Structure of the complex between human T-cell receptor, viral peptide and HLA-A2

Not just another Fab: the crystal structure of a TcR-MHC-peptide complex

The structure of a ternary complex formed between a T-cell receptor, a major histocompatibility complex (MHC) protein and a viral peptide provides new insights into the cellular immune response. The results provide a molecular basis for understanding the development of T cells and the reactions leading to transplant rejection and autoimmunity.

Biophysical and structural studies of TCRs and ligands: implications for T cell signaling

The availability of soluble alphabeta TCRs and the individual chains has now made it possible to carry out structural studies of these molecules and analyze their molecular interactions with peptide-MHC ligands. Recent X-ray crystallographic structures of TCR alpha and beta chains have finally established their structural similarity with the lg molecules. Kinetic measurements of the interaction between TCRs and their ligands have provided strong evidence in favour of an affinity/avidity model for T cell activation in the periphery as well as during development in the thymus.

Fine mapping of T-cell determinants of bovine beta-lactoglobulin

T-cell recognition sites, i.e. T-cell determinants, of bovine beta-lactoglobulin, a major allergen in milk, were analyzed in detail. For this purpose, we prepared primary cultures of lymph node cells from three strains of mice, C57BL/6 (H-2b), C3H/HeN (H-2k), and BALB/c (H-2d), and examined the proliferative response of these cells to a complete set of overlapping 15-mer peptides which covered the entire sequence of beta-lactoglobulin by shifting in single amino acid steps. We were able to determine the putative core sequence of each T-cell determinant and estimate its relative importance. In the case of C57BL/6 mice, dominant, subdominant, and minor determinants were identified as residues 122-130, 16-26, and 108-122, respectively, as represented by their core sequences. Each determinant peptide induced the production of interferon-gamma, the amount of which showed a correlation with the intensity of the proliferative response induced by each determinant. In the case of C3H/HeN mice, a dominant determinant comprised of residues 140-148 was identified together with three subdominant and two minor determinants. Dominant T-cell determinants recognized in BALB/c mice were identified as residues 67-75, 71-79, and 80-88, and six other regions were identified as subdominant determinants. Comparisons between our results and the determinants predicted from relevant MHC-binding motifs reported to date revealed the inadequacy of the motifs in predicting even the dominant determinants. The information obtained by complete mapping of T-cell determinants as done in this study is expected to be helpful in establishment and evaluation of new prediction methods and also may contribute to the development of a new approach to control immune responses by manipulation of the T-cell determinants of allergens.

T-cell receptors: feeling out the complex

Recent crystallographic studies show that the T-cell receptor has a largely immunoglobulin-like structure and binds to MHC-peptide complexes through loops from paired Valpha and Vbeta domains that focus on the central amino acids of the MHC-bound peptide, and to bacterial superantigens via peripheral aspects of the Vbeta domain.

Conformational changes in MHC class I molecules. Antibody, T-cell receptor, and NK cell recognition in an HLA-B7 model system

In this article we review the role of MHC conformation, including peptide-induced MHC conformation, in forming antibody (Ab), T-cell receptor (TCR), and natural killer (NK) cell receptor epitopes. Abs recognize conformational major histocompatibility (MHC) epitopes that often are influenced by the identity of MHC-bound peptide. Diverse TCRs recognize a common docking site on peptide/MHC complexes and directly contact peptide. Human NK cell inhibitory receptors (KIR) appear to recognize limited regions of the HLA alpha (1) helix. DX9+ KIR specifically focus on HLA-B residues 82 and 83. However, NK cells recognize much broader regions of HLA class I molecules and are sensitive to bound peptides. Thus, several classes of lymphocyte receptors are peptide-specific. Peptide specificity could be the result of direct contact with the receptor, or to conformational shifts in MHC residues that interact with both receptor and bound peptide.