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

MicroRNAs (miRNAs) are a newly discovered endogenous class of small noncoding RNAs that play important posttranscriptional regulatory roles by targeting mRNAs for cleavage or translational repression. Accumulating evidence now supports the importance of miRNAs for human embryonic stem cell (hESC) self-renewal,pluripotency,and differentiation. However,with respect to induced pluripotent stem cells (iPSC),in which embryonic-like cells are reprogrammed from adult cells using defined factors,the role of miRNAs during reprogramming has not been well-characterized. Determining the miRNAs that are associated with reprogramming should yield significant insight into the specific miRNA expression patterns that are required for pluripotency. To address this lack of knowledge,we use miRNA microarrays to compare the microRNA-omes" of human iPSCs� View Publication

Herpes simplex type 1 (HSV-1) amplicon vectors possess a number of features that make them excellent vectors for the delivery of transgenes into stem cells. HSV-1 amplicon vectors are capable of efficiently transducing both dividing and nondividing cells and since the virus is quite large,152 kb,it is of sufficient size to allow for incorporation of entire genomic DNA loci with native promoters. HSV-1 amplicon vectors can also be used to incorporate and deliver to cells a variety of sequences that allow extrachromosomal retention. These elements offer advantages over integrating vectors as they avoid transgene silencing and insertional mutagenesis. The construction of amplicon vectors carrying extrachromosomal retention elements,their packaging into HSV-1 viral particles,and the use of HSV-1 amplicons for stem cell transduction will be described. View Publication

Despite major progress in the management of human liver disease,the only cure for a critically failing organ is liver transplantation. While a highly successful approach,the use of cadaveric organs as a routine treatment option is severely limited by organ availability. Therefore,the use of cell-based therapies has been explored to provide support for the failing liver. In addition to developing new treatments,there is also an imperative to develop better human models 'in a dish'. Such approaches will undoubtedly lead to a better understanding of the disease process,offering new treatment or preventative strategies. With both approaches in mind,we have developed robust hepatocyte differentiation methodologies for use with pluripotent stem cells. Importantly,our procedure is highly efficient (∼ 90%) and delivers active,drug-inducible,and predictive human hepatocyte populations. View Publication

Functional endothelial-like cells (EC) have been successfully derived from different cell sources and potentially used for treatment of cardiovascular diseases; however,their relative therapeutic efficacy remains unclear. We differentiated functional EC from human bone marrow mononuclear cells (BM-EC),human embryonic stem cells (hESC-EC) and human induced pluripotent stem cells (hiPSC-EC),and compared their in-vitro tube formation,migration and cytokine expression profiles,and in-vivo capacity to attenuate hind-limb ischemia in mice. Successful differentiation of BM-EC was only achieved in 1/6 patient with severe coronary artery disease. Nevertheless,BM-EC,hESC-EC and hiPSC-EC exhibited typical cobblestone morphology,had the ability of uptaking DiI-labeled acetylated low-density-lipoprotein,and binding of Ulex europaeus lectin. In-vitro functional assay demonstrated that hiPSC-EC and hESC-EC had similar capacity for tube formation and migration as human umbilical cord endothelial cells (HUVEC) and BM-EC (Ptextgreater0.05). While increased expression of major angiogenic factors including epidermal growth factor,hepatocyte growth factor,vascular endothelial growth factor,placental growth factor and stromal derived factor-1 were observed in all EC cultures during hypoxia compared with normoxia (Ptextless0.05),the magnitudes of cytokine up-regulation upon hypoxic were more dramatic in hiPSC-EC and hESC-EC (Ptextless0.05). Compared with medium,transplanting BM-EC (n = 6),HUVEC (n = 6),hESC-EC (n = 8) or hiPSC-EC (n = 8) significantly attenuated severe hind-limb ischemia in mice via enhancement of neovascularization. In conclusion,functional EC can be generated from hECS and hiPSC with similar therapeutic efficacy for attenuation of severe hind-limb ischemia. Differentiation of functional BM-EC was more difficult to achieve in patients with cardiovascular diseases,and hESC-EC or iPSC-EC are readily available as off-the-shelf" format for the treatment of tissue ischemia." View Publication

The clinical use of human embryonic stem cells (hESCs) requires efficient cellular expansion that must be paired with an ability to generate specialized progeny through differentiation. Self-renewal and differentiation are deemed inherent hallmarks of hESCs and a growing body of evidence suggests that initial culture conditions dictate these two aspects of hESC behavior. Here,we reveal that defined culture conditions using commercial mTeSR1 media augment the expansion of hESCs and enhance their capacity for neural differentiation at the expense of hematopoietic lineage competency without affecting pluripotency. This culture-induced modification was shown to be reversible,as culture in mouse embryonic fibroblast-conditioned media (MEF-CM) in subsequent passages allowed mTeSR1-expanded hESCs to re-establish hematopoietic differentiation potential. Optimal yield of hematopoietic cells can be achieved by expansion in mTeSR1 followed by a recovery period in MEF-CM. Furthermore,the lineage propensity to hematopoietic and neural cell types could be predicted via analysis of surrogate markers expressed by hESCs cultured in mTeSR1 versus MEF-CM,thereby circumventing laborious in vitro differentiation assays. Our study reveals that hESCs exist in a range of functional states and balance expansion with differentiation potential,which can be modulated by culture conditions in a predictive and quantitative manner. Stem Cells 2015;33:1142-1152. View Publication

Human endothelial cells (ECs) and pericytes are of great interest for research on vascular development and disease,as well as for future therapy. This protocol describes the efficient generation of ECs and pericytes from human pluripotent stem cells (hPSCs) under defined conditions. Essential steps for hPSC culture,differentiation,isolation and functional characterization of ECs and pericytes are described. Substantial numbers of both cell types can be derived in only 2-3 weeks: this involves differentiation (10 d),isolation (1 d) and 4 or 10 d of expansion of ECs and pericytes,respectively. We also describe two assays for functional evaluation of hPSC-derived ECs: (i) primary vascular plexus formation upon coculture with hPSC-derived pericytes and (ii) incorporation in the vasculature of zebrafish xenografts in vivo. These assays can be used to test the quality and drug sensitivity of hPSC-derived ECs and model vascular diseases with patient-derived hPSCs. View Publication

Recent methodological advances have improved the ease and efficiency of generating human induced pluripotent stem cells (hiPSCs),but this now typically results in a greater number of hiPSC clones being derived than can be wholly characterized. It is therefore imperative that methods are developed which facilitate rapid selection of hiPSC clones most suited for the downstream research aims. Here we describe a combination of procedures enabling the simultaneous screening of multiple clones to determine their genomic integrity as well as their cardiac differentiation potential within two weeks of the putative reprogrammed colonies initially appearing. By coupling splinkerette-PCR with Ion Torrent sequencing,we could ascertain the number and map the proviral integration sites in lentiviral-reprogrammed hiPSCs. In parallel,we developed an effective cardiac differentiation protocol that generated functional cardiomyocytes within 10 days without requiring line-specific optimization for any of the six independent human pluripotent stem cell lines tested. Finally,to demonstrate the scalable potential of these procedures,we picked 20 nascent iPSC clones and performed these independent assays concurrently. Before the clones required passaging,we were able to identify clones with a single integrated copy of the reprogramming vector and robust cardiac differentiation potential for further analysis. View Publication

The recent technique of transducing key transcription factors into unipotent cells (fibroblasts) to generate pluripotent stem cells (induced pluripotent stem cells [iPSCs]) has significantly changed the stem cell field. These cells have great promise for many clinical applications,including that of regenerative medicine. Our findings show that iPSCs can be derived from human adipose-derived stromal cells (hASCs),a notable advancement in the clinical applicability of these cells. To investigate differences between two iPS cell lines (fibroblast-iPSC and hASC-iPSC),and also the gold standard human embryonic stem cell,we looked at cell stiffness as a possible indicator of cell differentiation-potential differences. We used atomic force microscopy as a tool to determine stem cell stiffness,and hence differences in material properties between cells. Human fibroblast and hASC stiffness was also ascertained for comparison. Interestingly,cells exhibited a noticeable difference in stiffness. From least to most stiff,the order of cell stiffness was as follows: hASC-iPSC,human embryonic stem cell,fibroblast-iPSC,fibroblasts,and,lastly,as the stiffest cell,hASC. In comparing hASC-iPSCs to their origin cell,the hASC,the reprogrammed cell is significantly less stiff,indicating that greater differentiation potentials may correlate with a lower cellular modulus. The stiffness differences are not dependent on cell culture density; hence,material differences between cells cannot be attributed solely to cell-cell constraints. The change in mechanical properties of the cells in response to reprogramming offers insight into how the cell interacts with its environment and might lend clues to how to efficiently reprogram cell populations as well as how to maintain their pluripotent state. View Publication

Rett syndrome (RTT) is a progressive neurologic disorder representing one of the most common causes of mental retardation in females. To date mutations in three genes have been associated with this condition. Classic RTT is caused by mutations in the MECP2 gene,whereas variants can be due to mutations in either MECP2 or FOXG1 or CDKL5. Mutations in CDKL5 have been identified both in females with the early onset seizure variant of RTT and in males with X-linked epileptic encephalopathy. CDKL5 is a kinase protein highly expressed in neurons,but its exact function inside the cell is unknown. To address this issue we established a human cellular model for CDKL5-related disease using the recently developed technology of induced pluripotent stem cells (iPSCs). iPSCs can be expanded indefinitely and differentiated in vitro into many different cell types,including neurons. These features make them the ideal tool to study disease mechanisms directly on the primarily affected neuronal cells. We derived iPSCs from fibroblasts of one female with p.Q347X and one male with p.T288I mutation,affected by early onset seizure variant and X-linked epileptic encephalopathy,respectively. We demonstrated that female CDKL5-mutated iPSCs maintain X-chromosome inactivation and clones express either the mutant CDKL5 allele or the wild-type allele that serve as an ideal experimental control. Array CGH indicates normal isogenic molecular karyotypes without detection of de novo CNVs in the CDKL5-mutated iPSCs. Furthermore,the iPS cells can be differentiated into neurons and are thus suitable to model disease pathogenesis in vitro. View Publication

PURPOSE To model keratoconus (KC) using induced pluripotent stem cells (iPSC) generated from fibroblasts of both KC and normal human corneal stroma by a viral method. METHODS Both normal and KC corneal fibroblasts from four human donors were reprogramed directly by delivering reprogramming factors in a single virus using 2A self-cleaving" peptides� View Publication

Cytosolic aldehyde dehydrogenase (ALDH),an enzyme responsible for oxidizing intracellular aldehydes,has an important role in ethanol,vitamin A,and cyclophosphamide metabolism. High expression of this enzyme in primitive stem cells from multiple tissues,including bone marrow and intestine,appears to be an important mechanism by which these cells are resistant to cyclophosphamide. However,although hematopoietic stem cells (HSC) express high levels of cytosolic ALDH,isolating viable HSC by their ALDH expression has not been possible because ALDH is an intracellular protein. We found that a fluorescent aldehyde,dansyl aminoacetaldehyde (DAAA),could be used in flow cytometry experiments to isolate viable mouse and human cells based on their ALDH content. The level of dansyl fluorescence exhibited by cells after incubation with DAAA paralleled cytosolic ALDH levels determined by Western blotting and the sensitivity of the cells to cyclophosphamide. Moreover,DAAA appeared to be a more sensitive means of assessing cytosolic ALDH levels than Western blotting. Bone marrow progenitors treated with DAAA proliferated normally. Furthermore,marrow cells expressing high levels of dansyl fluorescence after incubation with DAAA were enriched for hematopoietic progenitors. The ability to isolate viable cells that express high levels of cytosolic ALDH could be an important component of methodology for identifying and purifying HSC and for studying cyclophosphamide-resistant tumor cell populations. View Publication