Abstract
Activation of a T cell in response to peptide bound to class I MHC occurs by the sum of interactions across the area of contact between the TCR, the peptide, and class I MHC. It has been observed recently that substitution of the peptide residue at a position that is not accessible from the exterior of the class I molecule modulates T cell responses, raising the possibility that there may be indirect structural effects in the peptide-class I complex as a consequence of peptide binding. This report describes the use of mAbs to probe the conformation of the alpha 1 and alpha 2 domains of the mouse class I molecule Kb when bound to ovalbumin peptide and a panel of 19 peptide analogues that differ at position 2 (P2). By crystallographic data, side chains of this position are buried in the Ag binding cleft and have no direct access to the TCR. Substitution of position 2 results in a measurable change in conformation of the class I molecule, a change that correlates with the ability to stimulate T cells. This leads to a model that T cell activation by the peptide-class I complex may occur in three ways: 1) direct interaction of the TCR with the class I heavy chain, 2) direct interaction of the TCR with solvent-accessible peptide side chains, and 3) indirect interaction of peptide with TCR mediated via conformational perturbations in the class I complex.
