Breakdown of tolerance to a self-peptide of acetylcholine receptor alpha-subunit induces experimental myasthenia gravis in rats

Experimental autoimmune myasthenia gravis (EAMG), a model for human myasthenia (MG), is routinely induced in susceptible rat strains by a single immunization with Torpedo acetylcholine receptor (TAChR). TAChR immunization induces anti-AChR Abs that cross-react with self AChR, activate the complement cascade, and promote degradation of the postsynaptic membrane of the neuromuscular junction. In parallel, TAChR-specific T cells are induced, and their specific immunodominant epitope has been mapped to the sequence 97-116 of the AChR alpha subunit. A proliferative T cell response against the corresponding rat sequence (R97-116) was also found in TAChR-immunized rats. To test whether the rat (self) sequence can be pathogenic, we immunized Lewis rats with R97-116 or T97-116 peptides and evaluated clinical, neurophysiological, and immunological parameters. Clinical signs of the disease were noted only in R97-116-immunized animals and were confirmed by electrophysiological signs of impaired neuromuscular transmission. All animals produced Abs against the immunizing peptide, but anti-rat AChR Abs were observed only in animals immunized with the rat peptide. These findings suggested that EAMG in rats can be induced by a single peptide of the self AChR, that this sequence is recognized by T cells and Abs, and that breakdown of tolerance to a self epitope might be an initiating event in the pathogenesis of rat EAMG and MG.     

Degradation of acetylcholine receptor in diaphragms of rats with experimental autoimmune myasthenia gravis.

The degradation of acetylcholine receptor observed in denervated and innervated normal rat diaphragms in organ culture is stimulated by exogenous antireceptor serum. In this paper we demonstrate that diaphragms from rats with experimental autoimmune myasthenia gravis contain reduced amounts of acetylcholine receptor. Acetylcholine receptor from myasthenic, but not from normal, rats has antibody bound to it and is degraded at an accelerated rate. We conclude that in the chronic phase of experimental autoimmune myasthenia gravis increased acetylcholine receptor degradation can be accounted for by a mechanism involving antigenic modulation, and that such a process can contribute to the clinical symptoms of impaired neuromuscular transmission.     

Chronic experimental autoimmune myasthenia gravis induced by monoclonal antibody to acetylcholine receptor: biochemical and electrophysiologic criteria

To determine whether the chronic presence of antibody to acetylcholine receptor (AChR) can account for the neuromuscular abnormalities in myasthenia gravis (MG), rats injected repeatedly with monoclonal antibody (mAb) to AChR were compared with those injected with control mAb. In a previous report, those receiving anti-AChR mAb, studied ultrastructurally, had grossly simplified endplates when compared with normal controls. In this report, animals injected once or chronically for 9 to 12 wk had reduced content of muscle AChR. The chronically injected animals also had diminished miniature endplate potential amplitudes, but to a lesser extent than the reduction in AChR content. These studies establish the pathogenetic role of antibody to AChR in the induction of the ultrastructural, biochemical, and electrophysiologic hallmarks of MG.     

Induction of peripheral tolerance to experimental autoimmune myasthenia gravis by acetylcholine receptor-pulsed dendritic cells

Dendritic cells (DC) are usually regarded as antigen-presenting cells involved in T cell activation, but DC also directly and indirectly affect B cell activation, antibody synthesis, and isotype switch. In the present study, bone marrow (BM)-derived DC from healthy rats were pulsed in vitro with acetylcholine receptor (AChR) and injected subcutaneously into healthy Lewis rats. No clinical signs of the first phase of experimental autoimmune myasthenia gravis (EAMG) were observed during 3 weeks of observation. Upon immunization with AChR and complete Freund's adjuvant, the rats that had received AChR-pulsed DC did not develop clinical EAMG. This tolerance of rats injected with AChR-pulsed DC was associated with reduced expression of B cell-activating factor (BAFF) and by reduced numbers of B cells among splenic mononuclear cells (MNC) compared to rats injected with medium or unpulsed DC. Anti-AChR IgG antibody-secreting cells were decreased, while the ratio of IgG1:IgG2b isotypes was enhanced in rats treated with AChR-pulsed DC compared to control EAMG rats. These results demonstrate that AChR-pulsed DC induce peripheral tolerance to EAMG by possibly inhibiting the expression of BAFF and production of anti-AChR antibodies, providing a possible potential for immunotherapy of antibody-mediated autoimmune diseases.     

Monoclonal anti-acetylcholine receptor antibodies with differing capacities to induce experimental autoimmune myasthenia gravis

To study the characteristics of the individual autoantibodies that are important in the development of an autoimmune disease, we produced 26 anti-acetylcholine receptor (anti-AChR) monoclonal antibodies (mcAb) and studied the experimental autoimmune myasthenia gravis (EAMG) induced by a number of them. The mcAb reactive with mammalian acetylcholine receptor (M-AChR) exhibited a wide range of dissociation rates from in situ M-AChR of motor endplates. All anti-M-AChR mcAb were capable of producing at least some degree of histopathologic change at the endplate indicative of EAMG, but their potencies varied markedly. One mcAb induced, even at large doses, only minor macrophage invasion without clinical or electromyographic effect. Others induced severe EAMG, and even death, at 1/200th the dose. Low potency was associated with high rate of mcAb dissociation from antigen. High potency was associated with intermediate avidity, not high avidity. These observations suggest that in EAMG, and perhaps in myasthenia gravis, the characteristics of the individual antibodies making up the autoimmune response can determine the severity of the autoimmune disease.     

Mice with IFN-gamma receptor deficiency are less susceptible to experimental autoimmune myasthenia gravis

IFN-gamma can either adversely or beneficially affect certain experimental autoimmune diseases. To study the role of IFN-gamma in the autoantibody-mediated experimental autoimmune myasthenia gravis (EAMG), an animal model of myasthenia gravis in humans, IFN-gammaR-deficient (IFN-gammaR-/-) mutant C57BL/6 mice and congenic wild-type mice were immunized with Torpedo acetylcholine receptor (AChR) plus CFA. IFN-gammaR-/- mice exhibited significantly lower incidence and severity of muscle weakness, lower anti-AChR IgG Ab levels, and lower Ab affinity to AChR compared with wild-type mice. Passive transfer of serum from IFN-gammaR-/- mice induced less muscular weakness compared with serum from wild-type mice. In contrast, numbers of lymph node cells secreting IFN-gamma and of those expressing IFN-gamma mRNA were strongly augmented in the IFN-gammaR-/- mice, reflecting a failure of negative feedback circuits. Cytokine studies by in situ hybridization revealed lower levels of lymphoid cells expressing AChR-reactive IL-1beta and TNF-alpha mRNA in AChR + CFA-immunized IFN-gammaR-/- mice compared with wild-type mice. No differences were found for AChR-reactive cells expressing IL-4, IL-10, or TGF-beta mRNA. These results indicate that IFN-gamma promotes systemic humoral responses in EAMG by up-regulating the production and the affinity of anti-AChR autoantibodies, thereby contributing to susceptibility to EAMG in C57BL/6-type mice.     

Prevention and reversal of experimental autoimmune myasthenia gravis by a monoclonal antibody against acetylcholine receptor-specific T cells

We have recently described an algorithm to design, among others, peptides with complementarity contour to autoimmune epitopes. Immunization with one such peptide resulted in a monoclonal antibody (mAb), termed CTCR8, that specifically recognized Vbeta15 containing TCR on acetylcholine receptor (AChR) alpha-chain residue 100-116-specific T cells. CTCR8 was found to label the cell surface of AChR100-116-specific T cell lines and clones, immunoprecipitate the TCR from such cells, and block their proliferative responses to AChRalpha100-116. In the present report, we have found that there is a marked reduction in IFN-gamma and no effect on IL-10 production in a CTCR8-treated AChRalpha100-116-specific T cell line. Interestingly, when AChR100-116-primed, primary T cells were stimulated with peptide and treated with CTCR8, there was once again inhibition of IFN-gamma but also marked stimulation of IL-10 production. The change in the Th1/Th2 cytokine profile was paralleled by a reduction in AChR-specific IgG2a and IgM with no effect on IgG1. Remarkably, the most profoundly inhibited Ab population was that which causes experimental autoimmune myasthenia gravis (EAMG) by reaction with the main immunogenic region (alpha61-76) of the AChR. Based on these results, CTCR8 was tested for prophylactic and therapeutic effects in EAMG. EAMG induced by immunization with purified native Torpedo AChR was both inhibited and reversed by CTCR8. These findings suggest a means to produce therapeutic mAb for the treatment of autoimmune diseases.     

Mutation at I-A beta chain prevents experimental autoimmune myasthenia gravis

Immune response (Ir) gene(s) at the I-A subregion of the mouse H-2 complex influence susceptibility to experimental autoimmune myasthenia gravis (EAMG). To determine the importance of the Ir gene product, the Ia antigens, in EAMG pathogenesis, we studied the degree of EAMG susceptibility of an I-A mutant strain, the B6.C-H-2 ^bm12 (bm12), and its parent B6/Kh. According to the cellular, humoral, biochemical, and clinical manifestations of EAMG, the I-A mutation converted an EAMG susceptible strain (B6/Kh) into a relatively resistant strain (bm12). The relative resistance to EAMG induction in bm12 may be due to the lack of Ia.8 and/or la.39 determinants and/or quantitative expression of la antigens.Abbreviations used in this paper MG myasthenia gravis - AChR acetylcholine receptors - EAMG experimental autoimmune myasthenia gravis - Ir immune response - B6 C57BL/6J - bm12 B6.C-H-2 ^bm12 - CFA complete Freund's adjuvant - LNC lymph node cells - PPD purified protein derivative     

The role of acetylcholine receptor antibodies in myasthenia gravis.

Myasthenia gravis is an autoimmune disease of man characterized by remitting and relapsing muscle fatigability. Although the etiology and pathogenesis are incompletely understood, the presence of circulating antibodies directed against the nicotinic acetylcholine (ACh) receptor in 80--90% of patients with myasthenia gravis and the identification of immune complexes at their neuromuscular junction have helped explain the altered neuromuscular transmission. The ACh receptor antibodies do not block access of ACh to the receptor, but do decrease the number of receptors by accelerating their degradation both in rat myotube cultures and in vivo models. In vitro these antibodies play a major role in myasthenia gravis. However, correlations of antibody titers with the clinical state following thymectomy or in neonatal myasthenia suggest that host factors may be equally important in determining whether the ACh receptor antibodies will result in clinical myasthenia.     

Specificity of the T cell immune response to acetylcholine receptor in experimental autoimmune myasthenia gravis. Response to subunits and synthetic peptides

Myasthenia gravis (MG) and its animal model, experimental autoimmune MG (EAMG), are T cell-dependent diseases mediated by antibodies against acetylcholine receptor (AChR) on skeletal muscle. Most of the antibodies are directed toward conformation-dependent epitopes on the AChR, whereas T cells recognize denatured AChR. In search of T cell epitopes in EAMG, we tested 24 synthetic peptides covering 62% of the alpha-subunit sequence of Torpedo californica electric organ AChR in the T cell proliferation assay with lymph node cells from rats immunized with AChR. In Lewis rats, 2 of these peptides, [Tyr 100]alpha 100-116 and [Gly 89, Tyr 90]alpha 73-90, strongly stimulated T cells and, of these, [Tyr 100]alpha 100-116 was much more potent; 4 other peptides were weakly mitogenic and 18 were ineffective. None of the 24 synthetic peptides alone stimulated anti-AChR production and, when added to cultures along with AChR, [Tyr 100]alpha 100-116 and [Gly 89, Tyr 90]alpha 73-90 suppressed antibody production. Of twelve cloned T cell lines specific to AChR, 4 responded to [Tyr 100]alpha 100-116, indicating the importance of the epitope in alpha 101-116 in Lewis rats. In three other strains of rats whose responses to AChR and its subunits were similar to those in the Lewis rat, neither [Tyr 100]alpha 100-116 nor [Gly 89, Tyr 90]alpha 73-90 was stimulatory. Instead, completely different sets of peptides stimulated their T cells. When peptides were used as immunogens, each strain (except Lewis rats) responded only to the peptides that stimulated AChR-immune T cells from the same strain. Genetically restricted T cell recognition of AChR peptides in rats suggests that T cells from MG patients with different major histocompatibility haplotypes may recognize different AChR peptides.     

Specific killing of lymphocytes that cause experimental autoimmune myasthenia gravis by ricin toxin-acetylcholine receptor conjugates

Experimental autoimmune myasthenia gravis (EAMG) is an autoimmune disease in which antibodies to acetylcholine receptor (AChR) cause loss of AChR from muscle, thereby impairing neuromuscular transmission. Here we report the use of a hybrid molecule that contains ricin toxin, irreversibly coupled to AChR to specifically suppress the immune response to AChR in vitro. Lymph node cell cultures from rats with EAMG pretreated with ricin toxin-AChR conjugates exhibited suppressed T helper cell proliferation and B cell antibody synthesis in response to the subsequent addition of AChR. Nonspecific toxicity of the conjugates was measured by suppression of the T cell proliferative response to the mitogen concanavalin A and the antigen keyhole limpet hemocyanin (KLH), and B cell antibody production to KLH. We have evaluated different pretreatment conditions and ricin toxin covalently coupled to AChR in different molar ratios to optimize specific immunosuppression. By varying the number of ricin molecules covalently bound to AChR in the immunotoxin, we were able to minimize the nonspecific toxicity while still maintaining specific killing of AChR-reactive lymphocytes. Furthermore, B cells were more susceptible to specific killing than were the T cells. The specific immunosuppression was potentiated by performing the pretreatment with immunotoxin in the presence of chloroquine. Chloroquine raises lysosomal pH and probably delays the degradation of immunotoxin in the cell. It should be noted that ricin toxin was covalently coupled to AChR by using a novel, non-reducible reaction. These in vitro results suggest that it may be feasible to use immunotoxin molecules to specifically suppress this autoimmune response in vivo.     

Ex vivo generated regulatory T cells modulate experimental autoimmune myasthenia gravis

Naturally occurring CD4(+)CD25(+) regulatory T (Treg) cells are key players in immune tolerance and have therefore been suggested as potential therapeutic tools for autoimmune diseases. In myasthenia gravis (MG), reduced numbers or functionally impaired Treg cells have been reported. We have observed that PBL from myasthenic rats contain decreased numbers of CD4(+)CD25(high)Foxp3(+) cells as compared with PBL from healthy controls, and we have tested whether Treg cells from healthy donors can suppress experimental autoimmune MG in rats. Because the number of naturally occurring Treg cells is low, we used an approach for a large-scale ex vivo generation of functional Treg cells from CD4(+) splenocytes of healthy donor rats. Treg cells were generated ex vivo from CD4(+) cells by stimulation with anti-CD3 and anti-CD28 Abs in the presence of TGF-beta and IL-2. The obtained cells expressed high levels of CD25, CTLA-4, and Foxp3, and they were capable of suppressing in vitro proliferation of T cells from myasthenic rats in response to acetylcholine receptor, the major autoantigen in myasthenia. Administration of ex vivo-generated Treg cells to myasthenic rats inhibited the progression of experimental autoimmune MG and led to down-regulation of humoral acetylcholine receptor-specific responses, and to decreased IL-18 and IL-10 expression. The number of CD4(+)CD25(+) cells in the spleen of treated rats remained unchanged, but the subpopulation of CD4(+)CD25(+) cells expressing Foxp3 was significantly elevated. Our findings imply that Treg cells play a critical role in the control of myasthenia and could thus be considered as potential agents for the treatment of MG patients.     

The limitation of IL-10-exposed dendritic cells in the treatment of experimental autoimmune myasthenia gravis and myasthenia gravis

Dendritic cells (DC) are highly specialized antigen presenting cells that play critical roles as instigators and regulators of immune responses including B cell function, antibody synthesis and isotype switch. In this study, we compared immunotherapeutic effect of IL-10-treated DC (IL-10-DC) via both intraperitoneal (i.p.) and subcutaneous (s.c.) delivery in rats with incipient experimental autoimmune myasthenia gravis (EAMG). Spleen DC were isolated from onset of EAMG on day 39 post-immunization, exposed in vitro to IL-10, and then injected into incipient EAMG at dose of 1 x 10(6) cells/rat on day 5 after immunization. Intraperitoneal administration of IL-10-DC suppressed clinical scores, anti-acetylcholine receptors (AChR) antibody secreting cells, antigen-specific IL-10/IFN-gamma production and T cell proliferation compared to control EAMG rats. Importantly, IL-10-DC, if given by s.c. route, failed to ameliorate clinical sign of EAMG. Simultaneously, T cell proliferation, anti-AChR antibody secreting cells and IL-10/IFN-gamma production had no alteration, as compared to control EAMG rats. Both in vitro and in vivo experiments showed that treatment of IL-10 inhibited the migration of DC toward MIP-3beta and lymph node, indicating that in vitro manipulation of DC with IL-10 alters the migration of DC that influences the therapeutic effect in the treatment of autoimmune diseases. In MG patients, neither the improvement of clinical symptom nor the alteration of immunological parameter was observed through s.c. delivery of IL-10-DC, suggesting the limitation of IL-10-DC in the treatment of MG patients.     

Determinant selection in murine experimental autoimmune myasthenia gravis. Effect of the bm12 mutation on T cell recognition of acetylcholine receptor epitopes.

C57BL/6 (B6) mice respond to immunization with acetylcholine receptor (AChR) from Torpedo californica as measured by T cell proliferation, antibody production, and the development of muscle weakness resembling human myasthenia gravis. The congenic strain B6.C-H-2bm12 (bm12), which differs from B6 by three amino acid substitutions in the beta-chain of the MHC class II molecule I-A, develops a T cell proliferative response but does not produce antibody or develop muscle weakness. By examining the fine specificity of the B6 and bm12 T cell responses to AChR by using T cell clones and synthetic AChR peptides, we found key differences between the two strains in T cell epitope recognition. B6 T cells responded predominantly to the peptide representing alpha-subunit residues 146-162; this response was cross-reactive at the clonal level to peptide 111-126. Based on the sequence homology between these peptides and the T cell response to a set of truncated peptides, the major B6 T cell epitope was determined to be residues 148-152. The cross-reactivity of peptides 146-162 and 111-126 could also be demonstrated in vivo. Immunization of B6 mice with either peptide primed for T cell responses to both peptides. In contrast, immunization of bm12 mice with peptide 111-126 primed for an anti-peptide response, which did not cross-react with 146-162. Peptide-reactive T cells were not elicited after immunization of bm12 mice with 146-162. These results define a major T cell fine specificity in experimental autoimmune myasthenia gravis-susceptible B6 mice to be directed at alpha-subunit residues 148-152. T cells from disease-resistant bm12 mice fail to recognize this epitope but do recognize other portions of AChR. We postulate that alpha-148-152 is a disease-related epitope in murine experimental autoimmune myasthenia gravis. In this informative strain combination, MHC class II-associated determinant selection, rather than Ag responsiveness per se, may play a major role in determining disease susceptibility.