David K. Okita

Prevention of experimental myasthenia gravis by nasal administration of synthetic acetylcholine receptor T epitope sequences.

T cell tolerization prevents and improves T cell-mediated experimental autoimmune diseases. We investigated here whether similar approaches could be used for antibody (Ab)-mediated autoimmune diseases. Myasthenia gravis, caused by IgG Ab against muscle acetylcholine receptor (AChR), is perhaps the best characterized of them. We used an animal model, experimental myasthenia gravis induced in C57Bl/6 mice by immunization with Torpedo acetylcholine receptor (TAChR), to demonstrate that nasal administration of synthetic sequences of the TAChR alpha-subunit- forming epitopes recognized by anti-TAChR CD4+ T helper cells (residues alpha150-169, alpha181-200, and alpha360-378), given before and during immunization with TAChR, causes decreased CD4+ responsiveness to those epitopes and to TAChR, reduced synthesis of anti-TAChR Ab, and prevented experimental myasthenia gravis. These effects were not induced by nasal administration of synthetic epitopes of diphtheria toxin. Secretion of IL-2, IL-4, and IL-10 by spleen T cells from TAChR immunized mice, in response to challenge with TAChR in vitro, indicated that in sham-tolerized mice only Th1 cells responded to TAChR, while peptide-treated mice had also an AChR-specific Th2 response. The TAChR peptide treatment induced also in vitro anergy to the TAChR of the spleen T cells, which was reversed by IL-2.

T-cell recognition of muscle acetylcholine receptor subunits in generalized and ocular myasthenia gravis

Objectives: Our purpose was to identify the muscle acetylcholine receptor (AChR) subunits recognized by autoimmune CD4+ T cells in myasthenia gravis(MG) and determine whether they differ in generalized (gMG) and ocular MG(oMG), and as gMG progresses. Methods: We tested the proliferative response of blood CD4+ cells from 25 patients with gMG and four patients with oMG to synthetic peptides spanning the sequence of each subunit of human muscle AChR. We also investigated the antisubunit response of Th1 cells (a CD4+ subset frequently involved in autoimmune phenomena) using an enzyme-linked immunospot (ELISPOT) assay of antigen-induced secretion of interferon-γ by individual CD4+ cells. Results: In gMG patients both the total CD4+ population and the Th1 subset recognized all AChR subunits to comparable extents. oMG patients recognized the AChR ϵ subunit minimally, and other subunits consistently and more strongly. gMG patients whose disease had lasted less than 5 years had lower antisubunit responses, and several of them did not recognize some AChR subunits; patients whose disease had lasted for 5 or more years had higher antisubunit responses and always responded to all AChR subunits. Conclusions: CD4+ and Th1 responses in MG involve the entire AChR molecule. This likely results from spreading of the CD4+ sensitization to increasingly larger parts of the AChR as the disease progresses. The differential recognition of AChR subunits in oMG might be related to the preferential involvement of extrinsic ocular muscles, which express AChR containing the γ subunit.

C57BL/6 Mice Genetically Deficient in IL-12/IL-23 and IFN-γ Are Susceptible to Experimental Autoimmune Myasthenia Gravis, Suggesting a Pathogenic Role of Non-Th1 Cells

Immunization with Torpedo acetylcholine receptor (TAChR) induces experimental autoimmune myasthenia gravis (EAMG) in C57BL/6 (B6) mice. EAMG development needs IL-12, which drives differentiation of Th1 cells. The role of IFN-γ, an important Th1 effector, is not clear and that of IL-17, a proinflammatory cytokine produced by Th17 cells, is unknown. In this study, we examined the effect of simultaneous absence of IL-12 and IFN-γ on EAMG susceptibility, using null mutant B6 mice for the genes of both the IL-12/IL-23 p40 subunit and IFN-γ (dKO mice). Wild-type (WT) B6 mice served as control for EAMG induction. All mice were immunized with TAChR in Freund’s adjuvant. dKO mice developed weaker anti-TAChR CD4+T cells and Ab responses than WT mice. Yet, they developed EAMG symptoms, anti-mouse acetylcholine receptor (AChR) Ab, and CD4+ T cell responses against mouse AChR sequences similar to those of WT mice. dKO and WT mice had similarly reduced AChR content in their muscles, and IgG and complement at the neuromuscular junction. Naive dKO mice had significantly fewer NK, NKT, and CD4+CD25+Foxp3+ T regulatory (Treg) cells than naive WT mice. Treg cells from TAChR-immunized dKO mice had significantly less suppressive activity in vitro than Treg cells from TAChR-immunized WT mice. In contrast, TAChR-specific CD4+ T cells from TAChR-immunized dKO and WT mice secreted comparable amounts of IL-17 after stimulation in vitro with TAChR. The susceptibility of dKO mice to EAMG may be due to reduced Treg function, in the presence of a normal function of pathogenic Th17 cells.

Thl epitope repertoire on the a subunit of human muscle acetylcholine receptor in myasthenia gravis

In myasthenia gravis (MG), CD4+ T helper cells recognize the muscle acetylcholine receptor (AChR) a subunit. We investigated the epitope repertoire of anti-AChR blood CD4+ Thl cells from 13 myasthenic patients and three healthy controls, using overlapping synthetic peptides screening the α subunit sequence and an enzyme-linked immunospot (ELISPOT) assay that detects antigen-induced interferon-γ secretion of individual Th1 cells. All patients recognized a pool of the a subunit peptides. All but one patient recognized numerous peptides. Each patient had an individual pattern of peptide recognition, but most or all patients recognized four sequences (residues 48–67, 101–137, 304–322, and 403–437) that stimulated relatively large numbers of Thl cells. They include previously identified “immunodominant” sequences recognized by AChR-specific CD4+ T cell lines from myasthenic patients. Peptide 1–14 was also recognized frequently. The controls recognized, with a low precursor frequency, the peptide pool and a few peptides that frequently included the immunodominant sequences described above. The present results demonstrate that Th1 cells are involved in the anti-AChR response in MG and that their epitope repertoire is very complex. This indicates that when MG is clinically evident, the AChR itself is the sensitizing antigen and the target of the autoimmune Th1 cells, although it does not exclude that molecular mimicry between one AChR epitope and a microbial structure may have triggered this autoimmune response. Although the complexity of the Th1 repertoire suggests that development of specific immunosuppressive treatments targeted on epitopes recognized by autoimmune T cells will be difficult, the existence of immunodominant T epitope sequences might facilitate that task.

Mapping myasthenia gravis–associated T cell epitopes on human acetylcholine receptors in HLA transgenic mice

Susceptibility to myasthenia gravis (MG) is positively linked to expression of HLA-DQ8 and DR3 molecules and negatively linked to expression of the DQ6 molecule. To elucidate the molecular basis of this association, we have induced experimental autoimmune MG (EAMG) in mice transgenic for HLA-DQ8, DQ6, and DR3, and in DQ8xDQ6 and DQ8xDR3 F(1) transgenic mice, by immunization with human acetylcholine receptor (H-AChR) in CFA. Mice expressing transgenes for one or both of the HLA class II molecules positively associated with MG (DQ8 and DR3) developed EAMG. T cells from DQ8 transgenic mice responded well to three cytoplasmic peptide sequences of H-AChR (alpha320-337, alpha304-322, and alpha419-437), of which the response to alpha320-337 was the most intense. DR3 transgenic mice also responded to this sequence very strongly. H-AChR- and alpha320-337 peptide-specific lymphocyte responses were restricted by HLA class II molecules. Disease resistance in DQ6 transgenic mice was associated with reduced synthesis of anti-AChR IgG, IgG(2b), and IgG(2c) Abs and reduced IL-2 and IFN-gamma secretion by H-AChR- and peptide alpha320-337-specific lymphocytes. Finally, we show that DQ8 imparts susceptibility to EAMG and responsiveness to an epitope within the sequence alpha320-337 as a dominant trait.

Subcutaneous administration of T-epitope sequences of the acetylcholine receptor prevents experimental myasthenia gravis

Immunization with acetylcholine receptor (AChR) causes experimental myasthenia gravis (EMG). The s.c. administration to C57B1/6 mice of synthetic AChR CD4+ epitopes, before and during AChR immunization, reduced the epitope-specific CD4+ responses and the anti-AChR Ab synthesis, and prevented EMG. The s.c. administration of solubilized AChR had effects similar to those of peptide treatment. Sham-tolerized mice had only Th1 anti-AChR cells, whereas peptide-treated mice had also Th2 cells, and Th2-induced anti-peptide Ab. Established EMG was not affected by s.c. peptide treatment, whereas it worsened after s.c. administration of solubilized AChR.

Absence of IL-4 facilitates the development of chronic autoimmune myasthenia gravis in C57BL/6 mice.

Myasthenia gravis (MG) is a T cell-dependent, Ab-mediated autoimmune disease. Ab against muscle acetylcholine receptor (AChR) cause the muscular weakness that characterizes MG and its animal model, experimental MG (EMG). EMG is induced in C57BL6 (B6) mice by three injections of Torpedo AChR (TAChR) in adjuvant. B6 mice develop anti-TAChR Ab that cross-react with mouse muscle AChR, but their CD4+ T cells do not cross-react with mouse AChR sequences. Moreover, murine EMG is not self-maintaining as is human MG, and it has limited duration. Several studies suggest that IL-4 has a protecting function in EMG. Here we show that B6 mice genetically deficient in IL-4 (IL-4−/−) develop long-lasting muscle weakness after a single immunization with TAChR. They develop chronic self-reactive Ab, and their CD4+ T cells respond not only to the TAChR and TAChR α subunit peptides, but also to several mouse AChR α subunit peptides. These results suggest that in B6 mice, regulatory mechanisms that involve IL-4 contribute to preventing the development of a chronic Ab-mediated autoimmune response to the AChR.

Interleukin-4 deficiency facilitates development of experimental myasthenia gravis and precludes its prevention by nasal administration of CD4+ epitope sequences of the acetylcholine receptor.

Immunization with acetylcholine receptor (AChR) causes experimental myasthenia gravis (EMG). We investigated EMG in interleukin (IL)-4 knock out B6 (KO) mice, that lack Th2 cells. EMG was more frequent in KO than in wild type B6 mice. KO and B6 mice developed similar amounts of anti-AChR antibodies. They were IgG2a and IgG2b in KO mice, IgG1 and IgG2b in B6 mice. CD4+ cells from KO and B6 mice recognized the same AChR epitopes. Nasal administration of synthetic AChR CD4+ epitopes reduced antibody synthesis and prevented EMG in B6, not in KO mice. Thus, Th2 cells may have protective functions in EMG.

T cell recognition of muscle acetylcholine receptor in ocular myasthenia gravis.

We examined the proliferative response of blood CD4(+) cells to muscle acetylcholine receptor (AChR) subunits and the epitope repertoire of the epsilon and gamma subunits, in ocular myasthenia gravis (oMG) patients and healthy subjects. oMG patients seldom recognized all subunits. The frequency and intensity of recognition was the same for all subunits, irrespective of the disease duration. The responses in oMG were lower than in generalized myasthenia gravis. Healthy subjects had frequent, low responses to one or more subunits. oMG patients recognized several epitopes on the gamma and epsilon subunits, that partially overlapped those recognized in gMG. The subunits and epitopes recognized by individual oMG patients changed over time. Thus, oMG patients have minimal and unstable sensitization of anti-AChR CD4(+) cells, in agreement with their low and inconsistent synthesis of anti-AChR antibody.

CD4+ T cells specific for factor VIII as a target for specific suppression of inhibitor production.

The studies we reviewed here have begun to clarify the complex cellular mechanisms involved in the immune response to fVIII, and the circumstances under which fVIII inhibitors develop. Further characterization and comparison of the immune response to fVIII in both hemophilia patients and healthy subjects will help to further elucidate these mechanisms. The murine hemophilia model will hopefully provide further insights into the mechanisms of inhibitor formation, and prove to be a suitable tool for the design and testing of therapeutic strategies aimed at preventing the development of fVIII inhibitors.