Human T cells recognize HLA-DP–bound peptides in two orientations

Abstract: Human leukocyte antigen (HLA) molecules present small peptide antigens to T cells, thereby allowing them to recognize pathogen-infected and cancer cells. A central dogma over the last 50+ y is that peptide binding to HLA molecules is mediated by the docking of side chains of particular amino acids in the peptide into pockets in the HLA molecules in a conserved N- to C-terminal orientation. Whether peptides can be presented in a reversed C- to N-terminal orientation remains unclear. Here, we performed large-sca… Show more

“…This suggests that the HLA-DP α chain, although bearing a limited specificity-determining role (see later), is the major determinant for the acceptance of the inverted peptide binding mode. These observations are in alignment with recent studies ( 28 , 33 ), which have shown that widespread inversion of peptide binders is only observed for DP and only for DP molecules with certain α chains (namely, DPA1*02:01 and DPA1*02:02). Although molecules with DPB1*03:01 have not been observed in previous studies to have inverted binders ( 32 ), our method predicts a sizable percentage (~8.1%, 83 of 1029 peptides) of inversions for DPA1*02:01-DPB1*03:01.…”

“…On the basis of this, they hypothesized that for this molecule, peptides can bind both in a canonical (N- to C-terminal) and inverted (C- to N-terminal) orientation. This inverted binding mode was later confirmed experimentally in independent studies ( 28 , 33 ). In the context of T cell epitope prediction, Racle et al.…”

“…On the basis of this, they hypothesized that for this molecule, peptides can bind both in a canonical (N-to C-terminal) and inverted (C-to N-terminal) orientation. This inverted binding mode was later confirmed experimentally in independent studies (28,33). In the context of T cell epitope prediction, Racle et al (28) showed in a recent publication that by incorporating inverted binding prediction into their MixMHC2pred method, they were able to identify several epitopes bound inverted to DPA1*02:01-DPB1*01:01, which elicited a CD4 + immune response.…”

“…Before model training, the MS data were processed and enriched with artificial random natural negative peptides (as described in Materials and Methods). To accommodate the inverted binding mode recently observed for some DP molecules ( 28 , 33 ), we used a modified version of the NNAlign_MA machine learning framework (see fig. S1), which includes an option to simultaneously predict both the binding core offset and the orientation (forward or inverted) of the peptide ligands (for details on the implementation, refer to Materials and Methods).…”

Accurate prediction of HLA class II antigen presentation across all loci using tailored data acquisition and refined machine learning

“…This suggests that the HLA-DP α chain, although bearing a limited specificity-determining role (see later), is the major determinant for the acceptance of the inverted peptide binding mode. These observations are in alignment with recent studies ( 28 , 33 ), which have shown that widespread inversion of peptide binders is only observed for DP and only for DP molecules with certain α chains (namely, DPA1*02:01 and DPA1*02:02). Although molecules with DPB1*03:01 have not been observed in previous studies to have inverted binders ( 32 ), our method predicts a sizable percentage (~8.1%, 83 of 1029 peptides) of inversions for DPA1*02:01-DPB1*03:01.…”

“…On the basis of this, they hypothesized that for this molecule, peptides can bind both in a canonical (N- to C-terminal) and inverted (C- to N-terminal) orientation. This inverted binding mode was later confirmed experimentally in independent studies ( 28 , 33 ). In the context of T cell epitope prediction, Racle et al.…”

“…On the basis of this, they hypothesized that for this molecule, peptides can bind both in a canonical (N-to C-terminal) and inverted (C-to N-terminal) orientation. This inverted binding mode was later confirmed experimentally in independent studies (28,33). In the context of T cell epitope prediction, Racle et al (28) showed in a recent publication that by incorporating inverted binding prediction into their MixMHC2pred method, they were able to identify several epitopes bound inverted to DPA1*02:01-DPB1*01:01, which elicited a CD4 + immune response.…”

“…Before model training, the MS data were processed and enriched with artificial random natural negative peptides (as described in Materials and Methods). To accommodate the inverted binding mode recently observed for some DP molecules ( 28 , 33 ), we used a modified version of the NNAlign_MA machine learning framework (see fig. S1), which includes an option to simultaneously predict both the binding core offset and the orientation (forward or inverted) of the peptide ligands (for details on the implementation, refer to Materials and Methods).…”

Accurate prediction of HLA class II antigen presentation across all loci using tailored data acquisition and refined machine learning

“…For allogenic hematopoietic cell therapy (HCT), the HLA-DP locus is of particular interest given the frequent incompatibility of patients and donors 30 , the allotype dependency of peptide presentation and recognition by alloreactive CD4+ T cells [31][32][33] , and the relevance for chronic virus infections as indicated by the strong association of HLA-DPB1 SNPs with chronic hepatitis B virus (HBV) infections (see e.g., 34 ). CD4+ T cells recognizing HLA-DP-restricted peptides have also been described for HCMV [35][36][37][38][39] , but to our knowledge, viral countermeasures have not yet been described.…”

The human cytomegalovirus-encoded pUS28 antagonizes CD4+ T-cell recognition by targeting CIITA

Structural definition of HLA class II-presented SARS-CoV-2 epitopes reveals a mechanism to escape pre-existing CD4+ T cell immunity