Treatment of experimental myasthenia gravis with total lymphoid irradiation

Total lymphoid irradiation (TLI) has been reported to be effective in the immunosuppressive treatment of certain human and experimental autoimmune disorders. We have investigated the effects of TLI in Lewis rats with experimental autoimmune myasthenia gravis (EAMG) produced by immunization with purified torpedo acetylcholine receptor (AChR). The radiation is given in 17 divided fractions of 200 rad each, and nonlymphoid tissues are protected by lead shielding. This technique suppresses the immune system, while minimizing side effects, and permits the repopulation of the immune system by the patient's own bone marrow cells. Our results show that TLI treatment completely prevented the primary antibody response to immunization with torpedo AChR, it rapidly abolished the ongoing antibody response in established EAMG, and it suppressed the secondary (anamnestic) response to a boost of AChR. No EAMG animals died during TLI treatment, compared with six control animals that died of EAMG. TLI produces powerful and prompt immunosuppression and may eventually prove useful in the treatment of refractory human myasthenia gravis.     

An immunodominant site of acetylcholine receptor in experimental myasthenia mapped with T lymphocyte clones and synthetic peptides

Myasthenia gravis (MG) is an autoimmune disease of man caused by antibodies directed against the acetylcholine receptor (AChR). In the experimental model of MG in mice, murine experimental autoimmune myasthenia gravis (EAMG), an anti-AChR immune response is induced by immunization with Torpedo AChR, and anti-AChR antibodies. AChR-sensitized T cells, and neuromuscular dysfunction result. The production of antibodies to AChR is thymus-dependent. In order to define the epitopes of the AChR identified by AChR-specific T cells, we generated T cell populations and T cell hybridoma clones and tested their reactivity to synthetic uniform-sized overlapping peptides representing the entire extracellular portion of the alpha-chain of the AChR. The predominant reactivity of the T cell clones and the parent lines was to a peptide corresponding to residues 146-162 of Torpedo AChR. This data is consistent with a highly limited recognition of AChR determinants in murine EAMG by AChR-specific T cells.     

Experimental autoimmune myasthenia gravis induction in B cell-deficient mice

Experimental autoimmune myasthenia gravis (EAMG) is an animal model for human myasthenia gravis (MG). Autoantibody-induced functional loss of nicotinic acetylcholine receptor (AChR) at the postsynaptic membrane is an important pathogenic feature of both MG and EAMG. To evaluate the extent at which the humoral immune response against AChR operates in the pathogenesis of EAMG, we immunized B cell knockout (muMT) and wild- type C57BL/6 mice with AChR and complete Freund's adjuvant. The ability of AChR-primed lymph node cells to proliferate and secrete IFN-gamma in response to AChR and its dominant peptide alpha146-162 were intact in muMT mice as in wild-type mice. Similar amounts of mRNA for IFN-gamma, IL-4 and IL-10 in AChR-reactive lymph node cells were detected in muMT and wild-type mice. However, muMT mice had no detectable anti-AChR antibodies and remained completely free from clinical EAMG. We conclude that B cells are critically required for the genesis of clinical EAMG, but not for AChR-specific T cell priming.      

In vitro and in vivo actions of acetylcholine receptor educated suppressor T cell lines in murine experimental autoimmune myasthenia gravis.

Immunization of C57Bl/6 mice with Torpedo acetylcholine receptor (AChR) leads to EAMG, experimental autoimmune myasthenia gravis, with characteristic clinical, electrophysiological, and immune features. Present in the lymphoid organs of mice with EAMG are AChR specific suppressor T cells: these cells can be grown in vitro as T cell lines. These lines are able to suppress the in vitro response to AChR, and can suppress the in vivo development of EAMG.     

Prevention and therapy with electrolectin of experimental autoimmune myasthenia gravis in rabbits

Electrolectin (EL), an endogenous β-D -galactoside-binding lectin from Electrophorus electricus, was found to have a prophylactic and therapeutic action on the experimental autoimmune myasthenia gravis (EAMG) in rabbits. EAMG is an autoimmune disease induced by immunization with the purified acetylcholine receptor protein (AChR) and is considered to be a good model for the human disease myasthenia gravis. Simultaneous immunization with AChR and EL completely prevented the onset of myasthenic symptoms. This preventive effect was accompanied by a decrease in the recognition of AChR by anti-AChR antibodies. The administration of EL to myasthenic rabbits led, in most cases, to a complete recovery which was not accompanied by any significant change in the level of circulating anti-AChR antibodies. No evidence for an action of EL at the muscular level could be obtained. EL, however, was found to bind to rabbit lymphocytes and to stimulate their mitosis. These results suggest that EL produces its effects on EAMG by acting at the level of the immune system. It is proposed that EL may play a role in the immunological regulation of the response to self-antigen, which could be one of the biological functions of this animal lectin.     

Modulation of the anti-acetylcholine receptor response and experimental autoimmune myasthenia gravis by recombinant fragments of the acetylcholine receptor

Myasthenia gravis (MG) is a neuromuscular disorder of man caused by a humoral response to the acetylcholine receptor (AChR). Most of the antibodies in MG and in experimental autoimmune myasthenia gravis (EAMG) are directed to the extracellular portion of the AChR α subunit, and within it, primarily to the main immunogenic region (MIR). We have cloned and expressed recombinant fragments, corresponding to the entire extracellular domain of the AChR α subunit (Hα1 – 210), and to portions of it that encompass either the MIR (Hα1 – 121) or the ligand binding site of AChR (Hα122 – 210), and studied their ability to interfere with the immunopathological anti-AChR response in vitro and in vivo. All fragments were expressed as fusion proteins with glutathione S-transferase. Fragments Hα1 – 121 and Hα1 – 210 protected AChR in TE671 cells against accelerated degradation induced by the anti-MIR monoclonal antibody (mAb)198 in a dose-dependent manner. Moreover, these fragments had a similar effect on the antigenic modulation of AChR by other anti-MIR mAb and by polyclonal rat anti-AChR antibodies. Fragments Hα1 – 121 and Hα1 – 210 were also able to modulate in vivo muscle AChR loss and development of clinical symptoms of EAMG, passively transferred to rats by mAb 198. Fragment Hα122 – 210 did not have such a protective activity. Our results suggest that the appropriate recombinant fragments of the human AChR may be employed in the future for antigen-specific therapy of myasthenia.     

诱导实验性自身免疫性重症肌无力耐受性的机制初步探讨

目的:探讨鼻腔耐受和Wistar大鼠对实验性自身免疫性重症肌无力(EAMG)耐受的机制。方法:TdR掺入和酶联免疫斑点法。结果:免疫后第3、5、7周EAMG大鼠月国窝和腹股沟淋巴结(PILN)中乙酰胆碱受体(AChR)特异的淋巴细胞增生反应(LPR)刺激指数比鼻腔耐受大鼠高,第7周比Wistar大鼠高(P＜0.05)。免疫后第5、7周EAMG大鼠PILN中AChR反应性γ干扰素分泌细胞数比鼻腔耐受大鼠和Wistar大鼠高(P＜0.05)。结论:EAMG发生时淋巴细胞对AChR的免疫应答增强,分泌IFN-γ的Th1样细胞增多。EAMG耐受时,淋巴细胞对AChR的免疫应答降低,分泌IFN-γ的Th1样细胞受抑制。     

'Split tolerance' induction by intrathymic injection of acetylcholine receptor in a rat model of autoimmune myasthenia gravis; implications for the design of specific immunotherapies.

Experimental autoimmune myasthenia gravis (EAMG) in the Lewis rat, induced by a single injection of acetylcholine receptor (AChR) protein, is a model used to study human myasthenia gravis (MG). The production of anti-AChR antibodies in the animal model and human MG is T cell-dependent, and AChR-specific T cells have been considered as a potential target for specific immunotherapy. Intrathymic injection of antigens induces antigen-specific tolerance in several T cell-mediated autoimmune models. We examined the effect of intrathymic injection of AChR on T cell responses and the production of antibodies to AChR in EAMG rats. Primed lymph node cells from rats receiving intrathymic injection of AChR exhibited reduced proliferation to AChR with marked suppression of interferon-gamma (IFN-gamma) secretion in the antigen-stimulated culture, compared with those of rats injected with PBS. However, neither anti-Narke AChR nor anti-rat AChR antibody production was suppressed or enhanced in intrathymically AChR-injected animals compared with that of animals injected intrathymically with PBS or perithymically with AChR. This 'split tolerance' may be attributable to the suppression of type-1 T helper cells (Th1). Our results suggest that the suppression of Th1 function alone may not be sufficient for the prevention of antibody-mediated autoimmune diseases.     

The thymus in myasthenia gravis. Changes typical for the human disease are absent in experimental autoimmune myasthenia gravis of the Lewis rat.

In human myasthenia gravis (MG) formation of autoantibodies against acetylcholine receptor (AChR) is commonly associated with thymic changes termed lymphofollicular hyperplasia (LFH). To learn whether the thymic lesions of human MG are primary changes in the autoimmune pathogenesis, or rather secondary events caused by peripheral autoimmunization, the authors compared the pathologic changes of MG thymuses with the thymuses of Lewis rats with experimental autoimmune myasthenia gravis (EAMG). EAMG was induced either actively by immunization with AChR, or transferred passively with monoclonal antibodies (mAb) binding to AChR. The clinical diagnosis of EAMG was confirmed by electromyography. Germinal centers, which are typical for human MG thymuses, were not detectable in the thymus of EAMG rats. Scattered B cells were seen as normal components of the thymic medulla. In EAMG their number was not augmented, nor were they accumulated focally. The perivascular spaces (PVS) were not distended and the amount of reticulin was not increased. Thymic myoid cells were identified in EAMG as well as in control thymuses; their cellular microenvironment was inconspicuous. Both in normal and in EAMG thymuses, a subpopulation of myoid cells expressed the main immunogenic region of the AChR. Heavily affected rats showed a severe cortical involution, but no specific changes of the medulla. The fact that none of the thymic lesions characteristic for human MG was found in EAMG is compatible with the concept that the thymic changes in MG are primary events in the autoimmune pathogenesis of this disease.     

T-Cell Immunity to Acetylcholine Receptor and its Subunits in Lewis Rats over the Course of Experimental Autoimmune Myasthenia Gravis

Lymph nodes, spleen and thymus obtained from Lewis rats were examined over the course of experimental autoimmune myasthenia gravis (EAMG) for the distribution and the number of antigen-reactive CD4⁺ T helper cells which, upon recognition of Torpedo acetylcholine receptor (AChR) or the α, β, γ or δ subunits of Torpedo AChR, responded by secretion of interferon-gamma (IFN-γ). T cells with these specificities were detected in these three immune organs. Numbers were highest in lymph nodes. In spleen and thymus, numbers of antigen-reactive T cells did not differ. T cells reacting against the intact AChR were more frequent than T cells recognizing any of the subunits. The immunogenicity between the four subunits did not differ, with the exception that the α subunit induced a slightly higher T-cell response. No restriction of the T-cell repertoire to the four subunits was detected during early compared to late phases of EAMG. The AChR and subunit-reactive T cells could—via secretion of effector molecules including IFN-γ—play an important role in the initiation and perpetuation of EAMG. and consequently also of human myasthenia gravis. T cells with the same specificities were also detected in control animals injected with adjuvant only, but at much lower numbers which were within the range of T cells recognizing the control antigen myelin basic protein. They could represent naturally occurring autoimmune T cells.     

Pathogenic autoimmunity to affinity-purified mouse acetylcholine receptor induced without adjuvant in BALB/c mice

Myasthenia gravis (MG) and experimental autoimmune myasthenia gravis (EAMG) are antibody-mediated disorders in which anti-acetylcholine receptor (anti-AChR) antibodies cause loss of muscle AChR and subsequent weakness. Many species are susceptible to induction of EAMG with purified xenogeneic AChR in adjuvant, but injection of Torpedo AChR without adjuvants can also induce evidence of EAMG. To see whether pathogenic autoimmunity could be induced in mice by isolated mouse AChR we injected BALB/c mice with several doses (1 pmole; about 0.1 ug) of affinity-purified AChR (from the BC3H1 cell line but thought to be identical with denervated mouse muscle) intraperitoneally, without adjuvant, over a period of 10-22 weeks. Some of the mice became ill and died. High levels of serum anti-mouse AChR, directed mainly towards the main immunogenic region, were found and, in the survivors, correlated with loss of muscle AChR. Thus BALB/c mice can mount an autoimmune response to minute amounts of mouse AChR, without the use of adjuvants, and this response is very similar to that found in MG. This novel finding has implications regarding the etiology of the human disease.     

In vivo effects of neonatal administration of antiidiotype antibodies on experimental autoimmune myasthenia gravis.

The in vivo effects of neonatal administration of varying doses of anti-idiotype antibodies on serum anti-acetylcholine receptor (AChR) antibody titers, idiotype expression, and disease severity was studied in experimental autoimmune myasthenia gravis. Polyclonal affinity purified anti-idiotype antibodies and monoclonal anti-idiotype antibodies directed at anti-AChR monoclonal antibody 65 were administered in dosages varying from the nanogram to the microgram range. Mab 65 is directed against the main immunogenic region of mammalian AChR. In 1 out of 4 experiments administration of a nanogram dosage of anti-idiotype antibodies led to an enhanced anti-AChR antibody response after immunization with AChR. But no enhancing effect on idiotype expression could be demonstrated during this experiment. Adoptive transfer of spleen cells from rats pretreated with a nanogram dosage of anti-idiotype antibodies resulted in an significantly increased antibody response against rat AChR after immunization. From these experiments we conclude that in vivo administration of polyclonal or monoclonal anti-idiotypes does not reproduceably modify the serum antibody level against the acetylcholine receptor, nor influences the idiotype profile of the immune response. Secondly, the idiotype mediated manipulation of the immune response against large antigens, like the acetylcholine receptor, is clearly more complicated than that against small haptens. Adoptive transfer models, might be helpful in analysing the possibilities of anti-idiotype treatment in myasthenia gravis in more detail.     

Antigen-specific therapy of experimental myasthenia gravis with acetylcholine receptor-gelonin conjugates in vivo

Rats suffering from experimental autoimmune myasthenia gravis (EAMG) induced by previous immunization with foreign acetylcholine receptor (AChR) were treated with AChR-toxin conjugates using the plant toxin gelonin. This led to a marked improvement of clinical symptoms as well as a significant increase in functional AChR compared to untreated rats with EAMG as determined 6 to 10 weeks later. No therapeutic effect was observed after treatment with gelonin or AChR alone. The immune response to irrelevant control antigens was not altered by this treatment.     

Disruption of the IL-1beta gene diminishes acetylcholine receptor-induced immune responses in a murine model of myasthenia gravis

Human autoimmune myasthenia gravis (MG) is associated with the IL-1beta TaqI RFLP allele 2. Individuals positive for this allele have high levels of inducible IL-1beta in their peripheral blood. Here, we have characterized MG induction and the immune response elicited by Torpedo acetylcholine receptor (AChR) immunization in wild-type and IL-1beta deficient (-/-) mice. Compared with wild-type mice, IL-1beta-/- mice were relatively resistant to induction of clinical experimental autoimmune myasthenia gravis (EAMG). Draining lymph node cells from IL-1beta-/- mice showed poor proliferative capacity upon AChR stimulation in vitro. Both Th1 (IFN-gamma, IL-2) and Th2 (IL-4) cytokine responses were reduced and levels of serum anti-AChR antibodies decreased in IL-1beta-/- mice compared to wild-type mice. Taken together, these results reveal a critical role for IL-1beta in the induction of MG in mice, and support a role for IL-1beta in the pathogenesis of MG in man.     

Structural characterization of the main immunogenic region of the Torpedo acetylcholine receptor

To develop antigen-specific immunotherapies for autoimmune diseases, knowledge of the molecular structure of targeted immunological hotspots will guide the production of reagents to inhibit and halt production of antigen specific attack agents. To this end we have identified three noncontiguous segments of the Torpedo nicotinic acetylcholine receptor (AChR) α-subunit that contribute to the conformationally sensitive immunological hotspot on the AChR termed the main immunogenic region (MIR): α(1–12), α(65–79), and α(110–115). This region is the target of greater than 50% of the anti-AChR Abs in serum from patients with myasthenia gravis (MG) and animals with experimental autoimmune myasthenia gravis (EAMG). Many monoclonal antibodies (mAbs) raised in one species against an electric organ AChR cross react with the neuromuscular AChR MIR in several species. Probing the Torpedo AChR α-subunit with mAb 132A, a disease inducing anti-MIR mAb raised against the Torpedo AChR, we have determined that two of the three MIR segments, α(1–12) and α(65–79), form a complex providing the signature components recognized by mAb 132A. These two segments straddle a third, α(110–115), that seems not to contribute specific side chains for 132A recognition, but is necessary for optimum antibody binding. This third segment appears to form a foundation upon which the three-dimensional 132A epitope is anchored.     

The T-Cell Repertoire in Myasthenia Gravis Involves Multiple Cholinergic Receptor Epitopes

Antibodies against the alpha-subunit of the acetylcholine receptor (AChR) are found in most patients with myasthenia gravis and are considered to contribute to the receptor damage which leads to the characteristic signs and symptoms of the disease. This B-cell response is T-cell driven. Elevated T-cell reactivities to AChR and its alpha-subunit have been described in myasthenia gravis, and AChR alpha-subunit peptide reactive T-cell lines and clones preferentially recognizing certain defined sequence segments have been reported, thereby disclosing the possibility of specific immunotherapy. We have defined the T-cell repertoire to AChR, its alpha-subunit and the synthetic peptide sequences 100-117, 113-130, 143-163, 161-179, 207-225, 221-240, and 235-255 of the alpha-subunit in an immunospot assay which is based on secretion of interferon-gamma (IFN-gamma) by individual memory T cells upon stimulation with specific antigen in short-term cultures. Most patients with myasthenia gravis displayed T-cell reactivities to 1 to 6 different peptides. The mean numbers of T cells recognizing individual peptides varied in the myasthenia gravis patients between 1 per 77,000 and 1 per 167,000 peripheral blood mononuclear cells. None of the seven peptides evaluated could be identified as an immunodominant T-cell epitope, and any of them was found to dominate in individual patients. The numbers of T cells reacting with AChR and recombinant human AChR alpha-subunit were slightly higher (mean numbers 1 per 26,000 and 1 per 50,000 mononuclear cells, respectively). Such cells, as well as AChR alpha-subunit peptide reactive T cells, were also found in patients with other neurological diseases and in healthy subjects, but at lower frequencies and numbers. In myasthenia gravis, the elevated numbers of memory T cells recognizing multiple AChR alpha-subunit peptides may be crucial for the development of the disease, and the IFN-gamma released by such T cells might be important for its perpetuation.     

V{beta}-specific immunotoxin selectively kills acetylcholine receptor-reactive T lymphocytes from mice with experimental autoimmune myasthenia gravis

Immunization of C57BL/6 mice with purified acetytchollne receptor(AChR) is known to induce a T cell-dependent antibody responsethat results in experimental autoimmune myasthenia gravis (EAMG).Since past observations link V_ß6⁺ T cells with a prominentAChR epitope specificity, a V_ß6-specific immunotoxin(VIT6) was tested in vitro for its ability to selectively killmonoclonal and polyclonal T cells that demonstrate reactivityagainst AChR. Results described below clearly demonstrate theability to selectively kill AChR-reactlve T cells based on theirexpression of a particular V_ß-associated antigen receptor.     

The immunopathology of myasthenia gravis.

Experimental autoimmune myasthenia gravis, induced by immunization with solubilized acetylcholine receptors, has proven an excellent animal model for the study of myasthenia gravis. The role of the thymus in myasthenia gravis is not yet known. Its content of skeletal muscle elements and acetylcholine receptors and the presence of germinal centers in myasthenia gravis suggest that the thymus could be a site of autoimmunization. An effector role has not been demonstrated for T cells in the pathogenesis of experimental autoimmune or clinical myasthenia gravis, but helper T cells participate in the rat's autoantibody response to acetylcholine receptors. Antibodies and lymphocytes reactive with acetylcholine receptors are demonstrable in the peripheral blood of patients with myasthenia gravis and appear to be specific for this disease. Parallel studies of both experimental autoimmune and clinical myasthenia gravis have provided evidence for an autoimmune basis for the pathophysiology in myasthenia gravis. Antiacetylcholine receptor antibodies appear to play a central role in impairing neuromuscular transmission. Numerous antibody specificities have been described, but none seems to be directed at the acetylcholine binding site of the receptor. Addition of antiacetylcholine receptor antibodies to cultured muscle cells, in the absence of complement, causes redistribution of the receptors on the membranes of myotubes, accelerated receptor degradation, apparent impairment of ionophore function, and loss of sensitivity to acetylcholine. In vivo complement appears to be an important mediator of antiacetylcholine receptor antibody pathogenicity. Its presence is essential for the passive transfer of experimental autoimmune myasthenia gravis with antibodies. In muscle biopsy specimens from patients with myasthenia gravis, IgG and C3 have been demonstrated on the postsynaptic membrane and on degenerated fragments of membrane in the synaptic cleft. This suggests that complement activation in vivo is associated with focal lysis of the postsynaptic membrane. A causal relationship appears to exist between the binding of antibody to acetylcholine receptors, the reduction in muscle acetylcholine receptors, and impairment of neuromuscular transmission.     

Silencing miR‐146a influences B cells and ameliorates experimental autoimmune myasthenia gravis

MicroRNAs have been shown to be important regulators of immune homeostasis as patients with aberrant microRNA expression appeared to be more susceptible to autoimmune diseases. We recently found that miR‐146a was up‐regulated in activated B cells in response to rat acetylcholine receptor (AChR) α‐subunit 97‐116 peptide, and this up‐regulation was significantly attenuated by AntagomiR‐146a. Our data also demonstrated that silencing miR‐146a with its inhibitor AntagomiR‐146a effectively ameliorated clinical myasthenic symptoms in mice with ongoing experimental autoimmune myasthenia gravis. Furthermore, multiple defects were observed after miR‐146a was knocked down in B cells, including decreased anti‐R97‐116 antibody production and class switching, reduced numbers of plasma cells, memory B cells and B‐1 cells, and weakened activation of B cells. Previously, miR‐146a has been identified as a nuclear factor‐κB‐dependent gene and predicted to base pair with the tumour necrosis factor receptor‐associated factor 6 (TRAF6) and interleukin‐1 receptor‐associated kinase 1 (IRAK1) genes to regulate the immune response. However, our study proved that miR‐146a inhibition had no effect on the expression of TRAF6 and IRAK1 in B cells. This result suggests that the function of miR‐146a in B cells does not involve these two target molecules. We conclude that silencing miR‐146a exerts its therapeutic effects by influencing the B‐cell functions that contribute to the autoimmune pathogenesis of myasthenia gravis.