Human CD4+ T Cell Epitopes from Vaccinia Virus Induced by Vaccination or Infection

J Mauricio Calvo-Calle,Lawrence J Stern,Iwona Strug,Maria-Dorothea Nastke,Stephen P Baker,Mark L Buller

doi:10.1371/journal.ppat.0030144

J Mauricio Calvo-Calle, Lawrence J Stern + Show 4 more

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https://doi.org/10.1371/journal.ppat.0030144

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Journal: PLoS Pathogens	Publication Date: Oct 1, 2007
Citations: 125	License type: CC BY 4.0

Affiliation: University of Massachusetts Chan Medical School

Abstract

Despite the importance of vaccinia virus in basic and applied immunology, our knowledge of the human immune response directed against this virus is very limited. CD4+ T cell responses are an important component of immunity induced by current vaccinia-based vaccines, and likely will be required for new subunit vaccine approaches, but to date vaccinia-specific CD4+ T cell responses have been poorly characterized, and CD4+ T cell epitopes have been reported only recently. Classical approaches used to identify T cell epitopes are not practical for large genomes like vaccinia. We developed and validated a highly efficient computational approach that combines prediction of class II MHC-peptide binding activity with prediction of antigen processing and presentation. Using this approach and screening only 36 peptides, we identified 25 epitopes recognized by T cells from vaccinia-immune individuals. Although the predictions were made for HLA-DR1, eight of the peptides were recognized by donors of multiple haplotypes. T cell responses were observed in samples of peripheral blood obtained many years after primary vaccination, and were amplified after booster immunization. Peptides recognized by multiple donors are highly conserved across the poxvirus family, including variola, the causative agent of smallpox, and may be useful in development of a new generation of smallpox vaccines and in the analysis of the immune response elicited to vaccinia virus. Moreover, the epitope identification approach developed here should find application to other large-genome pathogens.

Highlights

Immunization with vaccinia virus elicits long-lasting cellular and humoral immune responses in humans and in animal models
Since protective antibody responses to poxvirus could be elicited by immunization with single or multiple proteins in mice and in primate models [9,10,11,12], or by transfer of monoclonal or polyclonal antibodies to defined protein components [10,13,14], development of subunit vaccines would appear to be feasible and will require the characterization of CD4þ T cell epitopes capable of generating long-lasting antibody responses
We develop a new computational approach for prediction of T cell epitopes, validate it using epitopes already identified by classical methods, and apply it to the prediction of vaccinia epitopes

Summary

Introduction

Immunization with vaccinia virus elicits long-lasting cellular and humoral immune responses in humans and in animal models (reviewed in [1]). Since protective antibody responses to poxvirus could be elicited by immunization with single or multiple proteins in mice and in primate models [9,10,11,12], or by transfer of monoclonal or polyclonal antibodies to defined protein components [10,13,14], development of subunit vaccines would appear to be feasible and will require the characterization of CD4þ T cell epitopes capable of generating long-lasting antibody responses. Moutaftsi et al screened 2,146 peptides and identified 14 epitopes restricted by the MHC molecule I-Ab. The two largescale screenings, by Jing et al in humans and by Moutaftsi et al in mice, suggest that the CD4þ T cell response to vaccinia

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