Low 2-dimensional CD4 T cell receptor affinity for myelin sets in motion delayed response kinetics.

T cells recognizing self-peptides that mediate autoimmune disease and those that are responsible for efficacious immunity against pathogens may differ in affinity for antigen due to central and peripheral tolerance mechanisms. Here we utilize prototypical self-reactive (myelin) and viral-specific (LCMV) T cells from T cell receptor (TCR) transgenic mice (2D2 and SMARTA, respectively) to explore affinity differences. The T cells responsive to virus possessed >10,000 fold higher 2D affinity as compared to the self-reactive T cells. Despite their dramatically lower affinity for their cognate ligand, 2D2 T cells respond with complete, albeit delayed, activation (proliferation and cytokine production). SMARTA activation occurs rapidly, achieving peak phosphorylation of p38 (1 minute), Erk (30 minutes), and Jun (3 hours) as well as CD69 and CD25 upregulation (3 and 6 hours, respectively), with a corresponding early initiation of proliferation. 2D2 stimulation with MOG results in altered signaling--no phospho-Erk or phospho-p38 accumulation, significantly delayed activation kinetics of Jun (12 hours), and delayed but sustained SHP-1 activity--as well as delayed CD69 and CD25 expression (12-24 hours), and slow initiation of proliferation. This delay was not intrinsic to the 2D2 T cells, as a more potent antigen with >100-fold increased 2D affinity restored rapid response kinetics in line with those identified for the viral antigen. Taken together, these data demonstrate that time can offset low TCR affinity to attain full activation and suggest a mechanism by which low affinity T cells participate in autoimmune disease.

MHC variant peptide-mediated anergy of encephalitogenic T cells requires SHP-1.

Our lab has demonstrated that encephalitogenic T cells can be effectively anergized by treatment with MHC variant peptides, which are analogues of immunogenic peptides containing an amino acid substitution at an MHC anchor residue. The MHC variant peptide of myelin oligodendrocyte glycoprotein (MOG)(35-55) proves an effective treatment as it does not induce symptoms of experimental autoimmune encephalomyelitis and fails to recruit macrophages or MOG(35-55)-specific T cells to the CNS. In this study, we sought to characterize the signaling pathways required for the induction of anergy by building upon the observations identifying the tyrosine phosphatase SHP-1 as a critical regulator of T cell responsiveness. Motheaten viable heterozygous mice, which contain a mutation in the SHP-1 gene resulting in a reduction in functional SHP-1, were challenged with MOG(35-55) or the MOG(35-55) MHC variant 45D. These mice display symptoms of experimental autoimmune encephalomyelitis upon immunization with MHC variant peptide and have significant CNS infiltration of tetramer-positive CD4(+) cells and macrophages, unlike B6 mice challenged with the variant peptide. The effects of SHP-1 are directly on the T cell as Motheaten viable heterozygous mice autoreactive T cells are not anergized in vitro. Lastly, we demonstrate no distinguishable difference in the initial interaction between the TCR and agonist or MHC variant. Rather, an unstable interaction between peptide and MHC attenuates the T cell response, seen in a decreased half-life relative to MOG(35-55). These results identify SHP-1 as a mediator of T cell anergy induced by destabilized peptide:MHC complexes.

Induction of anergy by antibody blockade of TCR in myelin oligodendrocyte glycoprotein-specific cells.

Previous studies have found that a 95% reduction in TCR expression does not adversely affect response to foreign Ags, indicating that T cells have an excess of TCR for Ag recognition. Because self-reactive T cells may have low affinity for peptide:MHC, we investigated whether myelin-reactive T cells require these excess TCR for optimal response. To test this concept, mAb were used to effectively reduce the TCR of Valpha3.2 and Vbeta11 TCR transgenic mice (referred to as 2D2). After masking the TCR with either continuous or prepulsed anti-Valpha3.2 Ab, 2D2 cells were immediately stimulated with myelin oligodendrocyte glycoprotein (MOG)(35-55). These cells have a dramatic Ab dose-dependent reduction in proliferation, with a small reduction in TCR expression leading to a 50% reduction in proliferation in vitro. Additionally, 2D2 cells, treated with anti-Valpha3.2 Ab and peptide for 7 days, were re-stimulated with MOG and continue to have a dose-dependent reduction in proliferation. TCR quantitation identified the same amount of TCR on the Ab/peptide treatment compared with the peptide-only control. These results point out that the combination of reduced TCR and peptide challenge leads to a phenotypic change resulting in T cell anergy. Importantly, adoptive transfer of these anergic T cells upon autoimmune disease induction had a marked reduction in disease severity compared with untreated MOG-specific CD4(+) T cells, which had significant autoimmune disease manifested by optic neuritis and death. Thus, reduction of TCR expression may provide a potential therapy for self-reactive T cells involved in autoimmune diseases through the induction of anergy.