Defective T helper cell epitope responsible for the failure of region 69-84 of the human myelin basic protein to induce experimental allergic encephalomyelitis in the Lewis rat

Studies on T-cell receptors involved in experimental autoimmune encephalomyelitis using the complementary peptide recognition approach

Based upon Blalock's complementary recognition approach, a complementary or antisense peptide (CP) was designed to the experimental autoimmune encephalomyelitis (EAE) epitope peptide, rat myelin basic protein (MBP) peptide 72-82. This peptide (EAE CP) was shown to have some sequence similarities to T-cell receptors (TCR) and MHC II molecules in a sequence homology search. Solid-phase binding assays demonstrated specific and high affinity binding (3 and 4 microM) between the EAE CP and the rat and guinea pig EAE epitope peptides (Rt72-82 and Gp69-82), respectively. This EAE CP was also found to be immunogenic in rats in an ear swelling test for delayed type hypersensitivity (DTH) reactions and an ELISA for antibody responses. However, a rabbit antibody generated to EAE CP was shown to be unable to stain the V beta 8+ EAE susceptible T-cells in immunofluorescence analyses. This EAE CP was also used in attempts to down-regulate EAE and the results showed that prior immunization with EAE CP in complete Freund's adjuvant could not prevent the Lewis rats from developing EAE. Although the data on sense-antisense peptide interaction were positive and the EAE CP was immunogenic, the inability of EAE CP to regulate EAE indicates that the CP approach may not be generally applicable.

Immunity to T cell receptor peptides: theory and applications

In this review, we describe an anti-idiotypic regulatory mechanism that is naturally induced by the autoimmune disease process, and that can be boosted by injection of TCR peptides that mimic epitopes generated naturally from germline sequences. The striking similarities in the induction and characteristics of rodent and human T cells specific for TCR peptides support the generality of the observation, and enhance the probability that this immunoregulatory mechanism will have application in human organ-specific autoimmune diseases that are characterized by oligoclonal expression of TCR V genes. The major challenges that remain to be resolved to make the TCR peptide therapy more widely applicable include (1) establishing disease-relevant V gene biases in individual patients, (2) identifying biologically active TCR peptide sequences, and (3) demonstrating that the induction of anti-TCR peptide immunity in humans can reduce the pernicious activity of autoreactive T cells putatively directed at organ-specific target antigens.