Priming CD8+ T cells with dendritic cells matured using TLR4 and TLR7/8 ligands together enhances generation of CD8+ T cells retaining CD28

TLRs expressed on dendritic cells (DCs) differentially activate DCs when activated alone or in combination, inducing distinct cytokines and costimulatory molecules that influence T-cell responses. Defining the requirements of DCs to program T cells during priming to become memory rather than effector cells could enhance vaccine development. We used an in vitro system to assess the influence of DC maturation signals on priming naive human CD8+ T cells. Maturation of DCs with lipopolysaccharide (LPS; TLR4) concurrently with R848 (TLR7/8) induced a heterogeneous population of DCs that produced high levels of IL12 p70. Compared with DCs matured with LPS or R848 alone, the DC population matured with both adjuvants primed CD8+ T-cell responses containing an increased proportion of antigen-specific T cells retaining CD28 expression. Priming with a homogenous subpopulation of LPS/R848-matured DCs that were CD83(Hi)/CD80+/CD86+ reduced this CD28+ subpopulation and induced T cells with an effector cytokine signature, whereas priming with the less mature subpopulations of DCs resulted in minimal T-cell expansion. These results suggest that TLR4 and TLR7/8 signals together induce DCs with fully mature and less mature phenotypes that are both required to more efficiently prime CD8+ T cells with qualities associated with memory T cells.     

Developmental dissociation of thymic dendritic cell and thymocyte lineages revealed in growth factor receptor mutant mice

Thymocytes and thymic dendritic cell (DC) lineages develop simultaneously and may originate from a common intrathymic progenitor. Mice deficient for two growth factor receptor molecules [c-kit and the common cytokine receptor gamma chain (gamma(c))] lack all thymocytes including T cell progenitors. Despite this lack of pro-T cells, thymic DC compartments were identified in c-kit(-)gamma(c)(-) mice. Thus, c-kit- and gamma(c)-mediated signals are not essential to generate thymic DCs. In addition, pro-T cells do not appear to be obligatory progenitors of thymic DCs, because DC development is dissociated from the generation of thymocytes in these mice. Thymic DCs in c-kit(-)gamma(c)(-) mice are phenotypically and functionally normal. In contrast to wild-type mice, however, thymic DCs in c-kit(-)gamma(c)(-) and, notably, in RAG-2-deficient mice are CD8alpha(neg/low), indicating that CD8alpha expression on thymic DCs is not independent of thymocytes developing beyond the "RAG-block."     

Arrest of human dendritic cells at the CD34-/CD4+/HLA-DR+ stage in the bone marrow of NOD/SCID-human chimeric mice

Human dendritic cell (DC) precursors were engrafted and maintained in NOD/SCID- human chimeric mice (NOD/SCID-hu mice) implanted with human cord blood mononuclear cells, although no mature human DCs were detected in lymphoid organs of the mice. Two months after implantation, bone marrow (BM) cells of NOD/SCID-hu mice formed colonies showing DC morphology and expressing CD1a in methylcellulose culture with granulocyte-macrophage colony-stimulating factor (GM-CSF) and tumor necrosis factor alpha (TNF-alpha). The CD34-/CD4+/HLA-DR+ cell fraction in NOD/SCID-hu mouse BM generated CD1a(+) cells that were highly stimulatory in mixed leukocyte reactions in culture with GM-CSF and TNF-alpha. These results suggest a strong potential for NOD/SCID-hu BM to generate human DCs, although DC differentiation may be blocked at the CD34-/CD4+/HLA-DR+ stage. (Blood. 2001;97:3655-3657)     

Generation of murine dendritic cells from flt3-ligand-supplemented bone marrow cultures

Murine dendritic cells (DCs) can be classified into at least 2 subsets, "myeloid-related" (CD11b(bright), CD8alpha(-)) and "lymphoid-related" (CD11b(dull), CD8alpha(+)), but the absolute relationship between the 2 remains unclear. Methods of generating DCs from bone marrow (BM) precursors in vitro typically employ granulocyte-macrophage colony-stimulating factor (GM-CSF) as the principal growth factor, and the resultant DCs exhibit a myeloidlike phenotype. Here we describe a flt3-ligand (FL)-dependent BM culture system that generated DCs with more diverse phenotypic characteristics. Murine BM cells cultured at high density in recombinant human FL for 9 days developed into small lymphoid-sized cells, most of which expressed CD11c, CD86, and major histocompatibility complex (MHC) class II. The CD11c(+) population could be divided into 2 populations on the basis of the level of expression of CD11b, which may represent the putative myeloid- and lymphoid-related subsets. The FL in vitro-derived DCs, when treated with interferon-alpha or lipopolysaccharide during the final 24 hours of culture, expressed an activated phenotype that included up-regulation of MHC class II, CD1d, CD8alpha, CD80, CD86, and CD40. The FL-derived DCs also exhibited potent antigen-processing and antigen-presenting capacity. Neutralizing anti-interleukin-6 (IL-6) antibody, but not anti-GM-CSF, significantly reduced the number of DCs generated in vitro with FL, suggesting that IL-6 has a role in the development of DCs from BM precursors. Stem cell factor, which exhibits some of the same bioactivities as FL, was unable to replace FL to promote DC development in vitro. This culture system will facilitate detailed analysis of murine DC development.     

Anatomic location and T-cell stimulatory functions of mouse dendritic cell subsets defined by CD4 and CD8 expression

Mouse spleen contains CD4+, CD8alpha+, and CD4-/CD8alpha- dendritic cells (DCs) in a 2:1:1 ratio. An analysis of 70 surface and cytoplasmic antigens revealed several differences in antigen expression between the 3 subsets. Notably, the Birbeck granule-associated Langerin antigen, as well as CD103 (the mouse homologue of the rat DC marker OX62), were specifically expressed by the CD8alpha+ DC subset. All DC types were apparent in the T-cell areas as well as in the splenic marginal zones and showed similar migratory capacity in collagen lattices. The 3 DC subtypes stimulated allogeneic CD4+ T cells comparably. However, CD8alpha+ DCs were very weak stimulators of resting or activated allogeneic CD8+ T cells, even at high stimulator-to-responder ratios, although this defect could be overcome under optimal DC/T cell ratios and peptide concentrations using CD8+ F5 T-cell receptor (TCR)-transgenic T cells. CD8alpha- or CD8alpha+ DCs presented alloantigens with the same efficiency for lysis by cytotoxic T lymphocytes (CTLs), and their turnover rate of class I-peptide complexes was similar, thus neither an inability to present, nor rapid loss of antigenic complexes from CD8alpha DCs was responsible for the low allostimulatory capacity of CD8alpha+ DCs in vitro. Surprisingly, both CD8alpha+ DCs and CD4-/CD8- DCs efficiently primed minor histocompatibility (H-Y male antigen) cytotoxicity following intravenous injection, whereas CD4+ DCs were weak inducers of CTLs. Thus, the inability of CD8alpha+ DCs to stimulate CD8+ T cells is limited to certain in vitro assays that must lack certain enhancing signals present during in vivo interaction between CD8alpha+ DCs and CD8+ T cells.     

Development of thymic and splenic dendritic cell populations from different hemopoietic precursors.

The antigen-presenting dendritic cells (DCs) found in mouse lymphoid tissues are heterogeneous. Several types of DCs have been identified on the basis of the expression of different surface molecules, including CD4, CD8alpha, and DEC-205. Previous studies by the authors showed that the mouse intrathymic lymphoid-restricted precursors (lin(-)c-kit(+)Thy-1(low)CD4(low)) can produce DCs in the thymus and spleen upon intravenous transfer, suggesting a lymphoid origin of these DCs. In the current study, the potential for DC production by the newly identified bone marrow (BM) common lymphoid precursors (CLPs), common myeloid precursors (CMPs), and committed granulocyte and macrophage precursors was examined. It was found that both the lymphoid and the myeloid precursors had the potential to produce DCs. All the different DC populations identified in mouse thymus and spleen could be produced by all these precursor populations. However, CLPs produced predominantly the CD4(-)CD8alpha(+) DCs, whereas CMPs produced similar numbers of CD4(-)CD8alpha(+) and CD4(+)CD8alpha(-) DCs, although at different peak times. On a per cell basis, the CLPs were more potent than the CMPs at DC production, but this may have been compensated for by an excess of CMPs over CLPs in BM. Overall, this study shows that the expression of CD8alpha does not delineate the hemopoietic precursor origin of DCs, and the nature of the early precursors may bias but does not dictate the phenotype of the DC product.     

CD8alpha+ dendritic cells originate from the CD8alpha- dendritic cell subset by a maturation process involving CD8alpha, DEC-205, and CD24 up-regulation.

CD8alpha+ and CD8alpha- dendritic cells (DCs) have been considered as independent DC subpopulations both ontogenetically and functionally during recent years. However, it has been demonstrated that both DC subsets can be generated from a single precursor population, supporting the concept that they do not represent separate DC lineages. By using highly purified splenic CD8alpha- DCs, which were injected intravenously and traced by means of an Ly5.1/Ly5.2 transfer system, this study shows that CD8alpha- DCs acquired the phenotypic characteristics of CD8alpha+ DCs, by a differentiation process involving CD8alpha, DEC-205, and CD24 up-regulation, paralleled by the down-regulation of CD11b, F4/80, and CD4. These data demonstrate that CD8alpha+ DCs derive from CD8alpha- DCs, and strongly support that CD8alpha- and CD8alpha+ DCs represent different maturation or differentiation stages of the same DC population. Therefore, CD8alpha+ DCs would represent the last stage of DC differentiation, playing an essential role in the induction of T-cell responses, due to their antigen-presenting potential, cross-priming ability, and capacity to secrete large amounts of key cytokines such as interferon gamma and interleukin-12.     

Immediate Exposure to TNF-α Activates Dendritic Cells Derived from Non-Purified Cord Blood Mononuclear Cells

Background: Tumor necrosis factor alpha (TNF-α) is a primary mediator of immune regulation and might be required in the early stages of DC development from CD34+ cells. However, details of optimal timing of exposure to TNF-α in DC development process in monocytes or non-purified hematopoitic cells are still lacking and clear benefits of this approach to the development of DCs remain to be validated. Objective: To evaluate the effect of early and late exposure to TNF-α on DC devel-opment from non-purified cord blood mononuclear cells. Methods: To define the ef-fects of early exposure to TNF-α on cord blood mononuclear cells, we cultured UCB-MNC in the presence of SCF, Flt3L, GM-CSF and IL-4 for 14 days and matured them for an extra 4 days. TNF-α was added on day 0, 7 and 14 in TNF-α + group, and only on day 14 in TNF-α - group where it was used only as a maturation factor. Results: Immediate exposure to TNF-α was shown to: (1) enhance the survival of cells in the first week of culture; (2) produce mature DCs with higher maturation markers (CD80, CD83, CD86 and HLA-DR); and (3) increase secretion of IL-12 by mature DCs. In contrast, delayed exposure to TNF-α stimulate mature DCs with less purity producing a high level of IL-10 and a low level of IL-12. Conclusion: We developed a simple, easy and cost effective method to generate DCs from non-fractionating mononuclear cells in this study. Also we confirm the presence of a large number of functional DCs under inflammatory conditions, where local concentrations of TNF-α were high.     

Concept of lymphoid versus myeloid dendritic cell lineages revisited: both CD8alpha(-) and CD8alpha(+) dendritic cells are generated from CD4(low) lymphoid-committed precursors

Two dendritic cell (DC) subsets have been identified in the murine system on the basis of their differential CD8alpha expression. CD8alpha(+) DCs and CD8alpha(-) DCs are considered as lymphoid- and myeloid-derived, respectively, because CD8alpha(+) but not CD8alpha(-) splenic DCs were generated from lymphoid CD4(low) precursors, devoid of myeloid reconstitution potential. Although CD8alpha(-) DCs were first described as negative for CD4, our results demonstrate that approximately 70% of them are CD4(+). Besides CD4(-) CD8alpha(-) and CD4(+) CD8alpha(-) DCs displayed a similar phenotype and T-cell stimulatory potential in mixed lymphocyte reaction (MLR), although among CD8alpha(-) DCs, the CD4(+) subset appears to have a higher endocytic capacity. Finally, experiments of DC reconstitution after irradiation in which, in contrast to previous studies, donor-type DCs were analyzed without depleting CD4(+) cells, revealed that both CD8alpha(+) DCs and CD8alpha(-) DCs were generated after transfer of CD4(low) precursors. These data suggest that both CD8alpha(+) and CD8alpha(-) DCs derive from a common precursor and, hence, do not support the concept of the CD8alpha(+) lymphoid-derived and CD8alpha(-) myeloid-derived DC lineages. However, because this hypothesis has to be confirmed at the clonal level, it remains possible that CD8alpha(-) DCs arise from a myeloid precursor within the CD4(low) precursor population or, alternatively, that both CD8alpha(+) and CD8alpha(-) DCs derive from an independent nonlymphoid, nonmyeloid DC precursor. In conclusion, although we favor the hypothesis that both CD8alpha(+) and CD8alpha(-) DCs derive from a lymphoid-committed precursor, a precise study of the differentiation process of CD8alpha(+) and CD8alpha(-) DCs is required to define conclusively their origin.     

5-lipoxygenase expression in dendritic cells generated from CD34(+) hematopoietic progenitors and in lymphoid organs

The 5-lipoxygenase (5-LO) pathway in human CD34(+) hematopoietic progenitor cells, which were induced to differentiate into dendritic cells (DCs) by cytokines in vitro and in DCs of lymphoid tissues in situ, was examined. Extracts prepared from HPCs contained low levels of 5-LO or 5-LO-activating protein. Granulocyte-macrophage colony-stimulating factor (GM-CSF) plus tumor necrosis factor-alpha (TNF-alpha) promoted DC differentiation and induced a strong rise in 5-LO and FLAP expression. Fluorescence-activated cell sorter (FACS) analyses identified a major DC population coexpressing human leukocyte antigen (HLA)-DR/CD80 and monocytic or Langerhans cell markers. Transforming growth factor-beta1 (TGF-beta-1), added to support DC maturation, strongly promoted the appearance of CD1a(+)/Lag(+) Langerhans-type cells as well as mature CD83(+) DCs. TGF-beta-1 further increased 5-LO and FLAP expression, recruited additional cells into the 5-LO(+) DC population, and promoted production of 5-hydroxyeicosatetraenoic acid and leukotriene B(4) in response to calcium (Ca(++)) ionophore A23187. These in vitro findings were corroborated by 5-LO expression in distinct DC phenotypes in vivo. Scattered 5-LO and FLAP in situ hybridization signals were recorded in cells of paracortical T-lymphocyte-rich areas and germinal centers (GCs) of lymph nodes (LNs) and tonsil and in cells of mucosae overlying the Waldeyer tonsillar ring. 5-LO protein localized to both CD1a(+) immature DCs and to CD83(+) mature interdigitating DCs of T-lymphocyte-rich areas of LNs and tonsil. As DCs have the unique ability to initiate naive lymphocyte activation, our data support the hypothesis that leukotrienes act at proximal steps of adaptive immune responses. (Blood. 2000;96:3857-3865)     

Dendritic cell potentials of early lymphoid and myeloid progenitors

It has been proposed that there are at least 2 classes of dendritic cells (DCs), CD8alpha(+) DCs derived from the lymphoid lineage and CD8alpha(-) DCs derived from the myeloid lineage. Here, the abilities of lymphoid- and myeloid-restricted progenitors to generate DCs are compared, and their overall contributions to the DC compartment are evaluated. It has previously been shown that primitive myeloid-committed progenitors (common myeloid progenitors [CMPs]) are efficient precursors of both CD8alpha(+) and CD8alpha(-) DCs in vivo. Here it is shown that the earliest lymphoid-committed progenitors (common lymphoid progenitors [CLPs]) and CMPs and their progeny granulocyte-macrophage progenitors (GMPs) can give rise to functional DCs in vitro and in vivo. CLPs are more efficient in generating DCs than their T-lineage descendants, the early thymocyte progenitors and pro-T cells, and CMPs are more efficient DC precursors than the descendant GMPs, whereas pro-B cells and megakaryocyte-erythrocyte progenitors are incapable of generating DCs. Thus, DC developmental potential is preserved during T- but not B-lymphoid differentiation from CLP and during granulocyte-macrophage but not megakaryocyte-erythrocyte development from CMP. In vivo reconstitution experiments show that CLPs and CMPs can reconstitute CD8alpha(+) and CD8alpha(-) DCs with similar efficiency on a per cell basis. However, CMPs are 10-fold more numerous than CLPs, suggesting that at steady state, CLPs provide only a minority of splenic DCs and approximately half the DCs in thymus, whereas most DCs, including CD8alpha(+) and CD8alpha(-) subtypes, are of myeloid origin. (Blood. 2001;97:3333-3341)     

1,25-Dihydroxyvitamin D(3) inhibits dendritic cell differentiation and maturation in vitro

OBJECTIVE: Because of its potent immunosuppressive properties in vitro as well as in vivo, we studied the effect of 1,25-dihydroxyvitamin D(3) (calcitriol) on differentiation, maturation, and function of dendritic cells (DC). MATERIALS AND METHODS: Monocyte-derived DCs were generated with GM-CSF plus IL-4, and maturation was induced by a 2-day exposure to TNFalpha. DCs were derived from CD34(+) progenitors using SCF plus GM-CSF plus TNFalpha. For differentiation studies, cells were exposed to calcitriol at concentrations of 10(-)(9)- 10(-7) M at days 0, 6, and 8, respectively. The obtained cell populations were evaluated by morphology, phenotype, and function. RESULTS: When added at day 0, calcitriol blocked DC differentiation from monocytes and inhibited the generation of CD1a(+) cells from progenitor cells while increasing CD14(+) cells. Exposure of immature DCs to calcitriol at day 6 resulted in a loss of the DC-characteristic surface molecule CD1a, downregulation of the costimulatory molecules CD40 and CD80, and MHC class II expression, whereas the monocyte/macrophage marker CD14 was clearly reinduced. In addition, calcitriol hindered TNFalpha-induced DC maturation, which is usually accompanied with induction of CD83 expression and upregulation of costimulatory molecules. In contrast, the mature CD83(+) DCs remained CD1a(+)CD14(-) when exposed to calcitriol. The capacity of cytokine-treated cells to stimulate allogeneic and autologous T cells and to take up soluble antigen was inhibited by calcitriol. CONCLUSION: The potent suppression of DC differentiation, the reversal of DC phenotype, and function in immature DCs, as well as the inhibition of DC maturation by calcitriol, may explain some of its immunosuppressive properties.