Characterization of ganglionic acetylcholine receptor autoantibodies

In myasthenia gravis (MG), autoantibodies bind to the alpha1 subunit and other subunits of the muscle nicotinic acetylcholine receptor (AChR). Autoimmune autonomic ganglionopathy (AAG) is an antibody-mediated neurological disorder caused by antibodies against neuronal AChRs in autonomic ganglia. Subunits of muscle and neuronal AChR are homologous. We examined the specificity of AChR antibodies in patients with MG and AAG. Ganglionic AChR autoantibodies found in AAG patients are specific for AChRs containing the alpha3 subunit. Muscle and ganglionic AChR antibody specificities are distinct. Antibody crossreactivity between AChRs with different alpha subunits is uncommon but can occur.     

Muscle autoantibodies in subgroups of myasthenia gravis patients

Myasthenia gravis (MG) is caused by autoantibodies to the acetylcholine receptor (AChR), but several other muscle autoantibodies have also been identified in patient sera. We studied muscle autoantibodies against AChR, striated muscle tissue sections (SH), titin, citric acid antigen (CA), and ryanodine receptor (RyR) in sera from 146 consecutive MG patients to evaluate whether a single test or several tests together can predict a thymoma. The MG patients were divided into five subgroups; ocular MG, early-onset MG (< 50 years), late-onset MG (≥ 50 years), MG with thymoma, and AChR antibody negative MG. AChR, SH, titin, CA, and RyR antibodies were detected in 85%, 34%, 34%, 25%, and 14% of the MG patients, respectively. For thymoma MG, AChR, SH, titin, CA, and RyR antibodies were detected in 100%, 75%, 95%, 70%, and 70% respectively. SH, titin, CA, RyR antibodies, and computed tomography of the anterior mediastinum have similar sensitivity for thymoma MG. The specificity of RyR, titin, CA, and SH antibodies for thymoma was 70%, 39%, 38%, and 31%, respectively, which is significantly higher for RyR antibodies than for the others. No single muscle antibody assay can predict a thymoma, and a combination of several antibody assays is preferred, although RyR antibody testing alone showed 70% sensitivity and specificity for thymoma MG. SH and CA antibodies provided only little additional information. Received: 23 September 1999, Received in revised form: 6 December 1999, Accepted: 19 January 2000     

The severity of myasthenia gravis correlates with the serum concentration of titin and ryanodine receptor antibodies

BACKGROUND: Myasthenia gravis (MG) is caused by autoantibodies to the acetylcholine receptor (AChR). Non-AChR muscle autoantibodies are present in many MG serum samples, mainly from patients with thymoma or late-onset MG. The exact relationship between MG severity and several non-AChR muscle antibodies is unknown. OBJECTIVE: To study the correlation between the severity of MG and the concentration of antibodies against striated muscle tissue sections, titin, citric acid antigen, ryanodine receptor, and AChR. SETTING: The severity of MG was graded in 146 consecutive patients with MG, and their serum samples were tested for the presence of autoantibodies. Ten patients who were titin antibody positive were observed in longitudinal follow-up. RESULTS: No significant difference was found in MG severity between late-onset and thymoma MG. Titin, citric acid antigen, and ryanodine receptor antibodies occurred significantly more often among patients with severe MG than among patients with less severe disease. Changes in MG severity correlated with changes in titin antibody titer in the individual patient. Titin antibodies showed a better longitudinal correlation with disease severity than the AChR antibodies. CONCLUSIONS: Non-AChR muscle autoantibodies occurred more frequently in severe MG regardless of MG subgroup. Thymoma per se does not generate a more severe MG. It may well be the presence of a humoral immune response to non-AChR muscle antigens such as titin, citric acid antigen, and ryanodine receptor that leads to a severe disease, not the presence of thymoma or a late age of onset. These antibodies can serve as important prognostic markers in MG regardless of the presence of thymoma.     

Extracellular domains of the beta, gamma and epsilon subunits of the human acetylcholine receptor as immunoadsorbents for myasthenic autoantibodies: a combination of immunoadsorbents results in increased efficiency

Myasthenia gravis (MG) is usually caused by autoantibodies against the human muscle acetylcholine receptor (AChR). Plasmapheresis offers a therapeutic option, but, as well as removing the pathogenic anti-AChR autoantibodies, it non-specifically removes indispensable immunoglobulins. An attractive alternative to plasmapheresis would be the extracorporeal specific removal of the autoantibodies using AChR-based immunoadsorbents. Previously, we used the N-terminal extracellular domain (ECD) of the AChR alpha subunit to immunoadsorb anti-alpha subunit autoantibodies from MG sera. In this study, we immobilised the beta -, gamma- and epsilon-AChR ECDs on Sepharose and tested them as immunoadsorbents on 50 MG sera. A given ECD removed a different percentage of autoantibodies from different sera and different ECDs removed different percentages from the same serum; on average, the beta-, gamma- and epsilon-ECDs removed 22%, 20% and 15.5% of the autoantibodies, respectively. Immunoadsorption was completed in 3 min, 1 mug of ECD removed approximately 2 pmol of autoantibodies, and the immunoadsorbent could be recycled approximately 4 times. The combined use of two (alpha+gamma) or four (alpha+beta+gamma+epsilon) ECDs in a single immunoadsorbent resulted in much higher (often additive) immunoadsorption. These results show that MG sera have autoantibodies against several AChR subunits, and suggest that the combined use of all AChR ECDs could provide the basis for a novel, antigen-specific therapy for MG.     

Myasthenia, thymoma, presynaptic antibodies, and a continuum of neuromuscular hyperexcitability.

BACKGROUND: Autoantibodies specific for the nicotinic acetylcholine receptor (AChR) of skeletal muscle impair neuromuscular transmission in myasthenia gravis (MG). Autoantibodies specific for alpha3 neuronal AChRs or voltage-gated potassium channels have been reported in patients with Isaacs syndrome, an acquired disorder of continuous muscle fiber activity characterized by neuromyotonia. OBJECTIVE: To report the neuromuscular autoantibody profiles of three patients with a syndrome of MG and neuromuscular hyperexcitability. RESULTS: All three patients reported here had clinical and electrophysiologic evidence of MG and neuromuscular hyperexcitability. None had neuromyotonia. Thymoma was proven in two patients and suspected in the third. One had MG and thymoma and subsequently developed cramp-fasciculation syndrome; MG and rippling muscle syndrome appeared simultaneously in the other two. All patients had muscle and neuronal AChR binding antibodies and striational antibodies. Only one had antibodies reactive with alpha-dendrotoxin-complexed potassium channels. CONCLUSIONS: The coexistence of cramp-fasciculation syndrome and acquired rippling muscle syndrome with MG, thymoma, and neuronal AChR autoantibodies suggests that there is a continuum of autoimmune neuromuscular hyperexcitability disorders related pathogenically to Isaacs syndrome. Manifestations of neuromuscular hyperexcitability may be altered and less apparent in the context of MG because of the coexisting defect of neuromuscular transmission.     

Pathogenic mechanisms of myasthenia gravis induced by antibodies against muscle-specific kinase]

Antibodies to acetylcholine receptor (AChR) are major cause of the human autoimmune disease, myasthenia gravis (MG). Additionally, autoantibodies against Muscle-specific kinase (MuSK) were found in a proportion of patients with generalized MG. After the identification of MuSK antibodies in MG patients, laboratory test for measuring antibodies to MuSK is now required to confirm the diagnosis of MG and the clinical treatment as well as AChR antibodies. MuSK is critical to the clustering of AChR and plays multiple roles at neuromuscular junctions (NMJ). However, it has been dispute concerning the pathogenicity of MuSK antibodies in muscle weakness of MG, as the experimental autoimmune MG caused by MuSK antibodies was absent. Here we describe the recent progress to understand the pathogenic roles of MuSK antibodies in muscle weakness of experimental animals induced by MuSK protein.     

Myasthenia gravis and myasthenic syndromes

More than a decade ago myasthenic symptoms were observed in rabbits immunized with acetylcholine receptor (AChR) [119] and AChR deficiency was found at the neuromuscular junction in human myasthenia gravis (MG) [36]. By 1977 the autoimmune character of MG and the pathogenic role of AChR antibodies had been established by several measures. These included the demonstration of circulating AChR antibodies in nearly 90% of patients with MG [87], passive transfer with IgG of several features of the disease from human to mouse [149], localization of immune complexes (IgG and complement) on the postsynaptic membrane [30], and the beneficial effects of plasmapheresis [20, 123]. Substantial subsequent progress has occurred in understanding the structure and function of AChR and its interaction with AChR antibodies. The relationships of the concentration, specificities, and functional properties of the antibodies to the clinical state in MG have been carefully analyzed, and the mechanisms by which AChR antibodies impair neuromuscular transmission have been further investigated. The clinical classification of MG has been refined, the role of the thymus gland in the disease has been further clarified, and new information has become available on transient neonatal MG. The prognosis for generalized MG is improving, but there is still no consensus on its optimal management. Novel therapeutic approaches to MG are now being explored in animal models. Recognition of the autoimmune origin of acquired MG also implied that myasthenic disorders occurring in a genetic or congenital setting had a different cause. As a result, a number of congenital myasthenic syndromes have come to be recognized and investigated. Finally, an acquired disorder of neuromuscular transmission different from MG, the Lambert-Eaton myasthenic syndrome, has also been shown to have an autoimmune basis. In this syndrome, active zone particles of the presynaptic membrane are direct or indirect targets of the pathogenic autoantibodies.     

Frequency of seronegativity in adult-acquired generalized myasthenia gravis

We determined the prevalence of muscle acetylcholine receptor (AChR) antibodies in patients with adult-acquired generalized myasthenia gravis (MG), the seroconversion rate at 12 months, and the prevalence of muscle-specific tyrosine kinase (MuSK) antibody among persistently seronegative patients. We identified 562 consecutive Mayo Clinic patients with MG based on clinical and electrophysiological criteria. At presentation, 508 patients (90.4%) tested positive for AChR binding or AChR modulating antibodies. After 12 months, 15.2% of initially seronegative patients had become seropositive, yielding a seronegativity rate of 8.2% (95% confidence interval: 6.2-9.6%). Among seronegative patients not receiving immunosuppressants, 38% were MuSK antibody-positive and 43% were seropositive for nonmuscle autoantibodies. Classification as seronegative MG should be reserved for nonimmunosuppressed patients with generalized MG who lack muscle AChR binding, AChR modulating, or MuSK antibodies at presentation and at follow-up of at least 12 months.     

Rituximab treatment of myasthenia gravis: A systematic review

Rituximab is a chimeric mouse/human anti‐CD20 monoclonal immunoglobulin. We reviewed the efficacy and safety of rituximab in 169 myasthenia gravis (MG) patients from case reports and series. Antibodies to the acetylcholine receptor (AChR) were present in 59% and muscle‐specific tyrosine kinase (MuSK) in 34%. Modified Myasthenia Gravis Foundation of America postintervention scale of minimal manifestations (MM) or better occurred in 44%, and combined pharmacologic and chronic stable remission in 27% overall; MM or better was achieved in 72% of MuSK MG and 30% of AChR MG (P < 0.001). Posttreatment relapses decreased more in MuSK MG (P = 0.05). Response predictors were MuSK MG, less severe disease, and younger age at treatment. Among a responder subset, 26% of AChR and 82% of MuSK MG patients showed decreased posttreatment antibody titers. Rituximab was generally well tolerated. Detectable serum rituximab and depleted CD20⁺ B‐cells were observed up to 20 and 16 weeks, respectively, after 4 weekly infusions. Muscle Nerve 56 : 185–196, 2017     

T cells in myasthenia gravis specific for embryonic acetylcholine receptor.

In myasthenia gravis (MG) there is an autoimmune response against muscle acetylcholine receptor (AChR). Embryonic and adult muscles express different AChRs; embryonic AChR contains a gamma subunit, instead of the homologous epsilon subunit that contributes to form adult AChR. We report propagation from the blood of MG patients of T helper (TH) cell lines specific for human embryonic AChR, by cycles of stimulation with a pool of synthetic peptides corresponding to the complete sequence of the gamma subunit (gamma pool). The TH lines strongly recognized AChR from embryonic mammalian muscle, and reacted less or not at all with adult muscle AChR. The existence of TH cells specific for embryonic AChR strongly suggests that the primary anti-AChR sensitization in MG occurs in a tissue other than the innervated skeletal muscle. This may be within the thymus, which expresses an AChR similar or identical to embryonic muscle AChR.     

Specific immunoadsorption of the autoantibodies from myasthenic patients using the extracellular domain of the human muscle acetylcholine receptor alpha-subunit. Development of an antigen-specific therapeutic strategy

Antibodies against the acetylcholine receptor (AChR) are the main pathogenic factor in myasthenia gravis (MG). Clinical improvement correlates well with a reduction in levels of circulating anti-AChR antibodies, and plasmapheresis is an efficient short-term MG treatment. The Sepharose-immobilized N-terminal extracellular domain of human muscle AChR alpha-subunit was used to immunoadsorb anti-AChR autoantibodies from 50 MG patients sera. The immunoadsorbents removed 60-94% of the anti-AChR antibodies in 10 sera and a mean of 35% from all samples combined. Immunoadsorption was fast, efficient, and the columns could be used repeatedly without any release or proteolysis of the polypeptide, suggesting the feasibility of antigen-specific MG immunoadsorption therapy.     

Morphological effects of myasthenia gravis patient sera on human muscle cells

Myasthenia gravis (MG) is caused primarily by autoantibodies against the nicotinic acetylcholine receptor (AChR), but autoantibodies to other muscle proteins may be present. Many of these proteins have structural or signalling functions, the disruption of which may affect muscle cell morphology or viability. In order to investigate the role of such autoantibodies in MG, we examined the effect of MG patient sera, of different autoantibody composition and obtained at different stages of disease severity, on primary human muscle cells. Sera from MG patients induced changes in cell morphology from typical elongated cells to an irregular phenotype, caused the formation of inclusion bodies and intracellular vesicles, and led to a disordered arrangement of actin microfilaments. Sera from the most severely affected patients also induced cell death, which did not occur via classic apoptosis. The effects were not complement-mediated and were dose- and time-dependent. As the effects observed in the cell culture system correlated with disease severity, a greater understanding of the individual factors responsible for these effects may improve our understanding of MG pathogenesis and be of value in the assessment of disease in individual patients.     

The significance of titin antibodies in myasthenia gravis

Myasthenia gravis (MG) is caused by autoantibodies to acetylcholine receptors (AChR). Non-AChR muscle autoantibodies, such as titin antibodies, are present in sera of many MG patients. To study the correlation between titin antibodies and the features of MG, the cDNA segment encoding MGT-30 was amplified and sequenced. The cloned MGT-30 cDNA was expressed in vector pET-30a, and then transfected into E.coli. BL21. We examined titin antibodies in sera of 265 normal subjects, 154 MG patients with different thymic pathology and 48 patients with other neurological diseases. Titin antibodies occurred more frequently in MGT, especially in MG with epithelial predominant-thymoma, and were correlated with the severity of disease. The levels of titin antibodies were reduced 6 months after thymectomy. The specificity of titin antibodies for the detection of thymoma was higher than that of CT examination in MG with thymoma. These results suggest that titin antibodies could be useful in both diagnosis and follow-up of MG patients with thymoma.     

Thymectomy in nonthymoma early-onset myasthenia gravis in correlation with disease severity and muscle autoantibodies

OBJECTIVE: To study the clinical effect of thymectomy in a well-defined early-onset MG subgroup and to correlate it to MG severity, the presence of circulating muscle autoantibodies, and the need for pharmacological treatment in a long-term setting. METHODS: Fifty-two consecutive AChR antibody-positive early-onset MG patients (34 thymectomized and 18 nonthymectomized) were included. Severity was assessed and the pharmacological treatment monitored on a yearly basis, starting from the year of MG onset, for 5, 10, 15, and 20 consecutive years; AChR, titin, and RyR antibodies were assayed. RESULTS: In the four follow-up groups, MG severity was significantly higher in nonthymectomized compared to thymectomized MG patients. The postthymectomy MG improvement was significant and persistent. There were 21/34 remissions in thymectomized patients and only 4/18 in the nonthymectomized group. Patients with initially high or low AChR antibody concentration had a similar thymectomy outcome. Only 6 patients had titin antibodies, and none had RyR antibodies. CONCLUSION: The present study indicates a benefit of thymectomy in early-onset MG. The muscle autoantibody concentration does not influence the outcome of thymectomy in early-onset MG.     

Effects of myasthenia gravis patient sera on human myoblast cultures

Objectives –  To investigate the role of acetylcholine receptor (AChR) and other anti-muscle autoantibodies in myasthenia gravis (MG). Since many of these autoantibodies target proteins with structural or signalling functions, we examined the effect of MG sera on muscle cell morphology.
Materials and methods –  Primary human myoblast cultures were exposed to MG sera and morphological changes observed by light and fluorescence microscopy.
Results –  MG patient sera caused changes in cell shape (cell retraction) and led to the formation of inclusion bodies and intracellular vesicles. A disordered arrangement of actin microfilaments was also observed. The effects were not complement-mediated, were both dose- and time-dependent, and appeared to correlate with disease severity of the MG donor.
Conclusion –  The factors responsible for these effects in vitro may also play a role in the pathogensis of MG in vivo . Further study of these factors may improve our understanding of MG pathogenesis.     

Canine and human myasthenia gravis autoantibodies recognize similar regions on the acetylcholine receptor

Serum from 35 cases of naturally occurring acquired canine myasthenia gravis (MG) were assayed for patterns of autoantibody specificities against canine acetylcholine receptor (AChR) using monoclonal antibodies (mAbs) and antiserum against defined regions of the AChR as competitive inhibitors of autoantibody binding. In human MG patients and in animals immunized with AChR purified from fish electric organs or mammalian muscle, most of the antibodies are directed against the main immunogenic region (MIR), a conformationally dependent region located on the extracellular surface of the alpha subunit away from the ACh binding site. In our studies using canine MG serum, we found that, as in human MG and in animals immunized with AChR, the antibody response is heterogeneous and predominantly IgG, with a large proportion of the autoantibodies directed against the MIR. The mAbs to the MIR blocked an average of 68% of serum antibody binding. A mAb to the beta subunit and polyclonal antiserum to the gamma subunit blocked an average of 34% and 39% of serum antibody binding, respectively, indicating that these subunits also contain relevant antigenic determinants, a pattern that has also been observed in human MG serum. Anti-alpha bungarotoxin binding site antibodies made up only a small fraction of the autoantibody population in canine MG as in human MG. These and other features described here suggest that canine MG is a useful model of human MG.     

Autoantibodies to low-density lipoprotein receptor-related protein 4 in myasthenia gravis

Myasthenia gravis (MG) is an autoimmune disease of the neuromuscular junction, where acetylcholine receptor (AChR), muscle-specific kinase (MuSK), and low-density lipoprotein (LDL) receptor-related protein 4 (Lrp4) are essential. About 80% and 0% to 10% of patients with generalized MG have autoantibodies to AChR and MuSK, respectively, but pathogenic factors are elusive in others. Here we show that a proportion of AChR antibody-negative patients have autoantibodies to Lrp4. These antibodies inhibit binding of Lrp4 to its ligand and predominantly belong to the immunoglobulin G1 (IgG1) subclass, a complement activator. These findings together indicate the involvement of Lrp4 antibodies in the pathogenesis of AChR antibody-negative MG.     

Myasthenia in SCID mice grafted with myasthenic patient lymphocytes: role of CD4+ and CD8+ cells

OBJECTIVES: Acetylcholine receptor (AChR)-specific CD4+ cells are present in MG patients, and synthesis of the high-affinity immunoglobulin G (IgG) autoantibodies (autoAb) against the muscle AChR that causes MG symptoms requires intervention of CD4+ cells. The role of CD4+ cells in MG pathogenesis has been postulated but never proven. MG patients do not have anti-AChR cytotoxic phenomena, and it has been assumed that CD8+ cells do not have a pathogenic role in MG. However, CD8+ cells may facilitate rodent experimental MG, raising the possibility that CD8+ cells might be necessary also in MG. In this study we examined whether CD4+ and CD8+ cells play a role in the pathogenesis of MG and whether CD4+ cells specific for AChR epitope sequences recognized by most MG patients ("universal" epitopes) drive the synthesis of pathogenic antibodies. METHODS: First we characterized a chimeric human-mouse model of MG in severe combined immunodeficiency (SCID) mice engrafted with blood lymphocytes (BL) from MG patients. We used that model to determine whether CD4+ and CD8+ cells are necessary for transfer of MG symptoms. We engrafted SCID mice intraperitoneum with BL from 19 MG patients and 5 healthy controls. We engrafted some mice with either BL, BL depleted in CD4+ or CD8+ cells from the same patient, or CD4+ depleted BL reconstituted with CD4+ T cells from the same patient, specific for "universal" AChR epitopes or for two unrelated antigens, tetanus and diphtheria toxoids. We tested the mice for myasthenic symptoms for 7 to 18 weeks. RESULTS: Mice transplanted with BL, or CD8+ depleted BL, or CD4+-depleted BL reconstituted with anti-AChR CD4+ cells from MG patients frequently developed myasthenic weakness. The mice had human anti-AChR Ab in the serum and bound to muscle AChR. Mice transplanted with BL from controls, or CD4+-depleted BL from MG patients, or CD4+-depleted BL from an MG patient reconstituted with CD4+ cells specific for tetanus or diphtheria toxoids did not develop myasthenic weakness or anti-AChR Ab. CONCLUSIONS: CD4+ cells are necessary for MG pathogenesis; CD8+ cells may not be. CD4+ cells specific for "universal" AChR epitopes help the synthesis of pathogenic Ab.