Modification in the function of dendritic cells (DC), such as that achieved by microbial stimuli or T cell help, plays a critical role in determining the quality and size of adaptive responses to Ag. NKT cells bearing an invariant TCR (iNKT cells) restricted by nonpolymorphic CD1d molecules may constitute a readily available source of help for DC. We therefore examined T cell responses to i.v. injection of soluble Ag in the presence or the absence of iNKT cell stimulation with the CD1d-binding glycolipid α-galactosylceramide (α-GalCer). Considerably enhanced CD4+ and CD8+ T cell responses were observed when α-GalCer was administered at the same time as or close to OVA injection. This enhancement was dependent on the involvement of iNKT cells and CD1d molecules and required CD40 signaling. Studies in IFN-γR−/− mice indicated that IFN-γ was not required for the adjuvant effect of α-GalCer. Consistent with this result, enhanced T cell responses were observed using OCH, an analog of α-GalCer with a truncated sphingosine chain and a reduced capacity to induce IFN-γ. Splenic DC from α-GalCer-treated animals expressed high levels of costimulatory molecules, suggesting maturation in response to iNKT cell activation. Furthermore, studies with cultured DC indicated that potentiation of T cell responses required presentation of specific peptide and α-GalCer by the same DC, implying conditioning of DC by iNKT cells. The iNKT-enhanced T cell responses resisted challenge with OVA-expressing tumors, whereas responses induced in the absence of iNKT stimulation did not. Thus, iNKT cells exert a significant influence on the efficacy of immune responses to soluble Ag by modulating DC function.
The fate of dendritic cells (DC) after they have initiated a T cell immune response is still undefined. We have monitored the migration of DC labeled with a fluorescent tracer and injected s.c. into naive mice or into mice with an ongoing immune response. DC not loaded with Ag were detected in the draining lymph node in excess of 7 days after injection with maximum numbers detectable ∼40 h after transfer. In contrast, DC that had been loaded with an MHC class I-binding peptide disappeared from the lymph node with kinetics that parallel the known kinetics of activation of CD8+ T cells to effector function. In the presence of high numbers of specific CTL precursors, as in TCR transgenic mice, DC numbers were significantly decreased by 72 h after injection. The rate of DC disappearance was extremely rapid and efficient in recently immunized mice and was slower in “memory” mice in which memory CD8+ cells needed to reacquire effector function before mediating DC elimination. We also show that CTL-mediated clearance of Ag-loaded DC has a notable effect on immune responses in vivo. Ag-specific CD8+ T cells failed to divide in response to Ag presented on a DC if the DC were targets of a pre-existing CTL response. The induction of antitumor immunity by tumor Ag-loaded DC was also impaired. Therefore, CTL-mediated clearance of Ag-loaded DC may serve as a negative feedback mechanism to limit the activity of DC within the lymph node.
The lifespan and survival of dendritic cells (DC) in vivo are potentially critical to the expansion of T cell immune responses. We have previously reported that DC loaded with specific antigen are rapidly eliminated by cytotoxic T lymphocytes (CTL) in vivo, but the site, mechanism, and consequences of DC elimination were not defined. In this article we show that DC elimination in vivo occurs in a perforin-dependent manner and does not require IFN-␥ or the presence of CD4 ؉ CD25 ؉ regulatory T cells. Most importantly, failure to eliminate DC had profound consequences on the CTL immune response. Perforin-deficient mice showed a progressive increase in the numbers of antigen-specific CD8 ؉ T cells after repeated immunizations with DC. In contrast, in control mice the number of antigen-specific CD8 ؉ T cells did not notably increase with repeated immunizations. Lastly, we also show that CTLmediated elimination of DC occurs in peripheral tissues but not in the lymph node. Our data suggest that CTL act as ''gatekeepers'' that control access of antigen-loaded DC into the lymph node, thereby preventing continued expansion of antigen-specific T cells.cytotoxic T cells ͉ immunoregulation ͉ killing D endritic cells (DC) are powerful antigen-presenting cells that are critical for the initiation of CD4 ϩ and CD8 ϩ T cell responses. DC reside in peripheral tissues where they take up antigens from the external environment, then migrate to the lymph nodes where they interact with antigen-specific T cells and induce their activation to proliferation and effector function (1, 2). The lifespan of DC once in the lymph node is thought to be relatively brief, but experimental estimates have not yielded a consistent figure (3-5).The mechanism and regulation of DC survival and death (6, 7) are likely to be important in maintaining the homeostatic balance of the immune system. A few reports have linked extended survival of DC to enhanced or dysregulated T cell immune responses and lymphoproliferative disease (8-10). In contrast, reduced survival of DC has been associated with impaired immune responses (7). It is presently unclear whether T cells also influence the lifespan of DC in an antigen-specific fashion. In lymph nodes of mice adoptively transferred with CD4 ϩ T cell receptor (TCR) transgenic T cells, DC presenting specific antigen disappear more rapidly than DC not presenting antigen (11), suggesting that T cells may have a role in regulating DC numbers and survival. Experiments using infection with Listeria or malaria also suggest that the number of antigen-presenting cells becomes limiting during the early phases of CD8 ϩ immune responses and prevents the continued expansion of antigen-specific T cells (12, 13). Together, these experiments suggest the attractive hypothesis that T cells may be able to regulate their own responses in a feedback fashion, by affecting the survival of antigen-presenting DC.We have previously reported that DC loaded with antigen and injected s.c. into immune mice are rapidly eliminated by CD8 ϩ T cel...
Distinct dendritic cell (DC) subsets differ with respect to pathways of Ag uptake and intracellular routing to MHC class I or MHC class II molecules. Murine studies suggest a specialized role for CD8α+ DC in cross-presentation, where exogenous Ags are presented on MHC class I molecules to CD8+ T cells, while CD8α− DC are more likely to present extracellular Ags on MHC class II molecules to CD4+ T cells. As a proportion of CD8α+ DC have been shown to express langerin (CD207), we investigated the role of langerin+CD8α+ DC in presenting Ag and priming T cell responses to soluble Ags. When splenic DC populations were sorted from animals administered protein i.v., the ability to cross-present Ag was restricted to the langerin+ compartment of the CD8α+ DC population. The langerin+CD8α+ DC population was also susceptible to depletion following administration of cytochrome c, which is known to trigger apoptosis if diverted to the cytosol. Cross-priming of CTL in the presence of the adjuvant activity of the TLR2 ligand N-palmitoyl-S-[2,3-bis(palmitoyloxy)-(2RS)-propyl]-[R]-Cys-[S]-Serl-[S]-Lys4-trihydrochloride or the invariant NKT cell ligand α-galactosylceramide was severely impaired in animals selectively depleted of langerin+ cells in vivo. The production of IL-12p40 in response to these systemic activation stimuli was restricted to langerin+CD8α+ DC, and the release of IL-12p70 into the serum following invariant NKT cell activation was ablated in the absence of langerin+ cells. These data suggest a critical role for the langerin+ compartment of the CD8α+ DC population in cross-priming and IL-12 production.
Plasmacytoid dendritic cells (PDCs) are a unique leukocyte population capable of secreting high levels of type I interferon (IFN) in response to viruses and bacterial stimuli. In vitro experiments have shown that upon maturation, human and murine PDCs develop into potent immunostimulatory cells; however, their ability to prime an immune response in vivo remains to be addressed. We report that CpG-matured murine PDCs are capable of eliciting in naive mice antigen-specific CTLs against endogenous antigens as well as exogenous peptides, but not against an exogenous antigen. Type I IFN is not required for priming, as injection of CpG-matured PDCs into type I IFN receptor–deficient mice elicits functional CTL responses. Mature PDCs prime CTLs that secrete IFN-γ and protect mice from a tumor challenge. In contrast, immature PDCs are unable to prime antigen-specific CTLs. However, mice injected with immature PDCs are fully responsive to secondary antigenic challenges, suggesting that PDCs have not induced long-lasting tolerance via anergic or regulatory T cells. Our results underline the heterogeneity and plasticity of different antigen-presenting cells, and reveal an important role of mature PDCs in priming CD8 responses to endogenous antigens, in addition to their previously reported ability to modulate antiviral responses via type I IFN.
Activation of invariant CD1d-dependent NK T cells (iNKT cells) in vivo through
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