clinical responses following vaccination have been limited,indicating that further improvements of DC vaccine potency are necessary. Pre-clinical studies suggest that vaccination with combination of primary DC subsets,such as myeloid and plasmacytoid blood DCs (mDCs and pDCs,respectively),may result in stronger clinical responses. However,it is a challenge to obtain high enough numbers of primary DCs for immunotherapy,since their frequency in blood is very low. We therefore explored the possibility to generate them from hematopoietic progenitor cells (HPCs). Here,we show that by inhibiting the aryl hydrocarbon receptor with its antagonist StemRegenin 1 (SR1),clinical-scale numbers of functional BDCA2(+)BDCA4(+) pDCs,BDCA1(+) mDCs,and BDCA3(+)DNGR1(+) mDCs can be efficiently generated from human CD34(+) HPCs. The ex vivo-generated DCs were phenotypically and functionally comparable to peripheral blood DCs. They secreted high levels of pro-inflammatory cytokines such as interferon (IFN)-α,interleukin (IL)-12,and tumor necrosis factor (TNF)-α and upregulated co-stimulatory molecules and maturation markers following stimulation with Toll-like receptor (TLR) ligands. Further,they induced potent allogeneic T-cell responses and activated antigen-experienced T cells. These findings demonstrate that SR1 can be exploited to generate high numbers of functional pDCs and mDCs from CD34(+) HPCs,providing an alternative option to Mo-DCs for immunotherapy of patients with cancer or infections. View Publication

Previous studies have demonstrated that normal mouse mammary tissue contains a rare subset of mammary stem cells. We now describe a method for detecting an analogous subpopulation in normal human mammary tissue. Dissociated cells are suspended with fibroblasts in collagen gels,which are then implanted under the kidney capsule of hormone-treated immunodeficient mice. After 2-8 weeks,the gels contain bilayered mammary epithelial structures,including luminal and myoepithelial cells,their in vitro clonogenic progenitors and cells that produce similar structures in secondary transplants. The regenerated clonogenic progenitors provide an objective indicator of input mammary stem cell activity and allow the frequency and phenotype of these human mammary stem cells to be determined by limiting-dilution analysis. This new assay procedure sets the stage for investigations of mechanisms regulating normal human mammary stem cells (and possibly stem cells in other tissues) and their relationship to human cancer stem cell populations. View Publication