Cellular differentiation

About: Cellular differentiation is a research topic. Over the lifetime, 90966 publications have been published within this topic receiving 6099252 citations. The topic is also known as: Cellular differentiation & GO:0030154.

Conversion of embryonic stem cells into neuroectodermal precursors in adherent monoculture.

Abstract: Mouse embryonic stem (ES) cells are competent for production of all fetal and adult cell types. However, the utility of ES cells as a developmental model or as a source of defined cell populations for pharmaceutical screening or transplantation is compromised because their differentiation in vitro is poorly controlled. Specification of primary lineages is not understood and consequently differentiation protocols are empirical, yielding variable and heterogeneous outcomes. Here we report that neither multicellular aggregation nor coculture is necessary for ES cells to commit efficiently to a neural fate. In adherent monoculture, elimination of inductive signals for alternative fates is sufficient for ES cells to develop into neural precursors. This process is not a simple default pathway, however, but requires autocrine fibroblast growth factor (FGF). Using flow cytometry quantitation and recording of individual colonies, we establish that the bulk of ES cells undergo neural conversion. The neural precursors can be purified to homogeneity by fluorescence activated cell sorting (FACS) or drug selection. This system provides a platform for defining the molecular machinery of neural commitment and optimizing the efficiency of neuronal and glial cell production from pluripotent mammalian stem cells.

The development of neural stem cells

Abstract: The discovery of stem cells that can generate neural tissue has raised new possibilities for repairing the nervous system A rush of papers proclaiming adult stem cell plasticity has fostered the notion that there is essentially one stem cell type that, with the right impetus, can create whatever progeny our heart, liver or other vital organ desires But studies aimed at understanding the role of stem cells during development have led to a different view - that stem cells are restricted regionally and temporally, and thus not all stem cells are equivalent Can these views be reconciled?

Induction of th1 and th2 cd4+ t cell responses : the alternative approaches

Abstract: T helper lymphocytes can be divided into two distinct subsets of effector cells based on their functional capabilities and the profile of cytokines they produce. The Th1 subset of CD4+ T cells secretes cytokines usually associated with inflammation, such as IFN-gamma and TNF and induces cell-mediated immune responses. The Th2 subset produces cytokines such as IL-4 and IL-5 that help B cells to proliferate and differentiate and is associated with humoral-type immune responses. The selective differentiation of either subset is established during priming and can be significantly influenced by a variety of factors. One of these factors, the cytokine environment, has been put forward as the major variable influencing Th development and is already well reviewed by others. Instead, in the current review, we focus on some of the alternative approaches for skewing Th1/Th2 responses. Specifically, we discuss the effects on Th priming of (a) using altered peptide ligands as antigens, (b) varying the dose of antigen, and (c) altering costimulatory signals. The potential importance of each of these variables to influence immune responses to pathogens in vivo is discussed throughout.

Acquisition of Lymphokine-Producing Phenotype by CD4+ T Cells

Abstract: Naive CD4+ T cells when stimulated produce IL-2 as their major lymphokine. Upon priming, these cells develop into cells that produce either IFN gamma, TNF beta, and IL-2 or IL-4 and its congeners. The former cells are designated TH1-like, and the latter TH2-like. Here we review the regulation of the differentiation of naive CD4 cells into IFN gamma- or IL-4-producers. The dominant factors that determine such differentiation are lymphokines and other cytokines. IL-2 itself appears to be required for naive cells to develop into TH1- or TH2-like cells but is not deterministic of their differentiation fate. If IL-4 is also present during the priming period, the resultant CD4+ T cells produce IL-4 upon restimulation; the development of IFN gamma-producing cells is strikingly inhibited by IL-4. In the absence of IL-4, priming for IFN gamma-production occurs, but this is markedly enhanced by IL-12. The role of IFN gamma in enhancing priming for IFN gamma-production is not fully resolved. In some in vitro systems, it appears to act together with IL-12 to enhance such production. Anti-IFN gamma diminishes priming for IFN gamma production in vivo. Lymphokines also exert a "cross-regulatory" or inhibitory effect. As noted above, IL-4 strikingly diminishes priming for IFN gamma production, although this inhibitory effect is blunted in the presence of IL-12. IFN gamma similarly diminishes priming for IL-4 production; this effect is principally observed when low concentrations of IL-4 are used in the priming culture. Although other factors may play a role in the determination of lymphokine-producing phenotype, such as antigen dose, type of antigen-presenting cell, and expression of accessory molecules and hormones, these effects appear to be secondary to the dominant role of the lymphokines and cytokines.

Little evidence for developmental plasticity of adult hematopoietic stem cells.

Abstract: To rigorously test the in vivo cell fate specificity of bone marrow (BM) hematopoietic stem cells (HSCs), we generated chimeric animals by transplantation of a single green fluorescent protein (GFP)-marked HSC into lethally irradiated nontransgenic recipients. Single HSCs robustly reconstituted peripheral blood leukocytes in these animals, but did not contribute appreciably to nonhematopoietic tissues, including brain, kidney, gut, liver, and muscle. Similarly, in GFP+:GFP- parabiotic mice, we found substantial chimerism of hematopoietic but not nonhematopoietic cells. These data indicate that "transdifferentiation" of circulating HSCs and/or their progeny is an extremely rare event, if it occurs at all.