Direct interaction between cholera toxin and dendritic cells is required for oral adjuvant activity.

Cholera toxin (CT) binds to GM1-ganglioside receptors present on all nucleated cells. Despite this, it is a very potent mucosal adjuvant that has a dramatic impact on immune cells, as well as nerve and epithelial cells, causing diarrhea. This fact has hampered our understanding of whether the adjuvanticity of CT is direct or indirect, as cells that bind CT may or may not be involved in its adjuvant function. The mucosal barrier is maintained by tight junctions between epithelial cells but dendritic cells (DCs) can protrude luminal dendrites. Here we investigated which cells are involved in the immune augmenting effect of CT. We explored oral immunizations with ovalbumin (OVA) and CT in bone marrow chimeric mice deficient in GM1-ganglioside in defined cellular subsets. We found that chimeric mice lacking GM1 in nonhematopoietic cells, including epithelial cells, mounted an unaltered intestinal IgA response. In contrast, chimeric mice lacking GM1-expressing hematopoietic cells in general, or specifically GM1-expressing conventional DCs (cDCs), largely failed to elicit anti-OVA adaptive immune responses. Therefore, the adjuvanticity of CT does not require epithelial activation, but is directly dependent on the binding of CT to gut cDCs via GM1-ganglioside. These results could have important implications for the generation of novel oral adjuvants.

The subcellular location of antigen expressed by adenoviral vectors modifies adaptive immunity but not dependency on cross-presenting dendritic cells.

Adenoviral (Ad) vaccine vectors can generate protective immunity to various pathogens in animal studies. However, recent failures in clinical vaccine trials have underscored the need for a better understanding of how mucosal immune responses to Ad-encoded vaccine Ags are generated in vivo. In this study, we addressed whether directing Ad-encoded ovalbumin (OVA) to different subcellular compartments influences the generation of OVA-specific acquired immunity and the APCs required following i.n. immunization of mice. We show that both secreted and membrane-anchored OVA activate CD4(+) T cells, induce cytotoxic CD8(+) T lymphocytes (CTLs) and generate serum IgG. Additionally, vaginal IgG is induced when OVA is expressed at these subcellular locations, but only the secreted form generates a significant IgA response in the lungs. On the contrary, intracellular expression of OVA efficiently expands CD8(+) T cells but fails to activate CD4(+) T cells, results in poor CTL activity, and does not generate Abs. Finally, we show that regardless of the subcellular localization of OVA, conventional DCs (cDCs) are required for the activation of T cells. However, the direct transduction of conventional DCs is not essential. These findings have important implications for the improvement of Ad vector design and vaccine-induced mucosal immunity.