Preferred size of peptides that bind to H‐2 Kb is sequence dependent

Abstract

The identification of naturally processed viral peptides reveals that major histocompatibility complex (MHC) class I epitopes are composed of nine or eight amino acid residues. Peptides eluted from H‐2 K^b MHC class I molecules have been suggested, as a class, to be eight amino acid residues long. To assay for peptide‐class I interactions, a stabilization assay described for surface labeled “empty” class I molecules was employed, but on biosynthetically labeled class I molecules. The Sendai virus nucleoprotein‐derived octapeptide APGNYPAL does not bind and stabilize K^b molecules, whereas other octameric K^b−restricted peptides and the nonameric peptide FAPGNYPAL interact stably. We attribute the failure of Sendai octamer binding to the presence of proline in position two: replacement of proline renders the resulting octamers as efficient as FAPGNYPAL for binding and stabilization of H‐2 K^b. Substitution of glycine in position three of APGNYPAL slighty improves its K^b stabilizing capacity. Iodination of the tyrosine residue significantly alters the binding properties of the nonamer peptide. We conclude that the length of epitopes as selected by the class I K^b molecule is influenced by their sequence and suggest that proper positioning of the NH₂ terminus of peptides is essential for class I stabilizing properties. The ability to stabilize newly synthesized “empty” class I molecules with peptide argues against an involvement of β₂ microglobulin exchange in the experiments described here.