Discovering naturally processed antigenic determinants that confer protective T cell immunity
Pavlo Gilchuk, … , Andrew J. Link, Sebastian Joyce
Pavlo Gilchuk, … , Andrew J. Link, Sebastian Joyce
Published April 1, 2013
Citation Information: J Clin Invest. 2013;123(5):1976-1987. https://doi.org/10.1172/JCI67388.
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Technical Advance Immunology

Discovering naturally processed antigenic determinants that confer protective T cell immunity

Abstract

CD8+ T cells (TCD8) confer protective immunity against many infectious diseases, suggesting that microbial TCD8 determinants are promising vaccine targets. Nevertheless, current T cell antigen identification approaches do not discern which epitopes drive protective immunity during active infection — information that is critical for the rational design of TCD8-targeted vaccines. We employed a proteomics-based approach for large-scale discovery of naturally processed determinants derived from a complex pathogen, vaccinia virus (VACV), that are presented by the most frequent representatives of four major HLA class I supertypes. Immunologic characterization revealed that many previously unidentified VACV determinants were recognized by smallpox-vaccinated human peripheral blood cells in a variegated manner. Many such determinants were recognized by HLA class I–transgenic mouse immune TCD8 too and elicited protective TCD8 immunity against lethal intranasal VACV infection. Notably, efficient processing and stable presentation of immune determinants as well as the availability of naive TCD8 precursors were sufficient to drive a multifunctional, protective TCD8 response. Our approach uses fundamental insights into T cell epitope processing and presentation to define targets of protective TCD8 immunity within human pathogens that have complex proteomes, suggesting that this approach has general applicability in vaccine sciences.

Authors

Pavlo Gilchuk, Charles T. Spencer, Stephanie B. Conant, Timothy Hill, Jennifer J. Gray, Xinnan Niu, Mu Zheng, John J. Erickson, Kelli L. Boyd, K. Jill McAfee, Carla Oseroff, Sine R. Hadrup, Jack R. Bennink, William Hildebrand, Kathryn M. Edwards, James E. Crowe Jr., John V. Williams, Søren Buus, Alessandro Sette, Ton N.M. Schumacher, Andrew J. Link, Sebastian Joyce

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Figure 3

Individual TCD8 exhibit similar phenotype, functional competence, and homing pattern.

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Individual TCD8 exhibit similar phenotype, functional competence, and ho...
(A) Experimental design. B7tg mice were inoculated i.p. with 2 × 105 pfu VACV, and the TCD8 response was characterized on day 7. (B) Dominant (D1R808–817, B8R70–79) and subdominant (A3L192–200) TCD8 specificities identified in VACV-immune spleens acquired similar effector (CD44hiCD62LLOGzmB+KLRG1hi) and memory (CD44hiCD62LhiCD127hi) phenotypes. Representative data for 3 TCD8 specificities of 6 measured are shown. Numbers represent the percentage of p/B7.2 tetramer+ cells within TCD8 gate (top row) or the percentage of p/B7.2 tetramer+ TCD8 with indicated phenotype. (C and D) Multifunctionality of dominant and subdominant TCD8 detected in immune spleens after ex vivo restimulation with peptide. Data are representative of at least 2 independent experiments. Numbers in C represent the percentage of IFN-γ+CD107a+ cells within the TCD8 gate (top row) or the percentage of IFN-γ+CD107a+ TCD8 expressing the indicated cytokines (middle and bottom rows). Error bars in D represent mean ± SD of the assay replicates (n = 3–5). (E) Broad TCR Vβ usage within individual TCD8 specificity. Bar segments indicate the proportion of TCRβ clonotype within the indicated p/B7.2 tetramer+ TCD8 spleen cells. Note that priming with VACV proteins followed by viral challenge enhanced the 4 low-frequency TCD8. (F) Wide tissue distribution of VACV-specific TCD8. Bar segments indicate the proportion of the indicated specificity within the 10 p/B7.2 tetramer+ TCD8 measured. Data are representative of 2 independent experiments (n = 5).