UNIPROT:P04141 - FACTA Search

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Query: UNIPROT:P04141 (granulocyte-macrophage colony-stimulating factor)
6,790 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Dendritic cells (DC) can be generated by culture of adherent peripheral blood (PB) cells in the presence of granulocyte-macrophage colony-stimulating factor (GM-CSF) and interleukin-4 (IL-4). There is controversy as to whether these DC arise from proliferating precursors or simply from differentiation of monocytes. DC were generated from myeloid-enriched PB non-T cells or sorted monocytes. DC generated from either population functioned as potent antigen-presenting cells. Uptake of [3H]-thymidine was observed in DC cultured from myeloid-enriched non-T cells. Addition of lipopolysaccharide or tumor necrosis factor-alpha led to maturation of the DC, but did not inhibit proliferation. Ki67(+) cells were observed in cytospins of these DC, and by double staining were CD3(-)CD19(-)CD11c-CD40(-) and myeloperoxidase+, suggesting that they were myeloid progenitor cells. Analysis of the starting population by flow cytometry demonstrated small numbers of CD34(+)CD33(-)CD14(-) progenitor cells, and numerous granulocyte-macrophage colony-forming units were generated in standard assays. Thus, production of DC in vitro from adherent PB cells also enriches for progenitor cells that are capable of proliferation after exposure to GM-CSF. Of clinical importance, the yield of DC derived in the presence of GM-CSF and IL-4 cannot be expanded beyond the number of starting monocytes.
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PMID:Proliferation in monocyte-derived dendritic cell cultures is caused by progenitor cells capable of myeloid differentiation. 971 87

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

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 professional antigen-presenting cells that are required for the initiation of the immune response. DCs have been shown to be generated from CD34(+) pluripotent hematopoietic progenitor cells in the bone marrow and cord blood (CB), but relatively little is known about the effect of cryopreservation on functional maturation of DCs from hematopoietic stem cells. In this work we report the generation of DCs from cryopreserved CB CD34(+) cells. CB CD34(+) cells were cryopreserved at -80 degreesC for 2 days. Cryopreserved CB CD34(+) cells as well as freshly isolated CB CD34(+) cells cultured with granulocyte-macrophage colony-stimulating factor (GM-CSF)/stem cell factor (SCF)/tumor necrosis factor-alpha (TNF-alpha) for 14 days gave rise to CD1a+/CD4(+)/CD11c+/CD14(-)/CD40(+)/CD80(+ )/CD83(+)/CD86(+)/HLA-DR+ cells with dendritic morphology. DCs derived from cryopreserved CB CD34(+) cells showed a similar endocytic capacity for fluorescein isothiocyanate-labeled dextran and lucifer yellow when compared with DCs derived from freshly isolated CB CD34(+) cells. Flow cytometric analysis revealed that two CC chemokine receptors (CCRs), CCR-1 and CCR-3, were expressed on the cell surface of DCs derived from both cryopreserved and freshly isolated CB CD34(+) cells, and these DCs exhibited similar chemotactic migratory capacities in response to regulated on activation normal T-cell expressed and secreted. DCs derived from cryopreserved as well as freshly isolated CB CD34(+) cells were more efficient than peripheral blood mononuclear cells in the primary allogeneic T-cell response. These results indicate that frozen CB CD34(+) cells cultured with GM-CSF/TNF-alpha/SCF gave rise to dendritic cells which were morphologically, phenotypically and functionally similar to DCs derived from fresh CB CD34(+) cells.
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PMID:Generation of dendritic cells from fresh and frozen cord blood CD34+ cells. 991 53

Multiple myeloma (MM) cells express idiotypic proteins and other tumor-associated antigens which make them ideal targets for novel immunotherapeutic approaches. However, recent reports show the presence of Kaposi's sarcoma herpesvirus (KSHV) gene sequences in bone marrow dendritic cells (BMDCs) in MM, raising concerns regarding their antigen-presenting cell (APC) function. In the present study, we sought to identify the ideal source of DCs from MM patients for use in vaccination approaches. We compared the relative frequency, phenotype, and function of BMDCs or peripheral blood dendritic cells (PBDCs) from MM patients versus normal donors. DCs were derived by culture of mononuclear cells in the presence of granulocyte-macrophage colony-stimulating factor and interleukin-4. The yield as well as the pattern and intensity of Ag (HLA-DR, CD40, CD54, CD80, and CD86) expression were equivalent on DCs from BM or PB of MM patients versus normal donors. Comparison of PBDCs versus BMDCs showed higher surface expression of HLA-DR (P =.01), CD86 (P =. 0003), and CD14 (P =.04) on PBDCs. APC function, assessed using an allogeneic mixed lymphocyte reaction (MLR), demonstrated equivalent T-cell proliferation triggered by MM versus normal DCs. Moreover, no differences in APC function were noted in BMDCs compared with PBDCs. Polymerase chain reaction (PCR) analysis of genomic DNA from both MM patient and normal donor DCs for the 233-bp KSHV gene sequence (KS330233) was negative, but nested PCR to yield a final product of 186 bp internal to KS330233 was positive in 16 of 18 (88.8%) MM BMDCs, 3 of 8 (37.5%) normal BMDCs, 1 of 5 (20%) MM PBDCs, and 2 of 6 (33.3%) normal donor PBDCs. Sequencing of 4 MM patient PCR products showed 96% to 98% homology to the published KSHV gene sequence, with patient specific mutations ruling out PCR artifacts or contamination. In addition, KHSV-specific viral cyclin D (open reading frame [ORF] 72) was amplified in 2 of 5 MM BMDCs, with sequencing of the ORF 72 amplicon revealing 91% and 92% homology to the KSHV viral cyclin D sequence. These sequences again demonstrated patient specific mutations, ruling out contamination. Therefore, our studies show that PB appears to be the preferred source of DCs for use in vaccination strategies due to the ready accessibility and phenotypic profile of PBDCs, as well as the comparable APC function and lower detection rate of KSHV gene sequences compared with BMDCs. Whether active KSHV infection is present and important in the pathophysiology of MM remains unclear; however, our study shows that MMDCs remain functional despite the detection of KSHV gene sequences.
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PMID:Bone marrow and peripheral blood dendritic cells from patients with multiple myeloma are phenotypically and functionally normal despite the detection of Kaposi's sarcoma herpesvirus gene sequences. 1002 75

Current in vitro culture systems allow the generation of human dendritic cells (DCs), but the output of mature cells remains modest. This contrasts with the extensive amplification of hematopoietic progenitors achieved when culturing CD34(+) cells with FLT3-ligand and thrombopoietin. To test whether such cultures contained DC precursors, CD34(+) cord blood cells were incubated with the above cytokines, inducing on the mean a 250-fold and a 16,600-fold increase in total cell number after 4 and 8 weeks, respectively. The addition of stem cell factor induced a further fivefold increase in proliferation. The majority of the cells produced were CD34(-)CD1a- CD14(+) (p14(+)) and CD34(-)CD1a-CD14(-) (p14(-)) and did not display the morphology, surface markers, or allostimulatory capacity of DC. When cultured with granulocyte-macrophage colony-stimulating factor (GM-CSF) and interleukin-4 (IL-4), both subsets differentiated without further proliferation into immature (CD1a+, CD14(-), CD83(-)) macropinocytic DC. Mature (CD1a+, CD14(-), CD83(+)) DCs with high allostimulatory activity were generated if such cultures were supplemented with tumor necrosis factor-alpha (TNF). In addition, p14(-) cells generated CD14(+) cells with GM-CSF and TNF, which in turn, differentiated into DC when exposed to GM-CSF and IL-4. Similar results were obtained with frozen DC precursors and also when using pooled human serum AB+ instead of bovine serum, emphasizing that this system using CD34(+) cells may improve future prospects for immunotherapy.
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PMID:Long-term culture of human CD34(+) progenitors with FLT3-ligand, thrombopoietin, and stem cell factor induces extensive amplification of a CD34(-)CD14(-) and a CD34(-)CD14(+) dendritic cell precursor. 1009 Sep 33

Phagocytic cells with macrophage or dendritic cell phenotype, able to capture and ingest tumor cells, were derived in large numbers from peripheral blood mononuclear cells using two different activation procedures. Peripheral blood mononuclear cells were stimulated in nonadherent conditions in the presence of human AB serum with either granulocyte-macrophage colony-stimulating factor and dihydroxy-vitamin D3 for 7 days and with interferon-gamma for the last 18 hours to obtain activated macrophages (MAK) or with granulocyte-macrophage colony-stimulating factor and interleukin-13 for 7 days (with fresh interleukin-13 added on day 4) to obtain macrophage-dendritic cells (MAC-DC). A strong ability of MAC-DC to phagocytose yeasts was observed, in contrast to a low-intermediate phagocytosis capacity by MAK. Both CD14+ FCgammaR+ (FcgammaRI/CD64, FcgammaRII/CD32, FcgammaRIII/CD16) MAK and CD1a+/CD86+, CD14- MAC-DC were able to phagocytose whole tumor cells. However, only MAK phagocytosis was enhanced by FcgammaR engagement. MAK but not MAC-DC could lyse tumor cell in antibody-dependent cell cytotoxicity assays, via FcgammaRI. Thus, MAK as well as MAC-DC may represent valuable tools for different in vivo therapy strategies that do or do not include the use of monoclonal antibodies.
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PMID:Generation of phagocytic MAK and MAC-DC for therapeutic use: characterization and in vitro functional properties. 1021 Mar 33

Patients with head and neck squamous cell carcinoma (HNSCC) have increased levels of immune-suppressive peripheral blood CD34+ cells. This study showed that the peripheral blood CD34+ cells of HNSCC patients are capable of differentiating into dendritic cells. Because CD34+ cells can differentiate through several pathways into dendritic cell subpopulations, the intermediate cells through which the blood CD34+ cells of HNSCC patients differentiate were identified. After 6-7 days of culturing the CD34+ cells of HNSCC patients with granulocyte-macrophage colony-stimulating factor, stem cell factor, and tumor necrosis factor at, there appeared CD14+CD1a+ and a lesser proportion of CD14(-)CD1a+ cells resembling the precursor cells of the bipotential and committed dendritic cell differentiation pathways that have been described for cord blood CD34+ cells. To functionally analyze whether these populations were in fact precursor cells, they were isolated and cultured for an additional 10-12 days. Each of these populations was shown to function as precursor cells because they were able to develop into cells that resembled dendritic cells, although a higher proportion developed from the CD14-CD1a+ cells. In contrast, expression of the dendritic activation/maturation marker CD83 was highest on the cells that developed from CD14+CD1a+ cells. Thus, the CD34+ cells whose levels are increased in HNSCC patients can develop into both committed and bipotential dendritic precursor cells, which can subsequently give rise to dendritic cells.
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PMID:Dendritic cell differentiation pathways of CD34+ cells from the peripheral blood of head and neck cancer patients. 1033 90

Immunization with tumor-associated antigen pulsed dendritic cells (DC) has been shown to elicit both protective and therapeutic antitumor immunity in a variety of animal models and is currently being investigated for the treatment of cancer patients in clinical trials. In this study we show that DC can be generated from peripheral blood mononuclear cells of healthy donors as well as breast and melanoma cancer patients using granulocyte-macrophage colony-stimulating factor (GM-CSF) and interleukin-13 (IL-13) and that these DC have many of the same characteristics as DC differentiated using GM-CSF and IL-4. The DC generated in GM-CSF and IL-13 are CD14- and express high levels of the cell surface markers CD86, HLA-DR, and CD58, as do DC generated in GM-CSF and IL-4. The purity and yield of both DC populations are not significantly different. Furthermore, both populations of DC are effective at presentation of alloantigen as determined in a mixed lymphocyte response, and both are able to process and present soluble tetanus toxoid antigen to CD4+ T cells. Because we are interested in the generation of DC for antigen-specific cytotoxic T lymphocyte (CTL) generation, we compared the ability of peptide-pulsed DC differentiated in GM-CSF and IL-4 versus GM-CSF and IL-13 for the generation of influenza and MART-1 specific CTL. Both populations of DC induced CD3+ CD8+ CD4- and CD56- CTL, which could lyse the appropriate targets in an antigen-specific manner. Finally, both GM-CSF and IL-4 DC and GM-CSF and IL-13 DC yielded similar beta galactosidase expression levels after transduction with recombinant adenovirus containing the LacZ gene. These results suggest that DC generated in GM-CSF and IL-13 may be useful for immunotherapy and gene therapy protocols.
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PMID:IL-13 can substitute for IL-4 in the generation of dendritic cells for the induction of cytotoxic T lymphocytes and gene therapy. 1033 82

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