Abstract
The identification of MHC class II restricted peptide epitopes is an important goal in immunological research. A number of computational tools have been developed for this purpose, but there is a lack of large-scale systematic evaluation of their performance. Herein, we used a comprehensive dataset consisting of more than 10,000 previously unpublished MHC-peptide binding affinities, 29 peptide/MHC crystal structures, and 664 peptides experimentally tested for CD4+ T cell responses to systematically evaluate the performances of publicly available MHC class II binding prediction tools. While in selected instances the best tools were associated with AUC values up to 0.86, in general, class II predictions did not perform as well as historically noted for class I predictions. It appears that the ability of MHC class II molecules to bind variable length peptides, which requires the correct assignment of peptide binding cores, is a critical factor limiting the performance of existing prediction tools. To improve performance, we implemented a consensus prediction approach that combines methods with top performances. We show that this consensus approach achieved best overall performance. Finally, we make the large datasets used publicly available as a benchmark to facilitate further development of MHC class II binding peptide prediction methods.
Highlights
The activation of CD4+ helper T cells is essential for the development of adaptive immunity against pathogens [1,2,3,4]
A critical step in developing immune response against pathogens is the recognition of antigenic peptides presented by MHC class II molecules
We carried out a large-scale systematic evaluation of existing prediction tools with the aim of establishing a benchmark for performance comparison and to identify directions that can further improve prediction performance
Summary
The activation of CD4+ helper T cells is essential for the development of adaptive immunity against pathogens [1,2,3,4]. A critical step in CD4+ T cell activation is the recognition of epitopes presented by MHC class II molecules [5]. MHC class II molecules are heterodimers expressed on the surface of professional antigen presenting cells that bind peptide fragments derived from protein antigens [6]. X-ray crystallographic studies demonstrated that the MHC class II epitope binding site consists of a groove and several pockets provided by a b-sheet and two a-helices [7,8]. Unlike class I, the class II binding groove is open at both ends. Peptides binding to class II molecules tend to be of variable length, but typically between 13 and 25 residues
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