Abstract
BackgroundExperimental screening of large sets of peptides with respect to their MHC binding capabilities is still very demanding due to the large number of possible peptide sequences and the extensive polymorphism of the MHC proteins. Therefore, there is significant interest in the development of computational methods for predicting the binding capability of peptides to MHC molecules, as a first step towards selecting peptides for actual screening.ResultsWe have examined the performance of four diverse MHC Class I prediction methods on comparatively large HLA-A and HLA-B allele peptide binding datasets extracted from the Immune Epitope Database and Analysis resource (IEDB). The chosen methods span a representative cross-section of available methodology for MHC binding predictions. Until the development of IEDB, such an analysis was not possible, as the available peptide sequence datasets were small and spread out over many separate efforts. We tested three datasets which differ in the IC50 cutoff criteria used to select the binders and non-binders. The best performance was achieved when predictions were performed on the dataset consisting only of strong binders (IC50 less than 10 nM) and clear non-binders (IC50 greater than 10,000 nM). In addition, robustness of the predictions was only achieved for alleles that were represented with a sufficiently large (greater than 200), balanced set of binders and non-binders.ConclusionsAll four methods show good to excellent performance on the comprehensive datasets, with the artificial neural networks based method outperforming the other methods. However, all methods show pronounced difficulties in correctly categorizing intermediate binders.
Highlights
Experimental screening of large sets of peptides with respect to their major histocompatibility complex (MHC) binding capabilities is still very demanding due to the large number of possible peptide sequences and the extensive polymorphism of the MHC proteins
This method allows for the fast prediction of MHC class I binders, and for the efficient construction of docked peptide conformations. This approach is the only prediction method available today, which allows for the construction of such conformations. We have evaluated this approach for MHC class I alleles of the human leukocyte antigen (HLA) genes A and B for which extensive datasets were available in Immune Epitope Database and Analysis resource (IEDB) and compared it to two sequence-based prediction methods from the literature
This probably is due to the lower number of epitopes which are available for HLA-B in IEDB and, in the case of DynaPredPOS, due to the fact that the BFESM was generated using HLA-A*0201 simulation results
Summary
Experimental screening of large sets of peptides with respect to their MHC binding capabilities is still very demanding due to the large number of possible peptide sequences and the extensive polymorphism of the MHC proteins. As part of the adaptive immune response, antigens are recognized by two different types of receptor molecules: immunoglobulins which act as antigen receptors on B cells and antigen-specific T-cell receptors (TCRs) [1,2]. The latter receptor molecules recognize antigens which are displayed on the surface of cells. The binding of antigenic peptides from pathogens to MHC class I molecules is one of the crucial steps in the immunological response against an infectious pathogen [2]. Deciphering why certain peptides become epitopes and others do not is central to the development of a precise understanding of host immune responses
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