Limited plasticity in T cell recognition of modified T cell receptor contact residues in MHC class II bound peptides.

The balance between specific and degenerate T cell recognition of MHC class II bound peptides is crucial for T cell repertoire selection, and holds important implications for protective immunity versus autoimmunity. To investigate the degree of degeneracy in T cell recognition, we applied selected modifications to T cell receptor (TCR) contact residue amino acids in the MHC class II bound epitope gpMBP72-85. By using glycosylated amino acids, as an example of a posttranslational modification, large alterations were applied. Small modifications were accomplished by exchanging an arginine residue for a citrulline or an ornithine residue. Finally, the unmodified TCR contact residue side chains were shifted one atom position to the left, using peptoid residues. Both these large and subtle changes in the wild type (WT) peptide caused lack of recognition by WT peptide specific monoclonal and polyclonal T cells. Furthermore, T cells specific for the modified peptides did not cross recognize the WT peptide. Using a set of additional compounds, we investigated the specificity of these T cell populations into detail. Our data reveal a strongly limited plasticity in T cell recognition, and a high specificity for TCR contact residue side chains.

Possibilities and limitations in the rational design of modified peptides for T cell mediated immunotherapy.

Therapeutic intervention in experimental autoimmune diseases by modulation of the T cell mediated autoimmune response has been accomplished in the past using altered peptide ligands (APLs). These peptides are usually created by applying alterations to the T cell epitope recognized by the autoaggressive T cells. In this study, we investigated whether it was possible to design APLs in a rational way, using knowledge of molecular interaction in the MHC-peptide-T cell receptor (TCR) complex, for the therapeutic intervention in experimental autoimmune encephalomyelitis (EAE). Additionally, the value of peptidomimetic modification and alterations based on posttranslational modifications for the design of APLs was examined. Based on a molecular model of the MHC-peptide complex, the T cell receptor contact residues were identified and selected alterations were applied. The designed APLs were tested for MHC binding capacity, T cell recognition, blocking of the autoreactive T cell response, immunogenicity, encephalitogenicity, and therapeutic activity. Based on the results of the in vitro assays, it was expected that some of our APLs would be able to modulate EAE. Nevertheless, none of these APLs displayed clear therapeutic activity in vivo. Thus, rational design of modified peptides for immunotherapy has to await further insights into the relationships between structure and peptide/peptidomimetic induced T cell activation, and until that, there is no possibility to take advantage of the tailor made origin of peptidomimetics.

Stabilization of peptide guinea pig myelin basic protein 72-85 by N-terminal acetylation-implications for immunological studies.

Peptide gpMBP72-85, containing amino acids 72-85 of guinea pig myelin basic protein is commonly used to induce experimental autoimmune encephalomyelitis in Lewis rats. The N-terminal glutamine in this peptide can cyclize to pyroglutamic acid, leading to loss of the first MHC anchor for binding to MHC class II. Acetylation of the peptide N-terminus prevents pyroglutamic acid formation and ensures a constant quality. An increased MHC binding affinity after N-terminal acetylation was observed. This modification also enhanced T cell proliferation of a gpMBP reactive T cell clone. The encephalitogenicity of peptide gpMBP72-85 was unaffected by acetylation. It is concluded that acetylation improves the chemical stability of gpMBP72-85, and is not detrimental but rather favorable for its biochemical and immunological, in vitro, and in vivo behavior.

Major histocompatibility complex class II binding characteristics of peptoid-peptide hybrids.

The major histocompatibility complex (MHC) class II binding requirements for solvent-exposed peptide residues were systematically studied using amino acid and peptoid substitutions. In a peptoid residue, the side chain is present on the backbone nitrogen atom as opposed to the alpha-carbon atom in an amino acid residue. To investigate the effect of this side chain shifting on MHC binding, three amino acids in the central part of the peptide sticking out of the binding groove were replaced by corresponding peptoid residues. Two peptoid-peptide hybrids showed large affinity decreases in the MHC-peptide binding assay. To investigate this affinity loss, the individual contributions to MHC binding affinity of the side chain (position), the putative hydrogen bond, and the flexibility were dissected. We conclude that the side chain position as well as the backbone nitrogen atom hydrogen bonding features of solvent-exposed residues in the peptide can be important for MHC binding affinity.