The specialized roles of immature and mature dendritic cells in antigen cross-presentation

Exogenous antigen cross-presentation is integral to the stimulation of cytotoxic T-lymphocytes against viruses and tumors. Central to this process are dendritic cells (DCs), which specialize in cross-presentation. DCs may be considered to exist in two radically different states of activation, generally referred to as immature and mature. In each of these states, the cell has a series of separate and specialized abilities for the induction of T-cell immunity. In the immature state, the DC is adept in surveying the periphery, acquiring and storing antigen, but has a limited capacity for direct T-cell activation. During a brief and defined window of time following DC stimulation, nearly every aspect of antigen handling changes, as it transitions from an entity focused on protein preservation to one capable of efficient cross-presentation. It is this time period and the underlying molecular mechanisms active here, which form the core of our studies on cross-presentation.     

未成熟树突细胞诱导同种免疫低应答性的研究

目的：证实缺少辅助刺激分子的未成熟树突细胞（ＤＣ）在体外诱导同种Ｔ细胞的低应答性。方法：应用骨髓微血管内皮细胞作为饲养细胞扩增同品系小鼠骨髓细胞,经不同浓度ＧＭ－ＣＳＦ作用,在体外培养出不同发育阶段的ＤＣ。采用初次和再次单向混合淋巴细胞培养方法观察Ｂａｌｂ／ｃ小鼠脾脏Ｔ细胞对同种未成熟ＤＣ或脾细胞的应答能力。结果：在初次ＭＬＲ试验中,Ｂａｌｂ／ｃ Ｔ细胞对Ｃ５７ＢＬ／６小鼠未成熟ＤＣ刺激只呈现出微     

小鼠骨髓成熟与不成熟树突状细胞中RelB基因的表达

目的:探讨体外分离培养的小鼠骨髓来源的成熟与未成熟DC中核转录因子RelB(avianreticuloendotheliosisviral(v-rel)oncogenerelatedB)基因的表达。方法:无菌从C57BL/6小鼠股骨和胫骨中取出骨髓细胞,利用rmGM-CSF和rmIL-4联合诱导骨髓前体细胞产生未成熟的DC,未成熟的DC在培养结束前18h经LPS刺激获得成熟的DC,用流式细胞术分析它们的表型,用RT-PCR和免疫荧光染色法检测成熟与未成熟DC中,RelBmRNA和其蛋白的表达。结果:流式细胞术分析显示未成熟的DC中MHC-Ⅱ类分子和共刺激分子(CD86和CD40)呈低水平表达;而成熟的DC则呈高水平表达。RT-PCR和免疫荧光染色法检测结果均显示,RelB基因在未成熟的DC中呈低水平表达;而在成熟的DC中呈高水平表达,两者比较具有统计学意义(P<0.01)。结论:RelB基因的表达与小鼠骨髓来源的DC的成熟状态密切相关。抑制DC中RelB基因的表达,有可能诱导产生具有耐受原性的未成熟的DC。     

Differential role of mitogen-activated protein kinases in CD40-mediated IL-12 production by immature and mature dendritic cells

Using a murine spleen-derived dendritic cell (DC) line (BC1) CD40-mediated interleukin (IL)-12 production was analyzed and compared between immature and mature DC. BC1 cells, immature DC (iDC), were maturated by treatment with lipopolysaccharide (LPS) or tumor necrosis factor (TNF)-alpha. IL-12 production of LPS-treated DC (LPS/DC) was markedly enhanced by treatment with an anti-CD40 monoclonal antibody (mAb). Although the anti-CD40 mAb also enhanced IL-12 productions of iDC and TNF-alpha-treated DC (TNF/DC), these production levels were considerably low compared with that of LPS/DC. CD40-mediated IL-12-productions by iDC and TNF/DC were significantly enhanced by treatment with PD98059, a specific inhibitor of extracellular signal-related kinase (ERK) pathway. In contrast, PD98059 showed no significant effects on CD40-mediated IL-12-production by LPS/DC. These results demonstrated that ERK pathway was involved in negative regulation of the IL-12 productions by iDC and TNF/DC but not by LPS/DC. On the other hand, SB203580, a specific inhibitor of p38 mitogen activated protein kinase (MAPK) pathway, completely inhibited CD40-mediated IL-12-production by iDC, while not affecting those of TNF/DC and LPS/DC. Thus, p38 MAPK pathway appeared to positively regulate the IL-12 production in iDC but not in mature DC. It seems that roles of ERK and p38 MAPK for IL-12 production are developmentally changed in murine DC.     

Disparate functions of immature and mature human myeloid dendritic cells: implications for dendritic cell-based vaccines

Although antigen-loaded dendritic cells (DC) are being investigated as antitumor vaccines, which DC differentiation state is most effective is not clear. Three DC functions that may be critical for immunization potential are expression of CD80/86, cytokine production following CD40 engagement, and migration to chemokine receptor 7-binding chemokines. We therefore examined highly purified human monocyte-derived immature and mature DC for these properties from normal donors and cancer patients. Although high expression of CD80/86 and migration to 6Ckine + macrophage-inflammatory protein-3beta were properties of mature DC, cytokine production following CD40 ligation was superior by immature DC. Loss of cytokine secretion occurred with multiple maturation conditions, was not apparently reversible, and was also seen with lipopolysaccharide stimulation in correlation with down-regulated Toll-like receptor expression. Our results suggest that the functions thought to contribute to optimal T cell priming are not coexpressed by the same DC population and that immature and mature DC likely possess distinct CD40-mediated signaling events.     

Distinct compartmental distribution of mature and immature dendritic cells in esophageal squamous cell carcinoma

Dendritic cells (DCs) play a critical role in generating anti-tumor immunity. DC functional defect has been related to the growth and progression of various human cancers. In esophageal squamous cell carcinoma (ESCC), the examination of DCs using immunohistochemistry (IHC) with anti-S100 antibody has demonstrated an increased infiltration of DCs into the tumor mass, however, the distribution patterns of DCs at different maturation states in ESCC are not fully evaluated. In this study, we immunohistochemically analyzed the DC maturation status by examining the S100-positive DCs, CD1α-positive immature DCs (iDCs), and CD208-positive mature DCs (mDCs) and their distribution patterns in 45 ESCCs and 10 control tissues. The IHC analysis showed that the number of S100-positive DCs was increased in both the cancer epithelium and tumor stroma. Further phenotypic analyses revealed that intraepithelial DCs in the cancer mass were predominantly CD1α-positive iDCs. Whereas DCs presented in the tumor stroma were exclusively CD208-positive mDCs, CD208-positive mDCs were particularly dense in the margin of cancerous lesions and formed clusters with CD3-positive lymphocytes. The number of CD208-positive mDCs in the tumor mass was significantly lower than the number of CD1α-positive iDCs. The current results suggest that ESCC tissue comprises a high frequency of iDCs in the cancerous epithelium and a low density of mDCs in the tumor stroma. Such a distinct distribution pattern may reflect the ongoing DC tracking in ESCCs.     

Human blood contains two subsets of dendritic cells,one immunologically mature and the other immature.

Two subsets of dendritic cells, differing in T-cell stimulatory function, have been purified directly from human blood. Both subsets are positive for major histocompatibility complex (MHC) class II expression and negative for lineage-specific antigens (e.g. CD3, CD14, CD16, CD19 negative), but are separated by exploiting differences in expression of the beta 2-integrin, CD11c. The CD11c-negative subset is functionally immature, requiring monocyte-derived cytokines to develop into typical dendritic cells. The CD11c-positive subset has potent T-cell stimulating activity and expresses the activation antigen CD45RO, unlike its immature counterpart. However, these mature cells only develop typical dendritic morphology and high levels of MHC proteins and adhesins after a period of culture independent of exogenous cytokines. Although the freshly isolated mature dendritic cells resemble monocytes in cytospin preparations, the former lack CD14 and have a much stronger primary T-cell stimulatory capacity. We hypothesize that the CD11c-negative immature cells are marrow-derived precursors to tissue dendritic cells, such as epidermal Langerhans'' cells, while the CD11c-positive cells are derived from tissues where they have been activated by antigen, and are en route to the spleen or lymph nodes to stimulate T-cell responses there.     

Generation or large numbers of immature and mature dendritic cells from rat bone marrow cultures

We have defined conditions for generating large numbers of dendritic cells (DC) in marrow cultures from 10 – 12-week-old ACI or WF rats. The combination of granulocyte-macrophage colony-stimulating factor (GM-CSF) and TNF-α, known to induce DC from human CD34⁺ progenitors, was not effective with rat. In contrast, GM-CSF plus IL-4 generated DC in high yield, corresponding to 30 – 40 % of the initial number of plated marrow cells. The DC proliferated in distinctive aggregates, in which most cells had an immature phenotype marked by undetectable surface B7 and high levels of MHC class II products within intracellular lysosomes. When dislodged and dispersed, the aggregates gave rise to mature stellate DC with abundant surface MHC class II and B7, sparse MHC class II^– lysosomes, and strong T cell-stimulating capacity. Therefore, rat marrow progenitors can generate large numbers of immature DC, with abundant intracellular MHC class II compartments, and potent, stimulatory, mature DC.     

Comparative analysis of NK- or NK-CTL-mediated lysis of immature or mature autologous dendritic cells

Natural killer (NK) cells have been shown to kill efficiently autologous immature dendritic cells (iDC), while sparing those undergone maturation. In this study we investigated the effect of the interaction between autologous DC and NK-cytolytic T lymphocytes (NK-CTL), a subset of HLA-E-restricted CD8(+) T cells that express HLA class I-specific inhibitory NK receptors. Although these cells share with NK cells various phenotypic and functional features (such as the capacity to lyse most allogeneic, NK-susceptible tumor cell lines), different from NK cells, NK-CTL failed to lyse autologous DC. However, after pulsing DC with a cytomegalovirus-derived, HLA-E-binding peptide recognized by NK-CTL, both iDC and mature DC became highly susceptible to lysis. On the other hand,the addition of the peptide resulted in the down-regulation of the NK-mediated lysis of the same autologous iDC. The capability of killing autologous DC, presenting a non-self, HLA-E-binding peptide, may represent a feedback mechanism by which NK-CTL down-regulate HLA-E-restricted responses to certain pathogens.     

Chicken CCR6 and CCR7 are markers for immature and mature dendritic cells respectively

In mammals, the CC chemokine receptors 6 and 7 (CCR6 and CCR7) play important roles in controlling the trafficking of dendritic cells (DC). CCR6 is expressed primarily on immature DC in the periphery and plays a role in the recruitment of immature DC to sites of potential antigen entry. On encountering pathogens, DC mature and migrate to secondary lymphoid organs where they present pathogen antigen to T cells to initiate specific adaptive immune responses. Maturation involves down-regulation of CCR6 but up-regulation of CCR7. To investigate the role of these two chemokine receptors in the function of DC in the chicken, a full-length chicken CCR7 (chCCR7) cDNA was cloned. Chicken CCR6 (chCCR6) was already available (Munoz et al., 2009). ChCCR7 shows the typical secondary structure of a seven-transmembrane G protein-coupled receptor and has 66% and 64% amino acid identity with human and mouse CCR7, respectively. Like its mammalian orthologues, chCCR7 mRNA was highly expressed in most lymphoid tissues (with the exception of the Harderian gland) and also in some non-lymphoid tissues (especially the heart, lung, skin and small intestine). Both chCCR6 and chCCR7 were expressed at the mRNA level in immature chicken bone marrow-derived dendritic cells (chBM-DC), as measured by real-time quantitative RT-PCR. After DC maturation following stimulation with LPS or CD40L, expression levels of chCCR6 mRNA were down-regulated, whereas those of chCCR7 were up-regulated, suggesting that these two chemokine receptors play a similar role in the trafficking of chicken DC as they do in mammals and that they act as markers of immature (chCCR6) and mature (chCCR7) DC.     

Chemokines and other GPCR ligands synergize in receptor-mediated migration of monocyte-derived immature and mature dendritic cells

Dendritic cells (DCs) are potent antigen presenting cells, described as the initiators of adaptive immune responses. Immature monocyte-derived DCs (MDDC) showed decreased CD14 expression, increased cell surface markers DC-SIGN and CD1a and enhanced levels of receptors for the chemokines CCL3 (CCR1/CCR5) and CXCL8 (CXCR1/CXCR2) compared with human CD14⁺ monocytes. After further MDDC maturation by LPS, the markers CD80 and CD83 and the chemokine receptors CXCR4 and CCR7 were upregulated, whereas CCR1, CCR2 and CCR5 expression was reduced. CCL3 dose-dependently synergized with CXCL8 or CXCL12 in chemotaxis of immature MDDC. CXCL12 augmented the CCL3-induced ERK1/2 and Akt phosphorylation in immature MDDC, although the synergy between CCL3 and CXCL12 in chemotaxis of immature MDDC was dependent on the Akt signaling pathway but not on ERK1/2 phosphorylation. CCL2 also synergized with CXCL12 in immature MDDC migration. Moreover, two CXC chemokines not sharing receptors (CXCL12 and CXCL8) cooperated in immature MDDC chemotaxis, whereas two CC chemokines (CCL3 and CCL7) sharing CCR1 did not. Further, the non-chemokine G protein-coupled receptor ligands chemerin and fMLP synergized with respectively CCL7 and CCL3 in immature MDDC signaling and migration. Finally, CXCL12 and CCL3 did not cooperate, but CXCL12 synergized with CCL21 in mature MDDC chemotaxis. Thus, chemokine synergy in immature and mature MDDC migration is dose-dependently regulated by chemokines via alterations in their chemokine receptor expression pattern according to their role in immune responses.     

Splenic stroma drives mature dendritic cells to differentiate into regulatory dendritic cells

The fates of dendritic cells (DCs) after antigen presentation have been studied extensively, but the influence of lymphoid microenvironments on DCs is mostly unknown. Here, using splenic stromal cells to mimic the immune microenvironment, we show that contact with stromal cells promoted mature DCs to proliferate in a fibronectin-dependent way and that both stromal cell contact and stromal cell-derived transforming growth factor-beta induced their differentiation into a new regulatory DC subset. We have identified an in vivo counterpart in the spleen with similar phenotype and functions. These differentiated DCs secreted nitric oxide, which mediated the suppression of T cell proliferation in response to antigen presentation by mature DCs. Thus, our findings identify an important mechanism by which the microenvironment regulates immune responses.     

IL-15-induced conversion of monocytes to mature dendritic cells.

IL-15 is produced by a wide variety of tissues in response to inflammatory stimuli. We examined the effect of IL-15 in supporting the maturation of monocytes to dendritic cells in ex vivo culture. IL-15 transformed CD14(+) monocytes to mature dendritic cells. These dendritic cells were similar to those obtained from monocyte cultures treated with a combination of the cytokines GM-CSF, IL-4 and TNF-alpha. The effects of IL-15 did not depend on endogenously produced GM-CSF. The IL-15-induced dendritic cells also expressed chemokines and stimulated strong allo-responses that were characteristic of mature dendritic cells. These data indicate that CD14(+) monocytes respond to IL-15 by undergoing morphological transformation and acquiring characteristic dendritic cell features that facilitate antigen-specific responses of T cells. Thus, the release of IL-15 by inflammatory stimuli may induce the conversion of monocytes to immuno-stimulatory dendritic cells to support primary immune responses against pathogens.     

Differential dendritic Ca2+ signalling in young and mature hippocampal granule cells

Neuronal activity is critically important for development and plasticity of dendrites, axons and synaptic connections. Although Ca(2+) is an important signal molecule for these processes, not much is known about the regulation of the dendritic Ca(2+) concentration in developing neurons. Here we used confocal Ca(2+) imaging to investigate dendritic Ca(2+) signalling in young and mature hippocampal granule cells, identified by the expression of the immature neuronal marker polysialated neural cell adhesion molecule (PSA-NCAM). Using the Ca(2+)-sensitive fluorescent dye OGB-5N, we found that both young and mature granule cells showed large action-potential evoked dendritic Ca(2+) transients with similar amplitude of approximately 200 nm, indicating active backpropagation of action potentials. However, the decay of the dendritic Ca(2+) concentration back to baseline values was substantially different with a decay time constant of 550 ms in young versus 130 ms in mature cells, leading to a more efficient temporal summation of Ca(2+) signals during theta-frequency stimulation in the young neurons. Comparison of the peak Ca(2+) concentration and the decay measured with different Ca(2+) indicators (OGB-5N, OGB-1) in the two populations of neurons revealed that the young cells had an approximately 3 times smaller endogenous Ca(2+)-binding ratio ( approximately 75 versus approximately 220) and an approximately 10 times slower Ca(2+) extrusion rate ( approximately 170 s(-1) versus approximately 1800 s(-1)). These data suggest that the large dendritic Ca(2+) signals due to low buffer capacity and slow extrusion rates in young granule cells may contribute to the activity-dependent growth and plasticity of dendrites and new synaptic connections. This will finally support differentiation and integration of young neurons into the hippocampal network.     

Differential production of inflammatory chemokines by murine dendritic cell subsets

Dendritic cells (DC) are efficient antigen presenting cells with the ability to activate na?ve T cells. Murine DC represent a heterogeneous population that can be subdivided into distinct subsets, including the conventional DC (cDC) which are either CD4(-)CD8(-) (DN), CD4(+)CD8(-) (CD4+) or CD4(-)CD8(+) (CD8+) subsets and the plasmacytoid DC (pDC), which have different immune regulatory functions. In this study, we investigated the differential expression of genes encoding the inflammatory chemokines Mip-1alpha, Mip-1beta and Rantes, and the secretion of these chemokines, among splenic DC subsets. These chemokine genes were expressed at higher levels by the splenic CD4+ and DN cDC subsets compared with the CD8+ cDC, in both the resting and activated states in vivo. Both the pDC and cDC subsets displayed increases in chemokine secretion in response to a range of toll-like receptor (TLR) stimuli in vitro. Whilst the pDC were the highest producers of Mip-1alpha and Mip-1beta in response to some TLR stimuli, the DN and CD4+ cDC subsets were the superior producers of Rantes. Overall, of the cDC, the CD4+ cDC produced all chemokines most efficiently, both at a basal level, and in response to most TLR stimuli. Thus, we report a new functional difference between the murine splenic cDC subsets, with the CD4+ cDC demonstrating the most efficient production of the inflammatory chemokines Mip-1alpha, Mip-1beta and Rantes.     

未成熟树突状细胞表面CD1d分子在体外移植免疫中的作用

背景：树突状细胞具有双向免疫调节作用,成熟树突状细胞激活免疫应答,而未成熟树突状细胞则倾向诱导免疫耐受。 目的：探讨鼠CD1d分子在未成熟树突状细胞诱导移植免疫耐受中的作用,以及在此过程中细胞因子的参与机制。 方法：利用vIL-10转染的BALB/c小鼠未成熟树突状细胞在体外用粒细胞-巨噬细胞集落刺激因子基因、脂多糖刺激成熟,经抗CD1d(anti-CD1d)干预。观察培养后的细胞表型、细胞因子表达。为探明CD1d分子在异体T细胞存在下的免疫作用,进行不同实验条件的初次、再次混合淋巴细胞培养(1stMLC、2ndMLC),观察T细胞增殖、细胞因子表达。 结果与结论：Anti-CD1d的干预降低了未成熟树突状细胞增殖异体T细胞的能力,anti-CD1d干预的未成熟树突状细胞致敏异体T细胞后其免疫功能低下;anti-CD1d干预在异体T细胞存在时影响未成熟树突状细胞在功能上的成熟,主要表现在抑制白细胞介素12的分泌,加强白细胞介素10的分泌。     

A novel bulk-culture method for generating mature dendritic cells from mouse bone marrow cells

We established a novel culture method for generating dendritic cells (DC) from mouse bone marrow (BM) cells. Unfractionated bulk BM cells were cultured in the presence of granulocyte-macrophage colony-stimulating factor (GM-CSF) and interleukin-4 (IL-4) for 5-7 days and a DC population was isolated by gradient centrifugation with 14.5% (w/v) metrizamide. Through this method, 30-40 x 10(6)/mouse DC with 85-95% purity was obtained on day 7; this yield was higher than those of conventional DC generated by Inaba's method either with GM-CSF alone (conventional-GM DC) or GM-CSF and IL-4 (conventional-GM/4 DC). Bulk-cultured DC have a more matured phenotype than both conventional-GM and -GM/4 DC as shown by higher expression of CD86, MHC class II and CD40. Functional analyses reveal that (1) bulk-DC show less ability in endocytosis than conventional-GM DC and are comparable in IL-12 p70 production with conventional-GM and -GM/4 DC. (2) Bulk-DC exhibit stronger stimulatory capacity in allogeneic T-cell proliferation than conventional DC. (3) By using ovalbumin (OVA) and OVA-specific T-cell receptor (TCR) transgenic mice (DO11.10) system, OVA protein-loaded bulk-DC stimulated CD4 T cells of DO11.10 mice more than conventional-GM DC and comparable with conventional-GM/4 DC. (4) Furthermore, OVA peptide-pulsed bulk-DC stimulated CD4 T cells more than conventional-GM and -GM/4 DC. These data indicate that bulk-DC are functionally more mature than conventional DC. Taken together, bulk-culture method is a simple technique for generating functionally mature BM-DC in large quantities and high purity.     

Serum amyloid A chemoattracts immature dendritic cells and indirectly provokes monocyte chemotaxis by induction of cooperating CC and CXC chemokines

Serum amyloid A (SAA) is an acute phase protein that is upregulated in inflammatory diseases and chemoattracts monocytes, lymphocytes, and granulocytes via its G protein‐coupled receptor formyl peptide receptor like 1/formyl peptide receptor 2 (FPRL1/FPR2). Here, we demonstrated that the SAA1α isoform also chemoattracts monocyte‐derived immature dendritic cells (DCs) in the Boyden and μ‐slide chemotaxis assay and that its chemotactic activity for monocytes and DCs was indirectly mediated via rapid chemokine induction. Indeed, SAA1 induced significant amounts (≥5 ng/mL) of macrophage inflammatory protein‐1α/CC chemokine ligand 3 (MIP‐1α/CCL3) and interleukin‐8/CXC chemokine ligand 8 (IL‐8/CXCL8) in monocytes and DCs in a dose‐dependent manner within 3 h. However, SAA1 also directly activated monocytes and DCs for signaling and chemotaxis without chemokine interference. SAA1‐induced monocyte migration was nevertheless significantly prevented (60–80% inhibition) in the constant presence of desensitizing exogenous MIP‐1α/CCL3, neutralizing anti‐MIP‐1α/CCL3 antibody, or a combination of CC chemokine receptor 1 (CCR1) and CCR5 antagonists, indicating that this endogenously produced CC chemokine was indirectly contributing to SAA1‐mediated chemotaxis. Further, anti‐IL‐8/CXCL8 antibody neutralized SAA1‐induced monocyte migration, suggesting that endogenous IL‐8/CXCL8 acted in concert with MIP‐1α/CCL3. This explained why SAA1 failed to synergize with exogenously added MIP‐1α/CCL3 or stromal cell‐derived factor‐1α (SDF‐1α)/CXCL12 in monocyte and DC chemotaxis. In addition to direct leukocyte activation, SAA1 induces a chemotactic cascade mediated by expression of cooperating chemokines to prolong leukocyte recruitment to the inflammatory site.     

Retroviral gene transfer, rapid selection, and maintenance of the immature phenotype in mouse dendritic cells.

We used the retroviral vector PINCO [which expresses the green fluorescent protein (GFP) as a selectable marker], to infect growth factor-dependent immature D1 dendritic cells (DC). The efficiency of infection in different experiments was between 5 and 30%, but subsequent cell sorting led to a virtually homogeneous population of GFP-positive cells. Retroviral infection did not modify the immature DC phenotype, as shown by the low expression of major histocompatibility complex and co-stimulatory molecules. Furthermore, the GFP-positive D1 cells underwent full maturation after lipopolysaccharide treatment, as indicated by a high expression of cell-surface MHC and co-stimulatory molecules, and also by strong stimulatory activity in allogeneic mixed lymphocyte reaction. The high efficiency of this retroviral system, the rapidity of the technique, and the possibility to overcome in vitro selection make this method very attractive for the stable introduction of heterologous genes into proliferating immature mouse D1 cells. Furthermore, this approach is suitable for functional studies of new DC-specific genes involved in DC maturation and survival.