A Structure-Based Algorithm to Predict Potential Binding Peptides to MHC Molecules with Hydrophobic Binding Pockets
Identifieur interne : 003E00 ( Main/Exploration ); précédent : 003D99; suivant : 003E01A Structure-Based Algorithm to Predict Potential Binding Peptides to MHC Molecules with Hydrophobic Binding Pockets
Auteurs : Yael Altuvia ; Alessandro Sette ; John Sidney ; Scott Southwood ; Hanah MargalitSource :
- Human Immunology [ 0198-8859 ] ; 1997.
English descriptors
- KwdEn :
- Teeft :
- Absolute temperature, Algorithm, Allele, Altuvia, American society, Amino, Amino acid, Amino acid sequence, Amino acids, Backbone coordinates, Binder, Binding, Binding capability, Binding energy, Binding groove, Binding motif, Binding motifs, Binding peptides, Binding pockets, Binding values, Coefficient, Contact residues, Correlation analysis, Correlation coefficients, Current algorithm, Current study, Cytotoxic, Different positions, Different templates, Elsevier science, Energy profile, Energy values, Epitope, Experimental binding data, Experimental binding values, Experimental data, Experimental efforts, Good binders, Hanah margalit, Histocompatibility, Human cytotoxic, Human immunology, Human papillomavirus type, Hydrophobic binding pockets, Hydrophobic interactions, Immunogenic, Immunogenic peptide, Immunogenic peptides, Immunol, Influenza, Interaction energy, Large ensemble, Lowest energy, Lymphocyte, Major histocompatibility, Matrix, Molecular genetics, Molecule, Other positions, Pairwise contact potentials, Peptide, Peptide binding, Peptide position, Peptide positions, Peptide residue, Peptide score, Peptide selection, Peptide sequence, Peptide sequences, Peptide vaccines, Precise prediction, Predictive algorithm, Proc natl acad, Protein crystal structures, Protein sequence, Protein sequences, Quantitative expression, Respective protein sequences, Respective sequences, Secondary anchor residues, Sequence requirements, Small number, Unknown structure, Viral peptides.
Abstract
Abstract: ABSTRACT: Binding of peptides to MHC class I molecules is a prerequisite for their recognition by cytotoxic T cells. Consequently, identification of peptides that will bind to a given MHC molecule must constitute a central part of any algorithm for prediction of T-cell antigenic peptides based on the amino acid sequence of the protein. Binding motifs, defined by anchor positions only, have proven to be insufficient to ensure binding, suggesting that other positions along the peptide sequence also affect peptide-MHC interaction. The second phase of prediction schemes therefore take into account the effect of all positions along the peptide sequence, and are based on position-dependent-coefficients that are used in the calculation of a peptide score. These coefficients can be extracted from a large ensemble of binding sequences that were tested experimentally, or derived from structural considerations, as in the algorithm developed by us recently. This algorithm uses the coordinates of solved complexes to evaluate the interactions of peptide amino acids with MHC contact residues, and results in a peptide score that reflects its binding energy. Here we present our analysis for peptide binding to four MHC alleles (HLA-A2, HLA-A68, HLA-B27 and H-2Kb), and compare the predictions of the algorithm to experimental binding data. The algorithm performs successfully in predicting peptide binding to MHC molecules with hydrophobic binding pockets but not when MHC molecules with hydrophilic, charged pockets are considered. For MHC molecules with hydrophobic pockets it is demonstrated how the algorithm succeeds in distinguishing binding from non-binding peptides, and in high ranking of immunogenic peptides within all overlapping same-length peptides spanning their respective protein sequences. The latter property of the algorithm makes it a useful tool in the rational design of peptide vaccines aimed at T-cell immunity.
Url:
DOI: 10.1016/S0198-8859(97)00210-3
Affiliations:
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ABSTRACT: Binding of peptides to MHC class I molecules is a prerequisite for their recognition by cytotoxic T cells. Consequently, identification of peptides that will bind to a given MHC molecule must constitute a central part of any algorithm for prediction of T-cell antigenic peptides based on the amino acid sequence of the protein. Binding motifs, defined by anchor positions only, have proven to be insufficient to ensure binding, suggesting that other positions along the peptide sequence also affect peptide-MHC interaction. The second phase of prediction schemes therefore take into account the effect of all positions along the peptide sequence, and are based on position-dependent-coefficients that are used in the calculation of a peptide score. These coefficients can be extracted from a large ensemble of binding sequences that were tested experimentally, or derived from structural considerations, as in the algorithm developed by us recently. This algorithm uses the coordinates of solved complexes to evaluate the interactions of peptide amino acids with MHC contact residues, and results in a peptide score that reflects its binding energy. Here we present our analysis for peptide binding to four MHC alleles (HLA-A2, HLA-A68, HLA-B27 and H-2Kb), and compare the predictions of the algorithm to experimental binding data. The algorithm performs successfully in predicting peptide binding to MHC molecules with hydrophobic binding pockets but not when MHC molecules with hydrophilic, charged pockets are considered. For MHC molecules with hydrophobic pockets it is demonstrated how the algorithm succeeds in distinguishing binding from non-binding peptides, and in high ranking of immunogenic peptides within all overlapping same-length peptides spanning their respective protein sequences. The latter property of the algorithm makes it a useful tool in the rational design of peptide vaccines aimed at T-cell immunity.</div></front></TEI><affiliations><list></list><tree><noCountry><name sortKey="Altuvia, Yael" sort="Altuvia, Yael" uniqKey="Altuvia Y" first="Yael" last="Altuvia">Yael Altuvia</name><name sortKey="Margalit, Hanah" sort="Margalit, Hanah" uniqKey="Margalit H" first="Hanah" last="Margalit">Hanah Margalit</name><name sortKey="Sette, Alessandro" sort="Sette, Alessandro" uniqKey="Sette A" first="Alessandro" last="Sette">Alessandro Sette</name><name sortKey="Sidney, John" sort="Sidney, John" uniqKey="Sidney J" first="John" last="Sidney">John Sidney</name><name sortKey="Southwood, Scott" sort="Southwood, Scott" uniqKey="Southwood S" first="Scott" last="Southwood">Scott Southwood</name></noCountry></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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