Antigen processing and CD24 expression determine antigen presentation by splenic CD4+ and CD8+ dendritic cells

To examine heterogeneity in dendritic cell (DC) antigen presentation function, murine splenic DCs were separated into CD4⁺ and CD8⁺ populations and assessed for the ability to process and present particulate antigen to CD4⁺ and CD8⁺ T cells. CD4⁺ and CD8⁺ DCs both processed exogenous particulate antigen, but CD8⁺ DCs were much more efficient than CD4⁺ DCs for both major histocompatibility complex (MHC) class II antigen presentation and MHC class I cross-presentation. While antigen processing efficiency contributed to the superior antigen presentation function of CD8⁺ DCs, our studies also revealed an important contribution of CD24. CD8⁺ DCs were also more efficient than CD4⁺ DCs in inducing naïve T cells to acquire certain effector T-cell functions, for example generation of cytotoxic CD8⁺ T cells and interferon (IFN)-γ-producing CD4⁺ T cells. In summary, CD8⁺ DCs are particularly potent antigen-presenting cells that express critical costimulators and efficiently process exogenous antigen for presentation by both MHC class I and II molecules.     

An improved enrichment method for functionally competent, highly purified peripheral blood dendritic cells and its application to HIV-infected blood samples.

Dendritic cells (DC) were purified from human peripheral blood using a rapid and simple method based on magnetic depletion of phagocytes with carbonyl iron, followed by centrifugation of nonphagocytic cells on a Percoll density gradient and depletion of lymphocytes and macrophages/monocytes with a panel of MoAbs and immunomagnetic beads. Enriched DC were obtained with > 99% purity as judged by non-specific esterase (NSE) staining. After isolation, these cells, representing 0.4% of the starting mononuclear cell population, still function as potent antigen-presenting cells for purified T lymphocytes. The present results confirm the ability of human peripheral blood DC to present soluble antigens to T cells including microbial antigens and show, further, that DC are more potent soluble antigen-presenting cells than monocytes. The method was successfully applied to the purification of DC from the blood of HIV-infected individuals. We could not detect decreased numbers of DC in four individuals with early HIV infection and no replicating HIV was detected by in situ hybridization in the DC.     

The delivery of an antigen from the endocytic compartment into the cytosol for cross-presentation is restricted to early immature dendritic cells

Dendritic cells (DCs) are the only antigen-presenting cell population having a cross-presentation capacity. For cross-presentation, however, the intracellular antigen-processing pathway and its regulatory mechanism have not been defined. Here we report the differences in cross-presentation ability among murine bone marrow-derived immature DC, early immature day8-DC and late immature day10-DC, and fully mature day10 + lipopolysaccharide DC. Day8-DCs and day10-DCs show an immature phenotypic profile but are different in morphology. Day8-DCs can internalize an abundant volume of exogenous soluble ovalbumin (OVA) and result in cross-presentation. In contrast, day10-DCs are not able to cross-present, although they maintain efficient macropinocytosis. Exogenously internalized OVA antigens are stored in the endocytic compartments. The endocytic compartments are temporarily maintained at mildly acidic pH in day8-DCs and are rapidly acidified in day10-DCs after uptake of antigens. We show that OVA antigens accumulated in the endocytic compartments move into the cytosol in day8-DCs but do not in day10-DCs. NH(4)Cl-treatment, which neutralizes the acidic endocytic compartments and/or delays endosomal maturation, restores day10-DCs for transport the stored OVA antigens from the endocytic compartments into the cytosol. Diphenyleneiodonium chloride-treatment, which acidifies the endocytic compartments, decreases an amount of transported OVA antigen into the cytosol in day8-DCs. These data indicate that only the early immature stage of DC interferes with endosomal maturation, even after uptake of exogenous antigens, and then transports the antigens into the cytosol.     

Concerted antigen presentation by dendritic cells and B cells is necessary for optimal CD4 T-cell immunity in vivo

The relative contributions of different types of antigen presenting cells to T-cell activation, expansion and induction of effector functions are still not fully understood. In order to evaluate the roles of dendritic versus B cells during these phases of a CD4 T-cell response in vivo, we adoptively transferred major histocompatibility complex class II restricted, T-cell receptor-transgenic CD4+ T cells into transgenic mice expressing selectively the T-cell restricting class II molecules on either dendritic cells, B cells or both. Upon immunization with peptide antigen, we observed that dendritic cells were sufficient to induce activation, expansion, interleukin-2 production and germinal centre migration of antigen-specific T cells, independently of other antigen-presenting cells. In contrast, neither resting nor activated B cells had similar antigen-presenting capacities in vivo. However, in double transgenic mice where both B cells and dendritic cells were capable of presenting antigen, T cells showed increased proliferation, expansion and cytokine production in vivo. Moreover, higher antigen-specific CD4 T-cell numbers accumulated in germinal centres. Our data demonstrate that dendritic cells are sufficient to activate naive CD4 T cells in vivo, but B cells subsequently can enhance CD4 T-cell expansion further.     

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.     

Drinking a lot is good for dendritic cells

Macropinocytosis is the actin-dependent formation of large vesicles, which allow the internalization of large quantities of fluid-phase solute. In the majority of cells examined, an exogenous stimulus is required to induce the initiation of this endocytic pathway. However, dendritic cells are thought to constitutively macropinocytose large quantities of exogenous solute as part of their sentinel function. In this review we discuss the evidence that dendritic cells macropinocytose exogenous solute and subsequently present antigenic peptides derived from internalized material to T cells. In addition, we put these data into the context of immune surveillance in vivo.     

Circulating myeloid and plasmacytoid dendritic cells after allergen inhalation in asthmatic subjects

BACKGROUND: Dendritic cells are key contributors to initiation and maintenance of T-cell immunity to inhaled allergen. The purpose of this study was to enumerate the changes in peripheral blood myeloid (mDCs) and plasmacytoid dendritic cells (pDCs), the DCs expressing chemokine receptor 6 (CCR6) and chemokine receptor 7 (CCR7), following diluent and allergen inhalation in asthmatic subjects. METHODS: Peripheral blood was obtained from 16 allergic asthmatic subjects before and at 0.5, 1, 2, 3, 4, 6, 24, and 48 h after inhaled diluent and allergen challenges. Dendritic cells were enumerated using flow cytometry. RESULTS: Allergen inhalation significantly reduced mDCs at 6 h (21.3 +/- 2.0 vs 15.0 +/- 1.8/microl blood; P < 0.05) and 24 h (21.5 +/- 3.4 vs 16.4 +/- 2.4/microl blood; P < 0.05) after challenge. Circulating pDCs were significantly lower than baseline up to 24 h after both allergen and diluent challenges. There was a significant efflux of CCR6(+) mDCs from peripheral blood at 6 h and CCR6(+) pDCs at 4 h after allergen challenge, when compared with diluent. There was no difference in the number of circulating CCR7(+) mDCs or pDCs after diluent or allergen challenges. CONCLUSIONS: Peripheral blood mDCs and CCR6(+) mDCs, but not pDCs, are reduced up to 24 h after allergen inhalation. Thus, allergen inhalation causes trafficking of immature CCR6(+) DCs from blood into the airway, while that of the trafficking of the mature CCR7(+) DCs from the airways into the regional lymph nodes probably occurs through the lymphatic system.     

Morphologically and functionally intact dendritic cells can be derived from the peripheral blood of aged individuals

Dendritic cells are antigen-presenting cells (APC), which are crucial for the initiation of an immune response. In spite of the well known decline of immune function in old age, no information is yet available on whether dendritic cells are also affected by the ageing process. It was therefore the aim of this study to compare peripheral blood dendritic cells (DC) from old and young healthy individuals. Using granulocyte-macrophage colony-stimulating factor (GM-CSF) and IL-4, DC were propagated from peripheral blood mononuclear cells (PBMC). The obtained cell populations had a typical dendritic morphology and expressed HLA class I and class II, CD23, CD32, CD40, CD44 and CD54, but not CD3 and CD19. Larger numbers of DC were obtained from old individuals than from young ones in spite of a similar expression pattern of surface molecules. DC from aged persons also survived better under in vitro culture conditions. When tested for their antigen-presenting capacity, DC from young and old individuals were equally effective in inducing the proliferation of tetanus toxoid-specific T cell clones after antigenic stimulation. Peripheral blood DC from aged individuals may thus still function as powerful APC. They may represent useful tools for immunotherapy in the aged.     

Expression of CD33-related siglecs on human mononuclear phagocytes, monocyte-derived dendritic cells and plasmacytoid dendritic cells

Siglecs are sialic acid binding Ig-like lectins mostly expressed in the haemopoietic and immune systems. Amongst the 11 human siglecs, there are eight proteins highly related to CD33 which have biochemical features of inhibitory receptors, containing two conserved tyrosine-based inhibitory motifs. Five of these (CD33/siglec-3, -5, -7, -9 and -10) are expressed on circulating monocytes. Here we show that monocytes cultured to differentiate into macrophages using either GM-CSF or M-CSF retained expression of these siglecs and their levels were unaffected following stimulation with LPS. In comparison, monocyte-derived dendritic cells down-modulated siglec-7 and -9 following maturation with LPS. Plasmacytoid dendritic cells in human blood expressed siglec-5 only. On monocytes, siglec-5 was shown to mediate rapid uptake of anti-siglec-5 (Fab)2 fragments into early endosomes. This suggests, in addition to inhibitory signalling, a potential role in endocytosis for siglec-5 and the other CD33-related siglecs. Our results show that siglecs are differentially expressed on mononuclear phagocytes and dendritic cells and that some can be modulated by stimuli that promote maturation and differentiation.     

Effect of SIVmac infection on plasmacytoid and CD1c+ myeloid dendritic cells in cynomolgus macaques

Dendritic cells (DCs) are known to be essential for the induction and regulation of immune responses. Non-human primates are essential in biomedical research and contribute to our understanding of the involvement of DCs in human infectious diseases. However, no direct single-platform method for quantifying DC precursors has yet been optimized in macaques to give accurate absolute blood counts of these rare-event cell populations in the blood. We adapted a rapid whole-blood assay for the absolute quantification of DCs in cynomolgous macaques by four-colour flow cytometry, using a single-platform assay compatible with human blood. Cynomolgus macaque plasmacytoid DCs (pDCs) and CD1c⁺ myeloid DCs (CD1c⁺ mDCs) were quantified in the blood of 34 healthy macaques and the results obtained were compared with those for blood samples from 11 healthy humans. In addition, circulating absolute numbers of pDCs were quantified in cynomolgus macaques chronically infected with SIVmac. During infection, pDC counts decreased whereas circulating CD1c⁺ mDC counts increased. Information regarding absolute pDC and mDC counts in non-human primates may improve our understanding of the role of these cells in SIV/HIV infection and in other infectious diseases.     

In vivo control of endosomal architecture by class II-associated invariant chain and cathepsin S

The invariant chain (Ii) is a chaperone that regulates assembly and transport of class II MHC molecules. In the absence of the lysosomal protease cathepsin S (CatS), degradation of Ii is impaired and an Ii remnant that extends from the N terminus to about residue 110 accumulates in class II MHC-positive endosomal compartments, which are enlarged in size and lack multivesicular morphology. In primary B cells examined in vitro and in lymph nodes examined by immuno-electron microscopy, CatS controls architecture of class II-positive endosomal compartments. In a compound mutant mouse that lacks both CatS and Ii, the normal size of endosomes in class II-positive cells is restored, although internal endosomal membranes are absent. Proper degradation of Ii is thus essential for normal endosomal morphology in antigen-presenting cells in vivo.     

Recruitment of immature plasmacytoid dendritic cells (plasmacytoid monocytes) and myeloid dendritic cells in primary cutaneous melanomas

The present study has analysed the distribution and phenotype of dendritic cells (DCs) in primary cutaneous melanomas and sentinel lymph nodes by immunohistochemistry. In primary melanomas, an increase of DCs was found in the epidermis and the peritumoural area. Intraepidermal DCs were mostly CD1a⁺/Langerin⁺ Langerhans cells. Peritumoural DCs included a large population of DC‐SIGN⁺/mannose‐receptor⁺/CD1a^? DCs, a small subset of CD1a⁺ DCs, and, remarkably, plasmacytoid monocytes/plasmacytoid DCs (PM/PDCs). The PM/PDCs, most likely recruited by SDF‐1 secreted by melanoma cells, produced type I interferon (IFN‐I), but the expression of the IFN‐α inducible protein MxA was extremely variable and very limited in the majority of cases. All DC subsets were predominantly immature. The peritumoural area also contained a minor subset of mature CD1a⁺ DCs. However, the small amount of local interleukin (IL)‐12 p40 mRNA and the naïve phenotype of 20–50% of peritumoural T‐lymphocytes are consistent with poor T‐cell stimulation or erroneous recruitment. In sentinel lymph nodes, notable expansion of mature CD1a⁺/Langerin⁺ DCs was observed. The paucity of intratumoural DCs and the predominant immature phenotype of peritumoural dermal DCs indicate defective maturation of primary cutaneous melanoma‐associated DCs, resulting in lack of T‐cell priming. These results may explain why melanoma cells grow despite the presence of infiltrating immune cells. Copyright © 2003 John Wiley & Sons, Ltd.     

慢性HCV感染者外周血中髓样和浆样树突状细胞频数和表型研究

目的 探讨慢性HCV感染者外周血中髓样树突状细胞(mDC)和浆样树突状细胞(pDC)频数和表型的变化,并分析其与丙型肝炎临床指标间的相关性.方法 采用流式细胞术检测HCV感染者及健康对照外周血中mDC和pDC的频数及细胞表面共刺激分子HLA-DR、CD83、CD86、CD40和共抑制分子PD-L1的表达水平,并分析DC频数与HCV感染者血浆病毒载量、谷丙转氨酶(ALT)的相关性.结果 与健康对照组相比,HCV感染者外周血中mDC和pDC的频数明显降低(患者组分别为0.37±0.19和0.19±0.12,对照组为0.51±0.18和0.29±0.13,P＜0.05),且mDC频数与血浆HCV载量和血清ALT水平呈负相关(r=-0.5878,P＜0.0001;r=-0.4628,P=0.003).患者mDC和pDC表面共刺激分子HLA-DR、CD83、CD86、CD40以及共抑制分子PD-L1的表达均有不同程度升高,差别有统计学意义(共刺激分子P＜0.01,共抑制分子P＜0.05或0.01).结论 慢性HCV感染者外周血mDC和pDC频数下降,但DC表面共刺激分子和共抑制分子的表达均明显升高.该结果提示mDC数量的减少可能与HCV的慢性持续性感染有关.

Abstract：

Objective To explore the frequencies and phenotype of myeloid and plasmacytoid dendritic cells (mDC and pDC) in chronic HCV infection and to investigate the relationships between DC frequencies and HCV viral load and serum ALT level. Methods PBMC were isolated from chronic HCV infected patients and healthy control. Multi-color flow cytometry was used to analyze the frequencies and surface marker expression on mDC and pDC. The relationship between DC frequencies and viral load and ALT level was also calculated. Results In comparison with healthy control, frequencies of mDC and pDC in chronic HCV infection were significantly decreased (0. 37 ± 0. 19 and 0. 19 ± 0. 12 vs 0. 51 ± 0. 18 and 0. 29 ± 0.13, P＜0.05). The frequency of mDC was negatively correlated with HCV viral load (r= -0.5878, P ＜ 0. 0001 ) and serum ALT level ( r = - 0. 4628 , P = 0. 003 ). Both costimulatory markers ( HLA-DR, CD83, CD86, and CD40) and coinhibitory marker (PD-L1) expression on mDC and pDC in HCV infection were increased (P＜0.01 for costimulatory marker, P＜0.05 or F＜0.01 for coinhibitory marker). Conclusion The frequencies of mDC and pDC in chronic HCV infection were decreased, while the expression of costimulatory markers and coinhibitory marker were increased or not decreased in HCV infection. The decreased frequency of mDC was probably related to persistance of HCV infection.     

Cross-presentation: dendritic cells and macrophages bite off more than they can chew!

As immunologists, our knowledge of the molecular mechanisms which underlie the presentation of antigens derived from extracellular or 'exogenous' sources to CD8 cytotoxic lymphocytes (CTL) has been limited. This process, termed 'cross-presentation', has been linked to the elicitation of protective CTL responses against tumours and may be extremely important in generating immune responses against clinically relevant pathogens that do not infect tissues of haemopoietic origin. It is now known that cross-presentation of exogenous antigens on major histocompatibility complex (MHC) class I occurs through several distinct cellular pathways. In this review we outline and discuss some recent advances in our understanding of these pathways.     

Dendritic cells, but not macrophages or B cells, activate major histocompatibility complex class II-restricted CD4+ T cells upon immune-complex uptake in vivo

Professional antigen-presenting cells (APC) are able to process and present exogenous antigen leading to the activation of T cells. Antigen-immunoglobulin (Ig)G complexes (IC) are much more efficiently processed and presented than soluble antigen. Dendritic cells (DC) are known for their ability to take up and process immune complex (IC) via FcgammaR, and they have been shown to play a crucial role in IC-processing onto major histocompatibility complex (MHC) class I as they contain a specialized cross-presenting transport system required for MHC class I antigen-processing. However, the MHC class II-antigen-processing pathway is distinct. Therefore various other professional APC, like macrophages and B cells, all displaying FcgammaR, are thought to present IC-delivered antigen in MHC class II. Nonetheless, the relative contribution of these APC in IC-facilitated antigen-presentation for MHC class II in vivo is not known. Here we show that, in mice, both macrophages and DC, but not B cells, efficiently capture IC. However, only DC, but not macrophages, efficiently activate antigen-specific MHC class II restricted CD4(+) T cells. These results indicate that mainly DC and not other professional APC, despite expressing FcgammaR and MHC class II, contribute significantly to IC-facilitated T cell activation in vivo under steady-state conditions.     

Differential migration behavior and chemokine production by myeloid and plasmacytoid dendritic cells

The existence of dendritic cell (DC) subsets is firmly established, but their trafficking properties are still largely unknown. We have indicated that myeloid dendritic cells (M-DCs) and plasmacytoid dendritic cells (P-DCs) isolated from human blood differ widely in the capacity to migrate to chemotactic stimuli. The pattern of chemokine receptors expressed ex vivo by both subsets is similar, but P-DCs display, compared with M-DCs, higher levels of CC chemokine receptor (CCR)5, CCR7, and CXCR3. Intriguingly, most chemokine receptors of P-DCs, in particular those specific for inflammatory chemokines and classical chemotactic agonists, are not functional in circulating cells. Following maturation induced by cluster designation (CD)40 ligation, the receptors for inflammatory chemokines are downregulated and CCR7 on P-DCs becomes coupled to migration. The drastically impaired capacity of blood P-DCs to migrate in response to inflammatory chemotactic signals contrasts with the response to lymph node-homing chemokines, indicating a propensity to migrate to secondary lymphoid organs rather than to sites of inflammation. The distinct migration behavior of DC subsets is accompanied by a different profile of chemokine production. In contrast to the high production by M-DCs, the homeostatic CC chemokine ligand (CCL)17/ thymus- and activation-regulated chemokine (TARC) is not produced by PDCs in response to any stimulus tested and their production of CCL22/MDC is minimal, if any, compared with M-DCs. Thus, stimulated M-DCs, but not P-DCs, are able to produce high levels of chemokines recruiting T-helper 2 cells (Th2) and T-regulatory cells. Conversely, the proinflammatory chemokine CCL3/macrophage inflammatory protein (MIP)-1 is predominantly produced by P-DCs. Therefore, P-DCs appear to produce preferentially proinflammatory chemokines, but to respond selectively to homeostatic ones, whereas the reverse is true for M-DCs, highlighting not only the different migratory properties of these DC subsets, but also their capacity to recruit different cell types at inflammation sites.     

Tumorous proliferations of plasmacytoid dendritic cells and Langerhans cells associated with acute myeloid leukaemia

Song H‐L, Huang W‐Y, Chen Y‐P & Chang K‐C
(2012) Histopathology  61, 974–983 Tumorous proliferations of plasmacytoid dendritic cells and Langerhans cells associated with acute myeloid leukaemia Aims: Proliferation of plasmacytoid dendritic cells (PDCs) occurs in both reactive lymphoid hyperplasia and myeloproliferative disorders, especially chronic myelomonocytic leukaemia. PDCs in the former appear reactive, but in the latter are reported to be clonally related to the underlying myeloid neoplasm. Langerhans cells (LCs), another type of dendritic cell, also proliferate in both reactive dermatoses and, rarely, myeloproliferative disorders, such as acute leukaemia. Methods and results: We report a rare case of tumorous proliferation of PDCs and LCs in the systemic lymph nodes in a 55‐year‐old man with acute myeloid leukaemia. A microsatellite instability assay showed identical patterns of short tandem repeats in both microdissected PDC and LC components, along with blood blasts. Conclusions: We hypothesize that the combined proliferations of PDCs and LCs derive from the same haematopoietic stem cells, but that they differentiate divergently under the effect of different microenvironments.     

Aberrant plasmacytoid dendritic cell distribution and function in patients with Crohn's disease and ulcerative colitis

Dendritic cell (DC) function is believed to be of critical importance for the pathogenesis of inflammatory bowel disease (IBD). To date, most research in animal models and the few human data available is restricted to myeloid DC, while plasmacytoid DC (pDC) capable of controlling both innate and adaptive immune responses have not yet been investigated systematically in human Crohn's disease (CD) or ulcerative colitis (UC). CD11c^‐, CD303⁺/CD304⁺ and CD123⁺ pDC from peripheral blood (n = 90), mucosal tissue (n = 28) or mesenteric lymph nodes (n = 40) (MLNs) of patients with UC and CD or controls were purified and cultured. Thereafter, pDC were enumerated, phenotyped and cytokine secretion measured by flow cytometry (FACS), immunohistochemistry and/or cytometric bead array, respectively. Interferon (IFN)‐α secretion following cytosine phosphatidyl guanine (CpG) A oligodeoxynucleotide (ODN) 2216 (5′‐GGGGGACGATCGTCGGGGGG‐3′) stimulation was assessed by enzyme‐linked immunosorbent assay (ELISA). We found a significantly higher frequency of pDC in the inflamed colonic mucosa and MLN of IBD patients. Moreover, the fraction of CD40 and CD86 expressing cultured peripheral blood pDC was significantly higher in flaring UC and CD patients and their secretion of tumour necrosis factor (TNF)‐α, interleukin (IL)‐6 and IL‐8 were increased significantly compared with controls. In contrast, the IFN‐α secretion of peripheral blood pDC isolated from flaring IBD, particularly in UC patients, was reduced significantly compared with controls. Our data suggest an aberrant distribution and function of pDC in IBD, contrary to their generally implicated role as inducers of tolerance. We speculate that the impaired IFN‐α secretion may relate to the hypothesized defect in innate immunity in IBD and could also impact upon the generation of regulatory T cells (T_reg).     

Development and functional specialization of CD103+ dendritic cells

Summary: CD103 (α_E) integrin expression distinguishes a population of dendritic cells (DCs) that can be found in many if not all lymphoid and non-lymphoid organs. CD103⁺ DCs display distinct functional activities. Migratory CD103⁺ DCs derived from skin, lung, and intestine efficiently present exogenous antigens in their corresponding draining lymph nodes to specific CD8⁺ T cells through a mechanism known as cross-presentation. On the T cells they prime, intestinal CD103⁺ DCs can drive the induction of the chemokine receptor CCR9 and α₄β₇ integrin, both known as gut-homing receptors. CD103⁺ DCs also contribute to control inflammatory responses and intestinal homeostasis by fostering the conversion of naive T cells into induced Foxp3⁺ regulatory T cells, a mechanism that relies on transforming growth factor-β and retinoic acid signaling. This review discusses recent findings that identify murine CD103⁺ DCs as important regulators of the immune response.