Protective T cell immunity in mice following protein-TLR7/8 agonist-conjugate immunization requires aggregation, type I IFN, and multiple DC subsets
Kathrin Kastenmüller, Ulrike Wille-Reece, Ross W.B. Lindsay, Lauren R. Trager, Patricia A. Darrah, Barbara J. Flynn, Maria R. Becker, Mark C. Udey, Björn E. Clausen, Botond Z. Igyarto, Daniel H. Kaplan, Wolfgang Kastenmüller, Ronald N. Germain, Robert A. Seder
Kathrin Kastenmüller, Ulrike Wille-Reece, Ross W.B. Lindsay, Lauren R. Trager, Patricia A. Darrah, Barbara J. Flynn, Maria R. Becker, Mark C. Udey, Björn E. Clausen, Botond Z. Igyarto, Daniel H. Kaplan, Wolfgang Kastenmüller, Ronald N. Germain, Robert A. Seder
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Research Article Immunology

Protective T cell immunity in mice following protein-TLR7/8 agonist-conjugate immunization requires aggregation, type I IFN, and multiple DC subsets

Abstract

The success of a non-live vaccine requires improved formulation and adjuvant selection to generate robust T cell immunity following immunization. Here, using protein linked to a TLR7/8 agonist (conjugate vaccine), we investigated the functional properties of vaccine formulation, the cytokines, and the DC subsets required to induce protective multifunctional T cell immunity in vivo. The conjugate vaccine required aggregation of the protein to elicit potent Th1 CD4+ and CD8+ T cell responses. Remarkably, the conjugate vaccine, through aggregation of the protein and activation of TLR7 in vivo, led to an influx of migratory DCs to the LN and increased antigen uptake by several resident and migratory DC subsets, with the latter effect strongly influenced by vaccine-induced type I IFN. Ex vivo migratory CD8–DEC205+CD103–CD326– langerin-negative dermal DCs were as potent in cross-presenting antigen to naive CD8+ T cells as CD11c+CD8+ DCs. Moreover, these cells also influenced Th1 CD4+ T cell priming. In summary, we propose a model in which broad-based T cell–mediated responses upon vaccination can be maximized by codelivery of aggregated protein and TLR7/8 agonist, which together promote optimal antigen acquisition and presentation by multiple DC subsets in the context of critical proinflammatory cytokines.

Authors

Kathrin Kastenmüller, Ulrike Wille-Reece, Ross W.B. Lindsay, Lauren R. Trager, Patricia A. Darrah, Barbara J. Flynn, Maria R. Becker, Mark C. Udey, Björn E. Clausen, Botond Z. Igyarto, Daniel H. Kaplan, Wolfgang Kastenmüller, Ronald N. Germain, Robert A. Seder

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Figure 5

OVA-conjugate vaccine confers protection against L. monocytogenes challenge.

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OVA-conjugate vaccine confers protection against L. monocytogenes challe...
(A) Mice (n = 4-5) were immunized twice, 3 weeks apart, with PBS, 20 μg OVA, OVA plus free TLR7/8 agonist, or the OVA-conjugate vaccine. Fourteen days after the second immunization mice were challenged i.v. with 3 × 104 CFUs of recombinant L. monocytogenes OVA. Bacterial loads in spleen and liver were enumerated 3 days after the challenge. (B) Mice (n = 4–5) were immunized once with 20 μg OVA plus free TLR7/8 agonist or the OVA-conjugate vaccine or were left untreated. Six weeks after immunization mice were challenged i.v. with 6 × 104 CFUs of recombinant L. monocytogenes OVA. Bacterial loads in spleen and liver were enumerated 3 days after the challenge. Solid lines represent the geometrical mean. Dotted lines represents the level of detection. *P < 0.05, Mann-Whitney test, comparing OVA-conjugate with all other vaccine groups. Each symbol represents an individual mouse.