Divergent motifs but overlapping binding repertoires of six HLA-DQ molecules frequently expressed in the worldwide human population.

Knowledge of the binding repertoires and specificities of HLA-DQ molecules is somewhat limited and contradictory, partly because of the scarcity of reports addressing some of the most common molecules and possibly because of the diversity of the techniques used. In this paper, we report the development of high-throughput binding assays for the six most common DQ molecules in the general worldwide population. Using comprehensive panels of single substitution analogs of specific ligands, we derived detailed binding motifs for DQA1*0501/DQB1*0301, DQA1*0401/DQB1*0402, and DQA1*0101/DQB1*0501 and more detailed motifs for DQA1*0501/DQB1*0201, DQA1*0301/DQB1*0302, and DQA1*0102/DQB1*0602, previously characterized on the basis of sets of eluted ligands and/or limited sets of substituted peptides.

Five HLA-DP molecules frequently expressed in the worldwide human population share a common HLA supertypic binding specificity.

Compared with DR and DQ, knowledge of the binding repertoires and specificities of HLA-DP alleles is somewhat limited. However, a growing body of literature has indicated the importance of DP-restricted responses in the context of cancer, allergy, and infectious disease. In the current study, we developed high-throughput binding assays for the five most common HLA-DPB1 alleles in the general worldwide population.

Quantitative peptide binding motifs for 19 human and mouse MHC class I molecules derived using positional scanning combinatorial peptide libraries.

Background: It has been previously shown that combinatorial peptide libraries are a useful tool to characterize the binding specificity of class I MHC molecules. Compared to other methodologies, such as pool sequencing or measuring the affinities of individual peptides, utilizing positional scanning combinatorial libraries provides a baseline characterization of MHC molecular specificity that is cost effective, quantitative and unbiased.

Results: Here, we present a large-scale application of this technology to 19 different human and mouse class I alleles.

Characterization of the peptide-binding specificity of the chimpanzee class I alleles A 0301 and A 0401 using a combinatorial peptide library.

Chimpanzees represent important models for studying several human pathogens. In the present study, we utilized a combinatorial peptide library to characterize the binding specificities of the chimpanzee class I molecules Patr A 0301 and A 0401, both of which are present in about 17% of chimpanzees. Patr A 0301 was found to recognize peptides using the canonical position 2/C-terminus spacing, with the small residues S, T, and A being the most preferred in position 2, and the positively charged residues R and K preferred at the C terminus.