Endogenous presentation of a nascent antigenic epitope to CD8+ CTL is more efficient than exogenous presentation

Abstract

Cytotoxic T lymphocytes (CTL) recognize short antigenic peptides in association with class I MHC molecules at the cell surface. Newly synthesized viral polypeptides are processed in the cytoplasm and the fragments of antigen are transported into the endoplasmic reticulum (ER) via a peptide transporter where they complex with nascent class I molecules. The peptide-MHC complex is transported to the cell surface and presented to CTL. Sequence analysis of endogenously expressed, MHC-associated self or viral antigens indicates that the naturally processed peptides bound to class I MHC molecules are in general 9 1 residues long. Peptides bound to specific class I MHC molecules have in common allele-specific motifs of conserved residues. The motif for the class I K^d molecules has been shown to be nine or 10 residues with the sequence X-Tyr-(X)6-I/L or X-Tyr-(X)7-I/L. The Tyr residue at the second position and the I/L residue at the ninth position are allele-specific anchor residues which appear to be required for binding of the peptide to K^d. To examine the stringency of the requirement for Tyr at the second position, we have performed saturation mutagenesis of a minigene encoding the class I K^d-restricted influenza HA210-219 site at the Tyr residue 211. A series of 10 mutants was tested for effects on target-cell sensitization. Most amino acid substitutions for the Tyr residue resulted in a loss of endogenous peptide recognition by HA210-219 reactive CTL, consistent with the critical role of the Tyr at the second position for interaction with K^d molecules. One mutant gene-product encoding a His substitution for the Tyr residue was recognized by CTL. However, the corresponding synthetic peptide containing a His substitution at the dominant anchor position bound only weakly to K^d, and target cells treated with the peptide were poorly recognized by CTL. The endogenous His-containing peptide was also less stably associated with class I MHC K^d molecules at the cell surface than the wild-type Tyr peptide. These data indicate that endogenous antigenic peptides may bind newly-synthesized class I MHC molecules in the ER more efficiently than fully formed class I molecules at the cell surface and that endogenous peptides may dissociate from class I MHC molecules at different rates. The implications of these findings for CTL recognition and epitope mapping are discussed.