UNIPROT:P06126 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P06126 (CD1a)
2,221 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

This study identifies type I IFNs as activating cytokines in a serum-free system in which human dendritic cells (DC) were generated from CD34+ progenitor cells. After 14 days of culture in GM-CSF, TNF-alpha, and IL-4, CD34+ progenitors gave rise to a population of large, immature DC expressing CD1a and CD11b but lacking CD14, CD80, CD83, CD86, and CMRF44. During the next 2 wk, this population spontaneously matured into nonadherent, CD1a(low/-), CD11b(low/-), CD14-, CD80+, CD83+, CD86+, CMRF44+ DC with high allostimulatory activity in the MLR. To examine which factors influenced this maturation, 25 different cytokines or factors were added to the immature DC culture. Only type I IFNs (alpha or beta) accelerated this maturation in a dose-dependent manner, so that after only 3 days the majority of large cells acquired the morphology, phenotype, and function characteristics of mature DC. Furthermore, supernatants from cultures containing spontaneously maturing DC revealed low levels of endogenous IFN production. Because of the similarity of the activation of DC in our culture system with the phenotypic and functional changes observed during Langerhans cells activation and migration in vivo, we investigated the effect of IFN-alpha on human Langerhans cell migration. IFN-alpha also activated the migration of human split skin-derived DC, demonstrating that this effect was not limited to DC derived in vitro from hemopoietic progenitor cells. DC activation by type I IFNs represents a novel mechanism of immunomodulation by these cytokines, which could be important during antiviral responses and autoimmune reactions.
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PMID:Type I IFNs enhance the terminal differentiation of dendritic cells. 971 65

We examined the effect of interleukin (IL)-4 or CD40 ligation on the differentiation and maturation of CD1a+CD14- and CD1a-CD14+ dendritic cell (DC) precursors. Cord blood CD34+ cells were cultured with granulocyte-macrophage colony-stimulating factor (GM-CSF) and tumor necrosis factor alpha (TNF-alpha), to which stem cell factor and Flt-3 ligand were added for 5 days. Phenotypic analysis of DC precursors on culture day 7 showed that CD1a+CD14- cells expressed higher CD11c and CD80 levels and lower CD116/GM-CSFR and CCR-5 levels than their CD1a-CD14+ counterparts. Culturing CD1a+CD14- precursors with GM-CSF and TNF-alpha resulted in DC with heterogeneous CD1a, HLA;SMDR (DR), CD11b, and CD83 expression, 10% of which acquired CD14. IL-4 and CD40 ligation affected their differentiation in contrasting ways: IL-4 induced CD1ahiCD14-DRloCD11b+CD83-S100+ DC with reduced MLR-stimulating capacity, whereas CD40 ligation led to CD1alo/-CD14-CD40-DRhiCD11b-CD83+S100+/- DC with stronger MLR-stimulating capacity. Also, both IL-4 and CD40 ligation promoted ReIB expression and nuclear translocation. When CD1a-CD14+ precursors were maintained in only the presence of GM-CSF and TNF-alpha, this led to mixed populations of adherent macrophages and nonadherent CD1a-CD14+ monocytes, and of CD1a+CD14- and CD1a+CD14+ DC, which were DRloCD11b+CD83-S100-. IL-4 or CD40 ligation prevented their differentiation into macrophages and resulted in DC with phenotypes close to those issued from CD1a+CD14- precursors, with only a minority staying CD14+ but most being S100-; their MLR-stimulating capacity also increased but remained lower than that of DC differentiated from CD1a+CD14- precursors. Thus, IL-4 or CD40 ligation induced CD1a+CD14- and CD1a-CD14+ DC precursors to differentiate into phenotypically close but functionally different DC populations, suggesting that DC function is primarily determined by their origin. The heterogeneity of DC should then be related to different developmental pathways and to different stages of maturation/activation.
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PMID:IL-4 and CD40 ligation affect differently the differentiation, maturation, and function of human CD34+ cell-derived CD1a+CD14- and CD1a-CD14+ dendritic cell precursors in vitro. 971 64

Dendritic cells (DC) are the main stimulators of primary T cell responses. Very little is known about DC in cord blood (CB), and whether they are involved in the low incidence and severity of GVHD following CB transplantation. Here, CBDC were identified as a HLA-DR+/lineage marker (lin; CD3, CD11b, CD14, CD16, CD19, CD34, CD56 and glycophorin A antigens) negative population, representing 0.3 +/- 0.1% (mean +/- s.d.; n = 15) of CB mononuclear cells. CBDC expressed the CD4, CD11a, CD18, CD45RA, CD50 and CD54 antigens but revealed no expression of the CD1a, CD11c, CD40, CD45R0, CD58, CD83, CD86 and CD102 antigens. Immunomagnetically enriched CBDC showed potent allostimulatory activity for CB T cells. Thus, CBDC are functionally competent and resemble in their immature/resting state CD11c- DC in peripheral blood.
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PMID:Functional competence of dendritic cells in human umbilical cord blood. 971 87

Dendritic cells (DC) that are stimulated with inflammatory mediators can maturate and migrate from nonlymphoid tissues to lymphoid organs to initiate T cell-mediated immune responses. This migratory step is closely related to the maturation of the DC. In an attempt to identify chemokine receptors that might influence migration and are selectively expressed in mature DC, we have discovered that the chemokine receptor, EBI1/CCR7, is strikingly up-regulated upon maturation in three distinct culture systems: 1) mouse bone marrow-derived DC, 2) mouse epidermal Langerhans cells, and 3) human monocyte-derived DC. The EBI1/CCR7 expressed in mature DC is functional because ELC/MIP-3beta, recently identified as a ligand of EBI1/CCR7, induces a rise in intracellular free calcium concentrations and directional migration of human monocyte-derived mature DC (HLA-DRhigh, CD1a(low), CD14-, CD25+, CD83+, and CD86high) in a dose-dependent manner, but not of immature DC (HLA-DRlow, CD1a(high), CD14-, CD25-, CD83-, and CD86-). In contrast, macrophage inflammatory protein-1alpha (MIP-1alpha), monocyte chemotactic protein-3 (MCP-3), and RANTES are active on immature DC but not on mature DC. Thus, it seems likely that MIP-1alpha, MCP-3, and RANTES can mediate the migration of immature DC located in peripheral sites, whereas ELC/MIP-3beta can direct the migration of Ag-carrying DC from peripheral inflammatory sites, where DC are stimulated to up-regulate the expression of EBI1/CCR7, to lymphoid organs. It is postulated that different chemokines and chemokine receptors are involved in DC migration in vivo, depending on the maturation state of DC.
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PMID:EBI1/CCR7 is a new member of dendritic cell chemokine receptor that is up-regulated upon maturation. 974 76

Most monocyte-derived dendritic cells (DC) display CD1a, like Langerhans cells (LC) and some dermal DC, but their relationship with these skin DC remains unclear. To address this issue, we studied the expression of different antigens characteristic of skin DC and of monocyte/macrophages in CD1a+ and CD1a- monocyte-derived DC. Their phenotype indicated that they may be related to dermal DC rather than to LC, i.e., they were all CD11b-positive, and 72% were Factor XIIIa-positive, but they did not express E-cadherin nor VLA-6. It is interesting that CD1a+ and CD1a-cells showed intracytoplasmic granules that were different from LC Birbeck granules. These phenotypical and ultrastructural features are comparable to those of CD14-derived DC obtained from cord blood precursors [C. Caux et al. J. Exp. Med. 184, 695-706]. These results show a close relationship between these two in vitro models, which are both related to dermal DC.
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PMID:Monocyte-derived dendritic cells have a phenotype comparable to that of dermal dendritic cells and display ultrastructural granules distinct from Birbeck granules. 976 29

The transitional stages in the relationship between sentinel monocytes and messenger dendritic cells that are active in adaptive immunity, are, as yet, unclear. To explore these events, 2-hr adherent peripheral blood mononuclear cells were used either as monocytes, or cultured for 7 days with granulocyte-macrophage colony-stimulating factor (GM-CSF) and interleukin-4 (IL-4) to generate dendritic cells, and the phenotypic features and relationship of the two cell populations was investigated using an extensive panel of monoclonal antibodies (mAbs). The features of the shift from monocyte to dendritic cell were also examined by daily phenotyping during the 7-day culture period. Twenty-five mAbs, most of which recognized known CD molecules, bound both monocytes and dendritic cells equally, whereas 19 mAbs exhibited differential staining. Four molecules not previously reported on dendritic cells were documented: CD87, CD98, CD147 and CD148. Seven cell-surface molecules (HLA-DQ, CD1a, CD13, CD30, CD43, CD63 and CD86) were expressed either at very low levels or not at all on monocytes, but had a strikingly increased expression on dendritic cells, suggesting a role in antigen presentation. The kinetics of monocyte to dendritic cell transition revealed a rapid activation phase within the first 24 hr, with a considerable increase in expression of the activation markers HLA-DR, CD13, CD14 and CD98; this was followed by a down-regulation of CD14 and a more gradual development of the other dendritic cell features over the remaining 6 days, with steady increases in CD1a, CD18, CD43, CD86, HLA-DR and HLA-DQ. Thus, these studies have demonstrated four novel components of the dendritic cell, and have documented the dynamic multistep nature of the process whereby an antigen-presenting dendritic cell phenotype may emerge from a monocyte precursor.
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PMID:From sentinel to messenger: an extended phenotypic analysis of the monocyte to dendritic cell transition. 976 44

The CMRF-44 monoclonal antibody (MoAb) recognizes an intermediate stage of blood dendritic cell (DC) differentiation as well as mature CD83+ blood DC. Here we describe the use of the CMRF-44 MoAb to monitor the in vitro development of DC-like cells from peripheral blood mononuclear cells. Neither granulocyte-macrophage colony-stimulating factor (GM-CSF) nor GM-CSF plus tumor necrosis factor-alpha (TNF-alpha) supported the development of CMRF-44+ cells. However, GM-CSF plus interleukin (IL)-4 generated a substantial number of CMRF-44+ cells among the heterogeneous CD14- myeloid cell population, produced after 7 or 10 days of culture. The addition of TNF-alpha to GM-CSF+IL-4 on the fifth day of culture enhanced the generation of CMRF-44+ cells from days 7 to 14. A concentration of 50 U/mL of IL-4 was sufficient to allow the development of CMRF-44+ cells. The presence of GM-CSF was essential, but a wide range of concentrations (50-800 U/mL) was effective for supporting IL-4-induced generation of CMRF-44+ cells. TNF-alpha at concentrations of 20 or 50 ng/mL induced a maximal increase in the number of CMRF-44+ cells. The CMRF-44+ DCs generated in the presence of GM-CSF+IL-4 were large, irregularly shaped cells with variable CD1a expression and have CD83 transcripts but no CD83 surface expression. Additional TNF-alpha treatment induced prominent dendritic processes and surface expression of CD83 on CMRF-44+ DCs. The CMRF-44+ DCs generated in GM-CSF+IL-4 showed higher allostimulatory activity than CMRF-44 cells but were less efficient at processing and presenting soluble antigen to T-lymphocyte lines. TNF-alpha treatment reduced antigen uptake but increased the allostimulatory activity of CMRF-44+ DCs. CMRF-44+ DC differentiation from blood CD14+ monocytes was not radiosensitive and thus does not involve cell division. We conclude that the MoAb CMRF-44 identifies both intermediate and fully mature stages of monocyte-DC differentiation and may be a useful marker in establishing the optimal timing for antigen loading of in vitro-generated monocyte-derived DCs.
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PMID:Generation of CMRF-44+ monocyte-derived dendritic cells: insights into phenotype and function. 984 82

The escape of malignant cells from the immune response against the tumor may result from a defective differentiation or function of professional antigen-presenting cells (APC), ie, dendritic cells (DC). To test this hypothesis, the effect of human renal cell carcinoma cell lines (RCC) on the development of DC from CD34(+) progenitors was investigated in vitro. RCC cell lines were found to release soluble factors that inhibit the differentiation of CD34(+) cells into DC and trigger their commitment towards monocytic cells (CD14(+)CD64(+)CD1a-CD86(-)CD80(-)HLA-D Rlow) with a potent phagocytic capacity but lacking APC function. RCC CM were found to act on the two distinct subpopulations emerging in the culture at day 6 ([CD14(+)CD1a-] and [CD14(-)CD1a+]) by inhibiting the differentiation into DC of [CD14(+)CD1a-] precursors and blocking the acquisition of APC function of the [CD14(-)CD1a+] derived DC. Interleukin-6 (IL-6) and macrophage colony-stimulating factor (M-CSF) were found to be responsible for this phenomenon: antibodies against IL-6 and M-CSF abrogated the inhibitory effects of RCC CM; and recombinant IL-6 and/or M-CSF inhibited the differentiation of DC similarly to RCC CM. The inhibition of DC differentiation by RCC CM was preceeded by an induction of M-CSF receptor (M-CSFR; CD115) and a loss of granulocyte-macrophage colony-stimulating factor receptor (GM-CSFR; CD116) expression at the surface of CD34(+) cells, two phenomenon reversed by anti-IL-6/IL-6R and anti-M-CSF antibodies, respectively. Finally, a panel of tumor cell lines producing IL-6 and M-CSF induced similar effects. Taken together, the results suggest that the inhibition of DC development could represent a frequent mechanism by which tumor cells will escape immune recognition.
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PMID:Inhibition of the differentiation of dendritic cells from CD34(+) progenitors by tumor cells: role of interleukin-6 and macrophage colony-stimulating factor. 984 45

Since dendritic cells (DCs) are the most professional antigen-presenting cells, (Schuler et al., 1997), increasing interest in their use in clinical approaches has been observed. (Nestle et al., 1998; Murphy G. et al., 1996). We have developed an ex vivo standardized process for the generation of dendritic-like cells (MAC-DCs) from human blood circulating monocytes. Human monocytes can differentiate into very different functional cells according to the conditions of culture, media and cytokines used. In the present study, we demonstrate that both pure monocytes and mononuclear cells differentiate into DCs when they are grown in defined medium AIM-V in the presence of granulocyte-macrophage colony-stimulating factor (GM-CSF) plus IL13 and in approved biocompatible non-adherent bags. Quality and functional controls of the immature DCs obtained rely on bacterial sterility, viability, morphology and recovery. The MAC-DCs also present an immature DC phenotype with a low expression of CD14 and CD64, and high expression of MHC-I, MHC-II and CD40. They also express B7 costimulatory molecules (CD80, CD86), CD83, and CD1a molecules. They induce strong allogenic T-cell proliferation (mixed lymphocyte reaction as well as proliferation of autologous memory T lymphocytes when incubated in the presence of recall antigens (tuberculosis, Candida albicans, and tetanus toxoid). They also show an increase in phagocytic uptake of yeast, tumour cells and debris. The global closed system which, under reproducible good medical practice (GMP) conditions, enables the production of dendritic cells of clinical quality, has been optimized ("Vac Cell Processor"). It contains all bags, connections, media, reagents, washing solutions, control antibodies, standard operating procedures, data management, traceability and help in the form of dedicated software.
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PMID:Monocyte-derived dendritic cells: development of a cellular processor for clinical applications. 985 16

Dendritic cells (DCs) are pivotal for antigen presentation, T-cell priming and B-cell functions. Few studies have been carried out on DCs in human diseases, partly because the current procedures used for DC preparation include elaborate negative selection with monoclonal antibodies (MoAb) and prolonged culture in cytokine-enriched milieu, which may influence DC functions. Using physical density and their adherent properties, DCs were prepared from the blood of healthy subjects. Approximately 2% of human blood mononuclear cells (MNC) were shown to consist of DCs, yielding DCs of 80-90% purity. They expressed markers related to DCs (CD1a, CD11c, CD32 and CD83), costimulatory molecules (CD40, CD80, CD86), human leucocyte antigen (HLA) class I and II molecules and inducible nitric oxide (NO) synthase (NOS2), and lacked lymphocyte and monocyte markers (CD3, CD19, CD20, CD56 and CD14). Compared with blood MNC and T cells, DCs showed a high level of spontaneous proliferation and nitric oxide production, as well as strong proliferative responses in mixed leucocyte reactions. Enzyme-linked immunospot (ELISPOT) assays revealed higher levels of interleukin (IL)-4-, IL-10- and interferon-gamma (IFN-gamma)-secreting cells among DCs than among MNC or T cells obtained from the same blood specimens, while levels of tumour necrosis factor-alpha (TNF-alpha)- and IL-6-secreting cells did not differ. The results demonstrate that the method used is fast, effective and competitively priced, and should be useful for studies of DCs in disease states.
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PMID:Phenotypic and functional properties of dendritic cells isolated from human peripheral blood in comparison with mononuclear cells and T cells. 1007 22

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