An Elite Controller of Picornavirus Infection Targets an Epitope That Is Resistant to Immune Escape

Michael P Bell,Aaron J Johnson,Kevin D Pavelko,Danielle N Renner,Ralph Tripp

doi:10.1371/journal.pone.0094332

Michael P Bell, Aaron J Johnson + Show 3 more

Open Access

https://doi.org/10.1371/journal.pone.0094332

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Journal: PLoS ONE	Publication Date: Apr 7, 2014
Citations: 47	License type: CC BY 4.0

Affiliation: Mayo Clinic, Winneshiek Medical Center

Abstract

The emergence of novel viral pathogens can lead to devastating consequences in the infected population. However, on occasion, rare hyper-responsive elite controllers are able to mount a protective primary response to infection and clear the new pathogen. Factors distinguishing elite controllers from other members of the population are not completely understood. We have been using Theiler's murine encephalomyelitis as a model of primary infection in mice and clearance of the virus is limited to one MHC genotype capable of generating a protective response to a single viral peptide VP2121-130. The genetics of host susceptibility to TMEV, a natural mouse pathogen, has been studied extensively and non-protective CD8 responses to other peptides have been documented, however, little is known why the protective response to infection focuses on the VP2121-130 peptide. To study this question, we have generated TMEV mutants that encode for mutations within the VP2121-130 peptide. We find that very few of mutants are able to assemble and infect in vitro. These mutations are not related to virus RNA structure since non-coding mutations do not interfere with assembly. In the rare event when functional VP2121-130 mutant viruses did emerge, they were attenuated to some level or retained the ability to develop an immune response to the wild-type VP2121-130 sequence, demonstrating that the virus is incapable of escaping the protective response. These findings advance our understanding of how characteristics of the host immune response and an infectious agent can interact to lead to the appearance of rare super controllers in a population. Furthermore, the immutable nature of the viral antigen highlights the importance of choosing appropriate vaccine antigens and has implications for the development of agents that are able to generate protective CD8 T-cell responses.

Highlights

Interaction with pathogens has been proposed to be the main driver of human immunity as well as the evolution of infectious diseases and the agents that cause them [1,2,3]
Development of Theiler’s murine encephalomyelitis virus (TMEV) VP2121-130 mutants To identify mutations that can be introduced into the immunodominant TMEV sequence FHAGSLLVFM at positions 121-130 of viral protein 2 (VP2), we used homology mapping to identify similar linear and conformational epitopes derived from related viruses
Our search identified 51 known homologous structures from several picornavirus species including two strains of TMEV and of Mengo virus, which were identical at VP2121-130

Summary

Introduction

Interaction with pathogens has been proposed to be the main driver of human immunity as well as the evolution of infectious diseases and the agents that cause them [1,2,3]. Infection with disease causing pathogens has been important for shaping the genetics of human populations and the most prominent element is the diversity of major histocompatibility genes and their role in recognizing emerging infectious diseases. We have been examining the underlying basis of super resistance in a mouse model of picornavirus infection [7]. These elite controllers represent a unique population that is able to recognize and eliminate an emerging pathogen while allowing survivors to pass on genes necessary for disease resistance

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