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

Since the 1960s,the stem cells have been extensively studied including embryonic stem cells,neural stem cells,bone marrow hematopoietic stem cells,and mesenchymal stem cells. In the recent years,several stem cells have been initially used in the treatment of diseases,such as in bone marrow transplant. At the same time,isolation and culture experimental technologies for stem cell research have been widely developed in recent years. In addition,molecular imaging technologies including optical molecular imaging,positron emission tomography,single-photon emission computed tomography,and computed tomography have been developed rapidly in recent the 10 years and have also been used in the research on disease mechanism and evaluation of treatment of disease related with stem cells. This paper will focus on recent typical isolation,culture,and observation techniques of stem cells followed by a concise introduction. Finally,the current challenges and the future applications of the new technologies in stem cells are given according to the understanding of the authors,and the paper is then concluded. View Publication

We report a system for Cre-regulated expression of RNA interference in vivo. Expression cassettes comprise selectable and FACS-sortable markers in tandem with additional marker genes and shRNAs in the antisense orientation. The cassettes are flanked by tandem LoxP sites arranged so that Cre expression inverts the marker-shRNA construct,allowing its regulated expression (and,at the same time,deletes the original selection/marker genes). The cassettes can be incorporated into retroviral or lentiviral vectors and delivered to cells in culture or used to generate transgenic mice. We describe cassettes incorporating various combinations of reporter genes,miRNA-based RNAi (including two shRNA constructs at once),and oncogenes and demonstrate the delivery of effective RNA interference in cells in culture,efficient transduction into hematopoietic stem cells with cell-type-specific knockdown in their progeny,and rapid generation of regulated shRNA knockdown in transgenic mice. These vector systems allow regulated combinatorial manipulation (both overexpression and loss of function) of gene expression in multiple systems in vitro and in vivo. View Publication

Human mesenchymal stromal cells (hMSCs) have generated significant interest due to their potential use in clinical applications. hMSCs are present at low frequency in vivo,but after isolation can be expanded considerably,generating clinically useful numbers of cells. In this study,we demonstrate the use of a defined embryonic stem cell expansion medium,mTeSR (Stem Cell Technologies),for the expansion of bone-marrow-derived hMSCs. The hMSCs grow at comparable rates,demonstrate tri-lineage differentiation potential,and show similar surface marker profiles (CD29(+),CD44(+),CD49a(+),CD73(+),CD90(+),CD105(+),CD146(+),CD166(+),CD34(-),and CD45(-)) in both the fetal bovine serum (FBS)-supplemented medium and mTeSR. However,expression of early differentiation transcription factors runt-related transcription factor 2,sex-determining region Y box 9,and peroxisome proliferator-activated receptor gamma changed significantly. Both runt-related transcription factor 2 and sex-determining region Y box 9 were upregulated,whereas peroxisome proliferator-activated receptor gamma was downregulated in mTeSR compared with FBS. Although osteogenic and chondrogenic differentiation was comparable in cells grown in mTeSR compared to FBS,adipogenic differentiation was significantly decreased in mTeSR-expanded cells,both in terms of gene expression and absolute numbers of adipocytes. The removal of the FBS from the medium and the provision of a defined medium with disclosed composition make mTeSR a superior study platform for hMSC biology in a controlled environment. Further,this provides a key step toward generating a clinical-grade medium for expansion of hMSCs for clinical applications that rely on osteo- and chondroinduction of MSCs,such as bone repair and cartilage generation. View Publication

Evidence suggests the transcription factor GATA-2 is a critical regulator of murine hematopoietic stem cells. Here,we explore the relation between GATA-2 and cell proliferation and show that inducing GATA-2 increases quiescence (G(0) residency) of murine and human hematopoietic cells. In human cord blood,quiescent fractions (CD34(+)CD38(-)Hoechst(lo)Pyronin Y(lo)) express more GATA-2 than cycling counterparts. Enforcing GATA-2 expression increased quiescence of cord blood cells,reducing proliferation and performance in long-term culture-initiating cell and colony-forming cell (CFC) assays. Gene expression analysis places GATA-2 upstream of the quiescence regulator MEF,but enforcing MEF expression does not prevent GATA-2-conferred quiescence,suggesting additional regulators are involved. Although known quiescence regulators p21(CIP1) and p27(KIP1) do not appear to be responsible,enforcing GATA-2 reduced expression of regulators of cell cycle such as CCND3,CDK4,and CDK6. Enforcing GATA-2 inhibited human hematopoiesis in vivo: cells with highest exogenous expression (GATA-2(hi)) failed to contribute to hematopoiesis in nonobese diabetic-severe combined immunodeficient (NOD-SCID) mice,whereas GATA-2(lo) cells contributed with delayed kinetics and low efficiency,with reduced expression of Ki-67. Thus,GATA-2 activity inhibits cell cycle in vitro and in vivo,highlighting GATA-2 as a molecular entry point into the transcriptional program regulating quiescence in human hematopoietic stem and progenitor cells. View Publication

A large membrane proteinase 3 (mPR3)-positive neutrophil subset (mPR3high) is a risk for Wegener's granulomatosis (WG). The relationship between mPR3 expression and clinical manifestations was investigated in 81 WG patients and mPR3 expression was studied in CD34+ stem cell-derived human neutrophils. The mPR3high neutrophil percentage correlated with renal function,anemia,and albumin at the time of presentation. The mPR3high neutrophil percentage and renal failure severity correlated directly after 5 yr. For elucidating mechanisms that govern mPR3 expression,studies were conducted to determine whether the genetic information that governs mPR3 expression resides within the neutrophils,even without stimuli possibly related to disease. CD34+ hematopoietic stem cells were differentiated to neutrophils,and their mPR3 expression was determined. A two-step amplification/differentiation protocol was used to differentiate human CD34+ hematopoietic stem cells into neutrophils with G-CSF. The cells progressively expressed the neutrophil surface markers CD66b,CD35,and CD11b. The ferricytochrome C assay demonstrated a strong respiratory burst at day 14 in response to PMA but none at day 0. Intracellular PR3 was detectable from day 4 by Western blotting. An increasing percentage of a mPR3-positive neutrophil subset became detectable by flow cytometry,whereas a second subset remained negative,consistent with a bimodal expression. Finally,human PR3-anti-neutrophil cytoplasmic autoantibodies induced a stronger respiratory burst,compared with human control IgG in stem cell-derived neutrophils. Taken together,these studies underscore the clinical importance of the WG mPR3 phenotype. The surface mPR3 on resting cells is probably genetically determined rather than being dictated by external factors. View Publication

The low frequency of hematopoietic stem and progenitor cells (HSPCs) in human BM has precluded analysis of the direct biochemical effects elicited by cytokines in these populations,and their functional consequences. Here,single-cell phospho-specific flow cytometry was used to define the signaling networks active in 5 previously defined human HSPC subsets. This analysis revealed that the currently defined HSC compartment is composed of biochemically distinct subsets with the ability to respond rapidly and directly in vitro to a broader array of cytokines than previously appreciated,including G-CSF. The G-CSF response was physiologically relevant-driving cell-cycle entry and increased proliferation in a subset of single cells within the HSC compartment. The heterogeneity in the single-cell signaling and proliferation responses prompted subfractionation of the adult BM HSC compartment by expression of CD114 (G-CSF receptor). Xenotransplantation assays revealed that HSC activity is significantly enriched in the CD114(neg/lo) compartment,and almost completely absent in the CD114(pos) subfraction. The single-cell analyses used here can be adapted for further refinement of HSPC surface immunophenotypes,and for examining the direct regulatory effects of other factors on the homeostasis of stem and progenitor populations in normal or diseased states. View Publication

Cancer-associated IDH mutations are characterized by neomorphic enzyme activity and resultant 2-hydroxyglutarate (2HG) production. Mutational and epigenetic profiling of a large acute myeloid leukemia (AML) patient cohort revealed that IDH1/2-mutant AMLs display global DNA hypermethylation and a specific hypermethylation signature. Furthermore,expression of 2HG-producing IDH alleles in cells induced global DNA hypermethylation. In the AML cohort,IDH1/2 mutations were mutually exclusive with mutations in the α-ketoglutarate-dependent enzyme TET2,and TET2 loss-of-function mutations were associated with similar epigenetic defects as IDH1/2 mutants. Consistent with these genetic and epigenetic data,expression of IDH mutants impaired TET2 catalytic function in cells. Finally,either expression of mutant IDH1/2 or Tet2 depletion impaired hematopoietic differentiation and increased stem/progenitor cell marker expression,suggesting a shared proleukemogenic effect. View Publication

Tristetraprolin (TTP,Zfp36,Nup475,Tis11) dramatically reduces the stability of target mRNAs by binding to AU-rich elements in their 3' untranslated regions. Through this mechanism,TTP functions as a rheostatic,temporal regulator of gene expression. TTP knockout (KO) mice exhibit completely penetrant granulocytic hyperplasia. We have shown that the hematopoietic stem-progenitor cell compartment in TTP KO mice is also altered. Although no change was detected in long-term hematopoietic stem cell (HSC) frequency or function,as assayed by immunophenotypic markers or limiting dilution transplants,we observed increases in the frequencies and numbers of short-term HSCs,multipotent progenitors,and granulocyte-monocyte progenitors. This pattern is consistent with reactive granulopoiesis� View Publication

The heart wall tissue,or the myocardium,is one of the main targets in cardiovascular disease prevention and treatment. Animal models have not been sufficient in mimicking the human myocardium as evident by the very low clinical translation rates of cardiovascular drugs. Additionally,current in vitro models of the human myocardium possess several shortcomings such as lack of physiologically relevant co-culture of myocardial cells,lack of a 3D biomimetic environment,and the use of non-human cells. In this study,we address these shortcomings through the design and manufacture of a myocardium-on-chip (MOC) using 3D cell-laden hydrogel constructs and human induced pluripotent stem cell (hiPSC) derived myocardial cells. The MOC utilizes 3D spatially controlled co-culture of hiPSC derived cardiomyocytes (iCMs) and hiPSC derived endothelial cells (iECs) integrated among iCMs as well as in capillary-like side channels,to better mimic the microvasculature seen in native myocardium. We first fully characterized iCMs using immunostaining,genetic,and electrochemical analysis and iECs through immunostaining and alignment analysis to ensure their functionality,and then seeded these cells sequentially into the MOC device. We showed that iECs could be cultured within the microfluidic device without losing their phenotypic lineage commitment,and align with the flow upon physiological level shear stresses. We were able to incorporate iCMs within the device in a spatially controlled manner with the help of photocrosslinkable polymers. The iCMs were shown to be viable and functional within the device up to 7 days,and were integrated with the iECs. The iCMs and iECs in this study were derived from the same hiPSC cell line,essentially mimicking the myocardium of an individual human patient. Such devices are essential for personalized medicine studies where the individual drug response of patients with different genetic backgrounds can be tested in a physiologically relevant manner. View Publication