Quantitative Prediction of Peptide Binding to HLA-DP1 Protein

Author

Ivanov, Sergiu ; Dimitrov, Ivan ; Doytchinova, Irini

Author_Institution

Sch. of Pharmacy, Med. Univ. of Sofia, Sofia, Bulgaria

Volume

10

Issue

3

fYear

2013

fDate

May-June 2013

Firstpage

811

Lastpage

815

Abstract

The exogenous proteins are processed by the host antigen-processing cells. Peptidic fragments of them are presented on the cell surface bound to the major hystocompatibility complex (MHC) molecules class II and recognized by the CD4+ T lymphocytes. The MHC binding is considered as the crucial prerequisite for T-cell recognition. Only peptides able to form stable complexes with the MHC proteins are recognized by the T-cells. These peptides are known as T-cell epitopes. All T-cell epitopes are MHC binders, but not all MHC binders are T-cell epitopes. The T-cell epitope prediction is one of the main priorities of immunoinformatics. In the present study, three chemometric techniques are combined to derive a model for in silico prediction of peptide binding to the human MHC class II protein HLA-DP1. The structures of a set of known peptide binders are described by amino acid z-descriptors. Data are processed by an iterative self-consisted algorithm using the method of partial least squares, and a quantitative matrix (QM) for peptide binding prediction to HLA-DP1 is derived. The QM is validated by two sets of proteins and showed an average accuracy of 86 percent.

Keywords

bonds (chemical); cellular biophysics; least squares approximations; molecular biophysics; proteins; CD4+ T lymphocytes; HLA-DP1 protein; MHC binders; MHC binding; MHC molecules class II; MHC proteins; T-cell epitopes; T-cell recognition; amino acid z-descriptors; cell surface; chemometric techniques; exogenous proteins; host antigen-processing cells; immunoinformatics; in silico prediction; iterative self-consisted algorithm; major hystocompatibility complex; partial least squares; peptide binding prediction; peptidic fragments; quantitative matrix; quantitative prediction; stable complexes; Amino acids; Diseases; Immune system; Peptides; Predictive models; Proteins; Training; Amino acids; CD4+ T lymphocytes; Diseases; HLA-DP1 protein; Immune system; MHC binders; MHC binding; MHC binding prediction; MHC molecules class II; MHC proteins; Peptides; Predictive models; Proteins; T-cell epitopes; T-cell recognition; Training; amino acid z-descriptors; bonds (chemical); cell surface; cellular biophysics; chemometric techniques; exogenous proteins; host antigen-processing cells; immunoinformatics; in silico prediction; iterative self-consisted algorithm; iterative self-consistent algorithm; least squares approximations; major hystocompatibility complex; molecular biophysics; partial least squares; partial least squares method; peptide binding prediction; peptidic fragments; proteins; quantitative matrix; quantitative prediction; stable complexes; z-descriptors;

fLanguage

English

Journal_Title

Computational Biology and Bioinformatics, IEEE/ACM Transactions on

Publisher

ieee

ISSN

1545-5963

Type

jour

DOI

10.1109/TCBB.2013.78

Filename

6552823