Rat monocyte-derived dendritic cells function and migrate in the same way as isolated tissue dendritic cells

Dendritic cells (DC) are the most potent antigen-presenting cells and are therefore useful to induce immune responses against tumor cells in patients. DC can be generated in vitro from monocytes using GM-CSF and IL-4, the so-called monocyte-derived DC (MoDC). To achieve antitumor responses, MoDC must be able to migrate to the draining lymph nodes after injection to induce cytotoxic T cells. Therefore, we studied migration of MoDC in a rat model. Functional rat MoDC were generated from PVG-RT7B rats and injected subcutaneously into PVG rats. These rat strains differ only at one epitope of the leukocyte-common antigen, which can be recognized by the antibody His 41. The advantage is that migrated cells can be detected in the draining lymph nodes by staining sections with His 41+; thus, migration is not influenced by labeling procedures. Rat MoDC migrated to the T-cell areas of the draining lymph nodes, just as isolated Langerhans cells or spleen DC do. In contrast, monocytes also migrated to the B-cell areas and the medulla.     

Differentiation and activation of equine monocyte‐derived dendritic cells are not correlated with CD206 or CD83 expression

Dendritic cells (DC) are the main immune mediators inducing primary immune responses. DC generated from monocytes (MoDC) are a model system to study the biology of DC in vitro, as they represent inflammatory DC in vivo. Previous studies on the generation of MoDC in horses indicated that there was no distinct difference between immature and mature DC and that the expression profile was distinctly different from humans, where CD206 is expressed on immature MoDC whereas CD83 is expressed on mature MoDC. Here we describe the kinetics of equine MoDC differentiation and activation, analysing both phenotypic and functional characteristics. Blood monocytes were first differentiated with equine granulocyte–macrophage colony‐stimulating factor and interleukin‐4 generating immature DC (iMoDC). These cells were further activated with a cocktail of cytokines including interferon‐γ) but not CD40 ligand to obtain mature DC (mMoDC). To determine the expression of a broad range of markers for which no monoclonal antibodies were available to analyse the protein expression, microarray and quantitative PCR analysis were performed to carry out gene expression analysis. This study demonstrates that equine iMoDC and mMoDC can be distinguished both phenotypically and functionally but the expression pattern of some markers including CD206 and CD83 is dissimilar to the human system.     

Glucocorticoids modulate the development of dendritic cells from blood precursors

Dendritic cells (DC) are professional antigen-presenting cells, capable of priming naive T cell responses. Glucocorticoids (GC) are frequently used in asthmatic patients. In this study we describe the effects of GC on the development and function of monocyte-derived DC (MoDC) in vitro and in vivo. Monocytes from healthy individuals were isolated and incubated with granulocyte-macrophage colony-stimulating factor (GM-CSF) and IL-4 for 6 days, to induce maturation into MoDC. To study the role of GC on DC differentiation in vitro cells were incubated with dexamethasone at different stages of MoDC development. At day 6 cells were characterized phenotypically by flow cytometry and functionally in an allogeneic mixed leucocyte reaction. To study the effect of GC in vivo patients with mild/moderate atopic asthma were selected. In one group no GC were used, whereas the other group used inhalation GC. MoDC from these patients were generated as described above and tested functionally. Incubation of MoDC or its peripheral blood precursors with dexamethasone decreased the accessory potency dose-dependently. The functional differences could not be explained by the changes in the expression of MHC II and the costimulatory molecules CD40 and CD86. The relevance of this mechanism was confirmed for the in vivo situation as well. MoDC from patients using inhalation GC showed a decreased accessory potency. These data suggest a modulatory effect of GC therapy at the level of the peripheral blood monocyte. The results indicate that GC influence DC development and function in vitro as well as in vivo.     

Interferon-alpha disables dendritic cell precursors: dendritic cells derived from interferon-alpha-treated monocytes are defective in maturation and T-cell stimulation

Dendritic cells (DC) can be derived from monocytes in vitro by culture with granulocyte-macrophage colony-stimulating factor (GM-CSF) and interleukin-4 (IL-4). It is unknown whether this regimen reflects DC differentiation from blood precursors under physiological conditions. Induction of DC development from monocytes by interferon-alpha (IFN-alpha) may occur in vivo during infection or inflammation and thus may represent a more physiological approach to DC differentiation in vitro. Here, we show that incubation of GM-CSF-cultured monocytes with IFN-alpha does not induce DC differentiation: cells maintain their original phenotype and cytokine secretion pattern. Even after stimulation with pro-inflammatory or T-cell-derived activation signals, IFN-alpha-treated monocytes do not develop DC characteristics. Addition of IL-4 during stimulation of IFN-alpha-treated monocytes results in the rapid development of DC-like cells expressing co-stimulatory molecules, CD83 and chemokine receptor CCR7, indicating that some degree of developmental plasticity is preserved. However, DC pre-activated with IFN-alpha are less effective in inducing allogeneic or antigen-specific autologous T-cell proliferation, produce less IL-12 and express lower levels of CCR7 compared to DC generated by culture with GM-CSF and IL-4. Incubating GM-CSF-cultured monocytes simultaneously with IFN-alpha and IL-4 does not affect phenotypic maturation of DC, but reduces IL-12 production upon pro-inflammatory activation. We conclude that: (1) IFN-alpha fails to induce DC differentiation and thus cannot replace IL-4 in generating DC from monocytes in vitro; and (2) the presence of IFN-alpha prior to or during differentiation of DC from monocyte precursors alters their response to maturation stimuli and may affect their capacity to stimulate T helper type 1 immune responses in vivo.     

An improved method to generate equine dendritic cells from peripheral blood mononuclear cells: divergent maturation programs by IL-4 and LPS

Equine dendritic cells (eqDC) can be generated from peripheral blood monocytes by propagation in GM-CSF and IL-4. Despite similarities with the generation of human DC, we found significant improvements for eqDC generation and functional influences on eqDC maturation. The fractionation of peripheral blood mononuclear cells (PBMC) by two subsequent gradients at densities of 1.090 and 1.077 as well as an adherence step in AIM V((R)) medium on dishes coated with extracellular matrix components (Primaria) improved the purity and yield of DC. After 3 days, eqDC cultures with GM-CSF alone developed into three subsets of (i) MHC II(neg) cells, (ii) MHC II(low) immature, endocytic cells and (iii) MHC II(high) spontaneously mature, non-endocytic DC. The immature DC fraction of the GM-CSF cultures matured, as detected by MHC II up-regulation, upon LPS exposure overnight. DC cultures in GM-CSF plus IL-4 resulted in higher cell yields, a loss of the immature MHC II(low) population but increased mature MHC II(high) DC, suggesting maturation. However, the MHC II(high) DC fraction was still endocytically active and did not lose their endocytic function after LPS treatment. They marginally up-regulated MHC II expression but this did not result in an enhanced stimulation of an allogeneic mixed lymphocyte reaction. However, LPS treatment clearly induced mRNA for IL-12p35 and p40, which was not observed by addition of IL-4 alone. Together our data indicate that IL-4 and LPS induce two different maturation programs. IL-4 induces a semi-maturation where the cells are still endocytic, which can be further matured to secrete cytokines in a second step by LPS.     

Differentiation of human dendritic cells from monocytes in vitro

Since either macrophages (M?) or dendritic cells (DC) differentiate from monocytes (MO) depending on culture conditions, we investigated the relationship of the DC and M? differentiation pathways. Culturing MO-enriched blood mononuclear cells with M? colony-stimulating factor (M-CSF) or with granulocyte/M? (GM)-CSF induced M? with a different morphology and CD14/CD1a expression. In contrast, in cultures with GM-CSF and interleukin (IL)-4, cells rapidly became nonadherent and acquired DC morphology, ultrastructure, CD1a expression, and most DC markers; they lost membrane CD14 and CD64 and capacity of phagocytosis, displayed less CD68 than M?, but retained nonspecific esterase activity. These DC directly developed from MO without proliferation inasmuch as only day 0 FACS-sorted MO, but not small CD14^? cells, differentiated into DC when cultured with GM-CSF and IL-4, or to M? with M-CSF. While overall cell numbers declined, DC numbers plateaued from culture day 2 onwards, indicating that most had differentiasted by then. This differentiation was radioresistant and occurred without [³H]thymidine incorporation. Commitment to differentiate into DC with GM-CSF and IL-4 was irreversible by day 2, since discontinuing IL-4 at this point did not revert cells to M?. Alternatively, cells rapidly converted to DC when IL-4 was added from day 2 to cultures initiated with GM-CSF only. If cultures were initiated with M-CSF and switched to GM-CSF and IL-4 after 2 or 5 days, about half of the cells still converted to DC. Thus, the capacity of MO and even of M? to differentiate into DC was conserved for at least this period. The increased capacity to stimulate the mixed leukocyte reaction correlated with the relative number of CD1a^? cells at any time and under each condition tested, a confirmation that these cells functionally qualify as DC. Thus, MO and even M? can be directed to differentiate into DC depending on the cytokine microenvironment.     

Stimulatory and inhibitory differentiation of human myeloid dendritic cells

Dendritic cells (DCs) play a critical obligate role in presenting antigens to T cells for activation. In the process, upon antigen capture, DCs undergo maturation and become more stimulatory. Human myeloid DCs can be generated from various sources, including blood, bone marrow, and CD34(+) stem cells. As such, plastic-adherent monocytes from circulation have served as a ready source for generating myeloid DCs in culture in granulocyte-macrophage colony-stimulating factor (GM-CSF) and interleukin-4 (IL-4) for translational research in active specific immunotherapy, especially in cancer, with the belief that they are essentially stimulatory or "immunogenic." Here we show that in vitro cultures of plastic-adherent circulating monocytes in GM-CSF and IL-4 followed by further maturation in interferon-gamma plus bacterial superantigens (DC maturing agents) can give rise to two diametrically opposite types of DCs-one stimulatory and another inhibitory. The stimulatory DCs express higher amounts of costimulatory molecules, synthesize IL-12, and efficiently stimulate naive allogeneic T cells in mixed lymphocyte reaction (MLR). The inhibitory DCs, in contrast, express lower concentrations of the critical costimulatory molecules, synthesize large amounts of IL-10, and are nonstimulatory in allogeneic primary MLR. Moreover, while the stimulatory DCs further amplify proliferation of T cells in lectin-driven proliferation assays, the inhibitory DCs totally block T cell proliferation in similar assays, in vitro. Most interestingly, neutralization of the endogenously derived IL-10 with anti-IL-10 antibody in DC cultures repolarizes the inhibitory DCs toward stimulatory phenotype. Accordingly, these observations have important implications in translational research involving myeloid DCs.     

In vitro differentiation of porcine blood CD163- and CD163+ monocytes into functional dendritic cells

Swine monocytes constitute a heterogeneous cell population containing subsets with distinct functional capacities or representing different maturational stages. Based on the expression of CD163, we have recently identified two monocyte subpopulations. In this study, we investigate the ability of both CD163- and CD163+ monocytes to differentiate into dendritic cells (DCs) in the presence of GM-CSF and IL-4. Monocyte differentiation into DC is accompanied by an up-regulation of the expression of swine leukocyte antigen (SLA) I, SLA II and CD80/86 molecules, and a decrease in the expression of CD14, CD16 and CD163. These DC express the pan-myeloid marker SWC3 and display typical dendritic cytoplasmic projections. When monocytes are split into CD163+ and CD163- cells, both subsets give rise to DC. However, compared to CD163- monocyte-derived DC (MoDC), CD163+ MoDC appear to have reached a more advanced stage of maturation, expressing higher levels of SLA II and CD80/86 and inducing more efficiently proliferation of T cells to recall antigens and alloantigens.     

Analysis of methods for the generation of dendritic cells from human peripheral blood monocytes

Dendritic cells (DC) are highly efficient antigen-presenting cells that initiate the primary immune response. Several laboratories have developed culture systems for human DC from peripheral blood monocytes. Most of these studies have used fetal calf serum (FCS) containing culture conditions that are inappropriate for human application. GM-CSF and IL-4 were used to make immature DC. The monocyte-conditioned medium (MCM) was used to induce the final maturation of DC. Using the previously described methods, the quality of MCM has unpredictable variations. Therefore using a defined cocktail of growth factors for the generation of mature DC would be advantageous for experimental as well as clinical purposes. In this study, it is suggested that combinations of both GM-CSF/IL-4 or GM-CSF/IL-13 could be used as the first-step culture to produce immature DC, and that cytokine cocktail (GM-CSF, IL-4, IL-1beta, TNF-alpha, IL-6, PGE2) was as efficient as MCM for the second step-culture to produce fully maturated DC. Here, we have generated an easily reproducible culture system for DC that allows for the generation of large amounts of immature and mature DC, and we also now have established the method in a FCS-free system that is suitable for clinical use.     

Granulocyte-macrophage colony-stimulating factor (GM-CSF) has opposing effects on the capacity of monocytes versus monocyte-derived dendritic cells to stimulate the antigen-specific proliferation of a human T cell clone

GM-CSF is widely used in combination with IL-4 to differentiate monocytes into potent T cell stimulatory cells, referred to as monocyte-derived dendritic cells (MoDC). These cytokines further increased the stimulatory function of MoDC when present during their incubation with antigen, as determined by the proliferative response of an allergen-specific T cell clone. Conversely, the incubation of freshly isolated monocytes with antigen in the presence of GM-CSF or GM-CSF and IL-4 strongly inhibited the specific stimulation of the T cells, compared with monocytes pulsed in the absence of cytokines. This suppression was partly due to the secretion of prostaglandin E2 (PGE2) and IL-10 by GM-CSF-treated monocytes, since the combined use of indomethacin and anti-IL-10 antibodies during GM-CSF incubation and antigen pulsing restored T cell growth to about 65% of control levels. As confirmed by culture supernatant transfer experiments, maximal inhibition of T cell stimulation was also dependent on the direct contact between the T cells and GM-CSF-treated monocytes during antigen presentation. Collectively, these results imply that GM-CSF can either inhibit or enhance the re-stimulation of primed T cells by antigen-presenting monocytes or MoDC, respectively.     

Increased expression of intracellular HLA-DM but not on the surface of blood monocyte-derived dendritic cells during maturation

Cutaneous dendritic cells (DCs), Langerhans cells (LCs) and dermal dendritic cells (DDCs), are present in an immature state. The maturation of DCs is crucial for initiating an immune response. Since HLA-DM has an important role for antigen presentation, an increase in HLA-DM expression according to the maturation of blood monocyte-derived dendritic cells (MoDCs), which have similar characteristics with DDCs, is expected. Therefore, the aim of this study was to determine whether or not HLA-DM expression in MoDCs is related to maturation at each culture day (from day 0 to day 13) by flow cytometry. This was compared with the functional changes related to the maturation of MoDCs. MoDCs were generated by culturing human peripheral blood monocytes in the presence of GM-CSF and IL-4 for 7 days, which were followed by subsequent treatment with a cytokine cocktail (GM-CSF, IL-4, IL-1beta, TNF-alpha, IL-6 and PGE2) for the maturation of MoDCs. The intracellular HLA-DM was expressed in the immature MoDC. A sudden 3 to 8 fold increase in the intracellular HLA-DM expression was observed after treatment with a cytokine cocktail. HLA-DM was weakly expressed on the surface of the immature MoDC, but it seemed to be decreased with maturation. This study indicated that the intracellular HLA-DM expression increased, but not on the MoDC surface during maturation. This was despite the fact that HLA-DM expression was noted not only on the surface but also in the intracellular in the MoDC.     

Effects of arsenic on porcine dendritic cells in vitro

Exposure to arsenic (As) is an ongoing, and in some places increasing, health problem. Still, however, the effects of As exposure on the immune system are not well understood. Dendritic cells (DC) are a critical immune cell that bridges the innate and adaptive immune systems. To determine the impact of inorganic (i)As exposure on DC, the effects of (geo)anthropogenically relevant levels of NaAsO₂ on the function of porcine monocyte-derived DC (MoDC) were evaluated in an in vitro model. The results showed a low dose of iAs reduced the phagocytic capacity of MoDC. Furthermore, although surface expression of DC activation markers, such as major histocompatibility complex (MHC)-II, CD80/86, CD40 and CD25, were only slightly changed, MoDC T-cell proliferation-inducing capacity was remarkably diminished by iAs treatment. Additionally, iAs induced significant interleukin (IL)-6 secretion by MoDC after 12- or 24-h incubation, whereas IL-1β secretion was only significantly up-regulated after 12?h. The secretion patterns of IL-8, tumor necrosis factor α (TNFα and IL-10 by iAs-treated MoDC were almost similar to that by mock-treated MoDC. Considering the broad roles of DC in immunobiology, this finding deepens the understanding of molecular mechanisms/functional consequences underpinning the immunopathology, inflammation, and increases in infection arising from As exposure.     

Mycobacterium bovis Bacillus Calmette-Guerin infects DC-SIGN- dendritic cell and causes the inhibition of IL-12 and the enhancement of IL-10 production

The only available vaccine against tuberculosis is Mycobacterium bovis Bacillus Calmette Guérin (BCG), although its efficacy in preventing pulmonary tuberculosis is controversial. Early interactions between dendritic cells (DC) and BCG or Mycobacterium tuberculosis (Mtb) are thought to be critical for mounting a protective antimycobacterial immune response. Recent studies have shown that BCG and Mtb target the DC-specific C-type lectin intercellular adhesion molecule-3-grabbing nonintegrin (DC-SIGN) to infect DC and inhibit their immunostimulatory function. This would occur through the interaction of the mycobacterial mannosylated lipoarabinomannan to DC-SIGN, which would prevent DC maturation and induce the immunosuppressive cytokine interleukin (IL)-10 synthesis. Here, we confirm that DC-SIGN is expressed in DC derived from monocytes cultured in granulocyte macrophage-colony stimulating factor (GM-CSF) and IL-4 and show that it is not expressed in DC derived from monocytes cultured in GM-CSF and interferon-alpha (IFN-alpha). We also demonstrate that DC-SIGN(-) DC cultured in GM-CSF and IFN-alpha are able to phagocytose BCG and to undergo a maturation program as well as DC-SIGN(+) DC cultured in IL-4 and GM-CSF. We also show that BCG causes the impairment of IL-12 and the induction of IL-10 secretion by DC, irrespective of DC-SIGN expression. Finally, we demonstrate that the capacity to stimulate a mixed leukocyte reaction of na?ve T lymphocytes is not altered by the treatment of both DC populations with BCG. These data suggest that DC-SIGN cannot be considered as the unique DC receptor for BCG internalization, and it is more interesting that the mycobacteria-induced immunosuppression cannot be attributed to the engagement of a single receptor.     

Monocyte-derived dendritic cell function in chronic hepatitis C is impaired at physiological numbers of dendritic cells

Monocyte-derived dendritic cells (MoDCs) are a promising cellular adjuvant for effector immune responses against tumours and chronic viral infections, including hepatitis C virus (HCV). If autologous DC therapeutic approaches are to be applied in persistent HCV infections in patients, it is important to have an unambiguous understanding of the functional status of the cell type used, namely MoDCs from patients with chronic hepatitis C (CHC) infection. Because of conflicting published reports of either impaired or normal MoDC function in CHC infection, we re-examined the ability of MoDCs from CHC and normal healthy donors (NHD) to mature to an inflammatory stimulus [tumour necrosis factor (TNF)-alpha] and their subsequent functional capabilities. Expression of maturation-associated phenotypic markers [human leucocyte antigen (HLA)-DR, CD83, CD86, CD40], allostimulatory capacity in mixed lymphocyte reactions (MLRs) and CD40-ligand-induced cytokine and chemokine generation were compared in CHC- versus NHD-MoDCs. TNF-alpha-stimulated CHC-MoDCs up-regulated phenotypic markers, but to significantly lower levels than NHD-MoDCs. At physiological ratios of DCs to T cells, CHC-MoDCs were less allostimulatory than NHD-MoDCs, but not when DC numbers were substantially increased. CHC- and NHD-MoDCs generated equivalent amounts of cytokines [TNF-alpha, interleukin (IL)-1beta, IL-6, IL-12p70, IL-15, IL-10] and chemokines [interferon-inducible protein (IP)-10, macrophage inflammatory protein (MIP)-1alpha, regulated upon activation, normal T expressed and secreted (RANTES)] after CD40 ligation. Because the functional defect was not apparent at high MoDC : T cell ratios, autologous MoDC therapy with sufficiently high numbers of DCs could, in theory, overcome any impairment of MoDC function in CHC.     

转录因子T-bet表达增强人树突状细胞疫苗诱导的抗肝癌免疫

目的：探讨T-bet在肝癌患者外周血来源的树突状细胞(dendritic cells，DCs)中表达能否增强其诱导抗肿瘤免疫。方法: 取肝癌患者外周血单核细胞，用5 μg/L rhGM-CSF、5 μg/L rhIL-4培养6 d成不成熟DC（iDC），随后加10 μg/L TNF-α诱导成熟DC。用冻融法制备肝癌细胞株HepG2肿瘤抗原，致敏DC，并分组如下： loaded DC/TNF-α（loaded mDC）； loaded DC/TNF-α+IFN-γ（loaded DC/T +I）； loaded DC/T-bet (loaded DC/T-bet)； iDC。体外刺激淋巴细胞。观察T-bet外源表达对DC的表型、混合淋巴细胞反应、肿瘤特异性细胞杀伤效率影响。结果: 外源表达T-bet促进DC/T-bet表型成熟，促进自体混合淋巴细胞反应，诱导分泌出更多的Th1型细胞因子，增强肝癌细胞特异性杀伤效应。结论: T-bet增强DC抗肿瘤免疫性能。     

gp130-linked signal transduction promotes the differentiation and maturation of dendritic cells

In order to explore the role of gp130-linked signal transduction in the differentiation and maturation of dendritic cells (DC), the mAb, B-S12, an agonist of gp130, was used for the activation of gp130 on DC. The effects of cytokines and of anti-gp130 mAb on the proliferation of DC, and their expression of IL-12 and CD80 (B7-1) by DC were evaluated. DC differentiating from peripheral blood mononuclear cells did not express the IL-6 receptor alpha chain, but expressed gp130. Anti-gp130 mAb promoted the proliferation of DC, induced by IL-4 and granulocyte macrophage colony stimulating factor (GM-CSF), by up-regulating the GM-CSF receptor on DC. DC induced by gp130 mAb and cytokines expressed DC-derived CC chemokine, as measured by RT-PCR. Induced DC also stimulated strong proliferation of autologous T cells in mixed lymphocyte reaction since an up-regulated expression of IL-12 and CD80 (B7-1) was observed in DC activated by anti-gp130 mAb. Thus, gp130 signal transduction is important for the differentiation and maturation of DC.     

Functional and phenotypic characteristics of dendritic cells generated in human plasma supplemented medium

One successful approach to generate dendritic cells (DC) is to cultivate peripheral blood monocytes in fetal calf serum (FCS)-containing medium in the presence of granulocyte-macrophage colony stimulating factor (GM-CSF) and interleukin (IL)-4. Because the use of xenogenic proteins has to be strictly avoided for clinical applications, alternative protocols use human plasma instead of FCS. The aim of our study was to characterize DC generated in the presence of human plasma; moreover, we describe a novel protocol to generate DC directly from peripheral blood mononuclear cells (PBMC). DC generated from purified monocytes in the presence of 1% human plasma (HP-DC) and GM-CSF and IL-4 both in the allogenic mixed leukocyte reaction (MLR) and in the tetanus presentation assay were potent stimulators of T-cell proliferation. DC generated from PBMC were equally effective stimulators in the allogenic MLR as those generated from purified monocytes. When the immunophenotype of DC generated from FCS containing medium (FCS-DC) was compared to that of HP-DC, the surface expression of CD1a and CD80 was significantly lower in HP-DC. In contrast, the expression of CD83 and CD86 was significantly higher in HP-DC than in FCS-DC. The capacity of receptor mediated endocytosis and macropinocytosis was found to be significantly lower in HP-DC when compared to FCS-DC. The differences in the immunophenotype, macropinocytosis and endocytosis between the HP-DC and the FCS-DC were observed independently of the generation of the cells from PBMC or purified monocytes. Our data indicate that HP-DC are potent stimulators of T-cell proliferation and exhibit a characteristic phenotype of intermediate maturity. Moreover, DC can be directly generated from PBMC preparations.     

Phenotype and function of human dendritic cells derived from M-DC8(+) monocytes

Dendritic cells (DC) generated from peripheral blood monocytes have been used with promising results as a new approach for the immunotherapy of cancer. However, at least four different subpopulations of peripheral blood monocytes have been recognized and their contribution to the generation of functional DC is not known. Recently, the monoclonal antibody M-DC8 has been shown to react with 0.2 - 1 % of blood leukocytes. We have identified M-DC8(+) cells as monocytes which represent about 40 % of CD14(low)CD16(+) monocytes. Similar to M-DC8(-) monocytes, they develop in the presence of GM-CSF and IL-4 into a very homogenous population of cells with DC phenotype and function. M-DC8(+) DC show on average a twofold higher expression of HLA class I and class II molecules than M-DC8(-) DC. These DC produce IL-12p75 both in response to LPS and to CD40 ligation. M-DC8(+) DC induced a strong Th1 immune response and were two to four old more potent than M-DC8(-) DC for the priming of cord blood T cells. M-DC8(+) monocytes can be used as a source of very potent dendritic cells with the potential to significantly improve the efficacy of DC-based immunotherapies.     

Lipopolysaccharide can block the potential of monocytes to differentiate into dendritic cells

We examined whether priming monocytes (MO) with lipopolysaccharide (LPS) influenced their further differentiation into either macrophages (Mphi) or dendritic cells (DC). LPS-primed MO differentiated into Mphi when cultured further with Mphi colony-stimulating factor (M-CSF) but, if cultured then with granulocyte/Mphi (GM)-CSF and IL-4 (interleukin-4), only about 30% of the cells differentiated into CD1a+ CD14- DC and half became CD1a- CD14+ Mphi. Cytokines present during LPS priming could affect subsequent MO differentiation. Relative to priming with LPS alone, adding M-CSF to LPS did not modify differentiation of MO to Mphi in further culture with M-CSF, nor did it change the way of differentiation of MO into DC was altered if culture was later switched to GM-CSF/IL-4. Using GM-CSF/IL-4 plus LPS upon priming did not modify differentiation of MO to Mphi in further culture with M-CSF, as compared to priming with GM-CSF/IL-4 alone, but it counteracted the effect of LPS on the differentiation of MO to DC in further culture with GM-CSF/IL-4: about 75% of cells then became DC. Alternatively, despite activation by LPS, mature M-CSF-induced Mphi preserved the potential to differentiate into DC on subsequent culture with GM-CSF/IL-4. Thus, LPS, a bacterial product known to sustain maturation of MO/Mphi as well as of DC, may block the differentiation of MO into DC, except if signal triggering DC differentiation is delivered concomitantly, and modulate in this manner the induction of adaptive immune responses to infection.