Brian L. Kelsall

Unique Functions of CD11b+, CD8α+, and Double-Negative Peyer’s Patch Dendritic Cells

We have recently demonstrated the presence of three populations of dendritic cells (DC) in the murine Peyer’s patch. CD11b+/CD8α− (myeloid) DCs are localized in the subepithelial dome, CD11b−/CD8α+ (lymphoid) DCs in the interfollicular regions, and CD11b−/CD8α− (double-negative; DN) DCs at both sites. We now describe the presence of a novel population of intraepithelial DN DCs within the follicle-associated epithelium and demonstrate a predominance of DN DCs only in mucosal lymphoid tissues. Furthermore, we demonstrate that all DC subpopulations maintain their surface phenotype upon maturation in vitro, and secrete a distinct pattern of cytokines upon exposure to T cell and microbial stimuli. Only myeloid DCs from the PP produce high levels of IL-10 upon stimulation with soluble CD40 ligand− trimer, or Staphylococcus aureus and IFN-γ. In contrast, lymphoid and DN, but not myeloid DCs, produce IL-12p70 following microbial stimulation, whereas no DC subset produces IL-12p70 in response to CD40 ligand trimer. Finally, we show that myeloid DCs from the PP are particularly capable of priming naive T cells to secrete high levels of IL-4 and IL-10, when compared with those from nonmucosal sites, while lymphoid and DN DCs from all tissues prime for IFN-γ production. These findings thus suggest that DC subsets within mucosal tissues have unique immune inductive capacities.

Reciprocal IFN-γ and TGF-β responses regulate the occurrence of mucosal inflammation

Abstract Recent studies of oral tolerance and experimental colitis indicate that the occurrence of gastrointestinal inflammation is determined by a balance between proinflammatory interferon γ responses and anti-inflammatory transforming growth factor β responses. Here, Warren Strober and colleagues discuss the new findings.

Inflammation switches the differentiation program of Ly6Chi monocytes from antiinflammatory macrophages to inflammatory dendritic cells in the colon

Blood monocytes differentiate into distinct colonic macrophage or dendritic cell subsets depending on the presence or absence of inflammation

Mucosal AIDS vaccine reduces disease and viral load in gut reservoir and blood after mucosal infection of macaques

Given the mucosal transmission of HIV-1, we compared whether a mucosal vaccine could induce mucosal cytotoxic T lymphocytes (CTLs) and protect rhesus macaques against mucosal infection with simian/human immunodeficiency virus (SHIV) more effectively than the same vaccine given subcutaneously. Here we show that mucosal CTLs specific for simian immunodeficiency virus can be induced by intrarectal immunization of macaques with a synthetic-peptide vaccine incorporating the LT(R192G) adjuvant. This response correlated with the level of T-helper response. After intrarectal challenge with pathogenic SHIV-Ku2, viral titers were eliminated more completely (to undetectable levels) both in blood and intestine, a major reservoir for virus replication, in intrarectally immunized animals than in subcutaneously immunized or control macaques. Moreover, CD4+ T cells were better preserved. Thus, induction of CTLs in the intestinal mucosa, a key site of virus replication, with a mucosal AIDS vaccine ameliorates infection by SHIV in non-human primates.

The importance of local mucosal HIV-specific CD8(+) cytotoxic T lymphocytes for resistance to mucosal viral transmission in mice and enhancement of resistance by local administration of IL-12.

Although crucial to mucosal vaccine development, the mechanisms of defense against mucosal viral infection are still poorly understood. Protection, cytotoxic T lymphocytes (CTL), and neutralizing antibodies have all been observed, but cause and effect have been difficult to determine. The ability of CTL in the mucosa to mediate protection against mucosal viral transmission has never been proven. Here, we use an HIV peptide immunogen and an HIV-1 gp160-expressing recombinant vaccinia viral intrarectal murine challenge system, in which neutralizing antibodies do not play a role, to demonstrate for the first time that long-lasting immune resistance to mucosal viral transmission can be accomplished by CD8(+) CTL that must be present in the mucosal site of exposure. The resistance is ablated by depleting CD8(+) cells in vivo and requires CTL in the mucosa, whereas systemic (splenic) CTL are shown to be unable to protect against mucosal challenge. Furthermore, the resistance as well as the CTL response can be increased by local mucosal delivery of IL-12 with the vaccine. These results imply that induction of local mucosal CTL may be critical for success of a vaccine against viruses transmitted through a mucosal route, such as HIV.

Selective Suppression of IL-12 Production by Chemoattractants

We investigated the ability of chemoattractants to affect IL-12 production by human monocytes and dendritic cells. We found that pretreatment of monocytes with macrophage chemoattractant proteins (MCP-1 to -4), or C5a, but not stromal-derived factor-1, macrophage inflammatory protein-1α, RANTES, or eotaxin, inhibited IL-12 p70 production in response to stimulation with Staphylococcus aureus, Cowan strain 1 (SAC), and IFN-γ. The production of TNF-α and IL-10, however, was minimally affected by any of the chemoattractants. The degree of inhibition of IL-12 p70 production by MCP-1 to -4 was donor dependent and was affected by the autocrine inhibitory effects of IL-10. In contrast, C5a profoundly suppressed IL-12 production in an IL-10-independent fashion. Neither TGF-β1 nor PGE2 was important for the suppression of IL-12 by any of the chemoattractants tested. The accumulation of mRNA for both IL-12 p35 and p40 genes was inhibited by chemokine pretreatment. Interestingly, MCP-1 to -4 and C5a did not suppress IL-12 production by monocyte-derived dendritic cells (DC) stimulated with CD40 ligand and IFN-γ or by SAC and IFN-γ, suggesting that these factors may act at the site of inflammation to suppress IL-12 and IFN-γ production rather than in the lymph node to affect T cell priming. Despite the inability of C5a to inhibit IL-12 production by DCs, the receptor for C5a (CD88) was expressed by these cells, and recombinant C5a induced a Ca2+ flux. Taken together, these results define a range of chemoattractant molecules with the ability to suppress IL-12 production by human monocytes and have broad implications for the regulation of immune responses in vivo.

Dendritic cells at the host-pathogen interface

A May 2002 workshop in Virginia, USA, focused on dendritic cells. Kelsall and colleagues summarize here some of the outstanding questions raised at the conference.

Interleukin-12 Production by Dendritic Cells

Recent studies have demonstrated that the treatment of mice with anti-gp39 antibodies impairs T-cell functions in the murine collagen type II-induced arthritis model, in acute semi-allogenic graft-versus-host disease, and in the allo-specific CTL-reaction, that is, reactions that are believed to be mediated by Th1-type T cells. On the other hand, the administration of anti-gp39 antibody did not influence Th2 T-cells responses, suggesting that CD40-CD40L interactions are more crucial for Th1 than Th2 T-cell development. Recent studies also demonstrate that dendritic cells (DC) are capable of driving a Th1 T-cell response that is mediated by IL-12. In addition, stimulation of CD40 on human monocytes results in IL-12 production, suggesting that activated T cells expressing CD40L may directly induce the production of IL-12 by antigen-presenting cells, thus allowing for the generation of a Th1 T-cell response in the absence of intracellular pathogens. We investigated whether the CD40-CD40L interaction was important in the production of IL-12 by DCs in an in vitro system that allowed precise control of cytokine concentrations. Initially we showed that FACS-purified mouse spleen DCs produce high amounts of IL-12 p40 in response to CD40 crosslinking by CD40L-expressing fibroblasts. We then demonstrate that DCs also produce IL-12 p40 in a more physiologic system using purified DCs pulsed with ovalbumin (OVA) and then cultured with LECAM-1hi T cells from ovalbumin T-cell receptor transgenic mice. Finally, we show that IL-10 has a potent capacity to shut down CD40-induced IL-12 p40 secretion; and, in addition, IL-4 partially inhibits CD40-induced IL-12 p40 secretion and enhances IL-10-mediated inhibition in an additive fashion. We also investigated the in vivo relevance of this interaction in an experimental model for a Th1-mediated disease, the hapten reagent (TNBS)-induced colitis. The administration of anti-gp39 (CD40L) antibodies during the induction phase of the Th1 response completely prevented IFN-gamma production by CD4 T cells from the intestinal lamina propria and also the clinical and histological evidence of disease. In further studies we showed that the prevention of disease activity was due to an inhibition of IL-12 secretion. Thus, the injection of recombinant IL12 p75 heterodimer into TNBS + anti-gp39-treated mice reversed the effect of anti-gp39 and resulted in severe disease activity. In conclusion, these findings suggest that DCs produce IL-12 in response to CD40 signaling, that a mechanism by which IL-4 may induce Th2 development is by acting with IL-10 to inhibit IL-12 production by DCs, and that the CD40L-CD40 interaction is crucial for the IL-12-dependent priming of Th1 T cells in vivo.

Involvement of intestinal dendritic cells in oral tolerance, immunity to pathogens, and inflammatory bowel disease

Summary:  Dendritic cells (DCs) are composed of a family of cells, now recognized to be essential for innate and acquired immunity. DCs at mucosal surfaces have a particular capacity to induce the differentiation of regulatory T cells producing interleukin‐10 (IL‐10) and transforming growth factor‐β (TGF‐β) in the steady state (non‐infected, non‐immunized), yet they retain the capacity to induce effector T cells in response to invasive pathogens. This decision between the induction of active immunity and tolerance will depend on the subpopulation of DC involved and the surface receptors engaged during DC activation and T‐cell priming. The local microenvironment will likely play an important role both in defining the DC phenotype and in providing direct signals to responding T cells. Furthermore, DCs in organized mucosal lymphoid tissues preferentially induce the expression of CCR9 and α4β7 on T cells, which results in T‐cell homing to the intestinal lamina propria. Finally, DCs may play an important role in the maintenance of abnormal intestinal inflammation either by driving pathogenic T‐cell responses in mesenteric lymph nodes or by acting to expand or maintain pathogenic T cells locally at sites of inflammation. In this review, a brief discussion of general issues of DC biology that are pertinent to mucosal immunity is followed by a more in‐depth discussion of the phenotype and function of DC populations in the intestine.

Peyer's Patch Dendritic Cells Process Viral Antigen from Apoptotic Epithelial Cells in the Intestine of Reovirus-infected Mice

We explored the role of Peyers patch (PP) dendritic cell (DC) populations in the induction of immune responses to reovirus strain type 1 Lang (T1L). Immunofluorescence staining revealed the presence of T1L structural (σ1) and nonstructural (σNS) proteins in PPs of T1L-infected mice. Cells in the follicle-associated epithelium contained both σ1 and σNS, indicating productive viral replication. In contrast, σ1, but not σNS, was detected in the subepithelial dome (SED) in association with CD11c+/CD8α−/CD11blo DCs, suggesting antigen uptake by these DCs in the absence of infection. Consistent with this possibility, PP DCs purified from infected mice contained σ1, but not σNS, and PP DCs from uninfected mice could not be productively infected in vitro. Furthermore, σ1 protein in the SED was associated with fragmented DNA by terminal deoxy-UTP nick-end labeling staining, activated caspase-3, and the epithelial cell protein cytokeratin, suggesting that DCs capture T1L antigen from infected apoptotic epithelial cells. Finally, PP DCs from infected mice activated T1L-primed CD4+ T cells in vitro. These studies show that CD8α−/CD11blo DCs in the PP SED process T1L antigen from infected apoptotic epithelial cells for presentation to CD4+ T cells, and therefore demonstrate the cross-presentation of virally infected cells by DCs in vivo during a natural viral infection.