Crystal structure of Fab198, an efficient protector of the acetylcholine receptor against myasthenogenic antibodies

The crystal structure of the Fab fragment of the rat monoclonal antibody 198, with protective activity for the main immunogenic region of the human muscle acetylcholine receptor against the destructive action of myasthenic antibodies, has been determined and refined to 2.8 A resolution by X-ray crystallographic methods. The mouse anti-lysozyme Fab D1.3 was used as a search model in molecular replacement with the AMORE software. The complementarity determining regions (CDR)-L2, CDR-H1 and CDR-H2 belong to canonical groups. Loops CDR-L3, CDR-H2 and CDR-H3, which seem to make a major contribution to binding, were analyzed and residues of potential importance for antigen-binding are examined. The antigen-binding site was found to be a long crescent-shaped crevice. The structure should serve as a model in the rational design of very high affinity humanized mutants of Fab198, appropriate for therapeutic approaches in the model autoimmune disease myasthenia gravis.

The conformation of the main immunogenic region on the alpha-subunit of muscle acetylcholine receptor is affected by neighboring receptor subunits

Myasthenia gravis (MG) is caused by autoantibodies to the acetylcholine receptor (AChR). Experiments with fetal (alpha(2)betagammadelta) and adult (alpha(2)betaepsilondelta) AChR and with recombinant subunit dimers showed that some monoclonal antibodies (mAbs) against the main immunogenic region (MIR), located on the alpha-subunit of the AChR, bind better to fetal AChR and to alphagamma subunit dimer than to adult AChR and alphaepsilon dimer and equally to both alphabeta and alphadelta. However, other anti-MIR mAbs prefer adult AChR and alphaepsilon dimer, bind well to alphabeta but weakly to alphadelta. These results suggest that the MIR conformation is affected by the neighboring gamma/epsilon- and delta-subunits and may contribute to understanding the antibody specificities in MG.

Severe congenital myasthenic syndrome due to homozygosity of the 1293insG epsilon-acetylcholine receptor subunit mutation

Recently, a congenital myasthenic syndrome (CMS) with end-plate acetylcholine receptor (AChR) deficiency due to missense mutations in the genes for the AChR subunit was described. The first observed patient with this CMS was heteroallelic for the two epsilon-AChR subunit mutations epsilon1101insT and epsilon1293insG. This patient had only a moderate phenotype with mild muscle weakness and abnormal fatigue. We have now found homozygosity for the epsilon1293insG mutation in a severely affected CMS patient, who lost the ability to walk in midchildhood and shows profound weakness and muscle wasting. Our observation allows a genotype-phenotype correlation illustrating how differences in the AChR mutation haplotype can profoundly influence disease severity.

Reconstitution of conformationally dependent epitopes on the N-terminal extracellular domain of the human muscle acetylcholine receptor alpha subunit expressed in Escherichia coli: implications for myasthenia gravis therapeutic approaches

Myasthenia gravis (MG) is an autoimmune disease, caused by autoantibodies against the muscle acetylcholine receptor (AChR), an oligomeric transmembrane glycoprotein composed of alpha(2)beta gamma delta subunits. The alpha subunit carries in its N-terminal extracellular domain the main immunogenic region (MIR), a group of conformationally dependent epitopes that seems to be a major target for the anti-AChR antibodies in MG patients. Detailed epitope studies on pathogenic anti-AChR antibodies have been hindered because the binding of most of these antibodies is conformationally dependent, which precludes the use of denatured AChR fragments. The N-terminal extracellular fragment, residues 1-207, of the human AChR alpha subunit was expressed in Escherichia coli in a denatured form, solubilized in a guanidinium hydrochloride-containing buffer, purified, and renatured using a refolding approach which employs a detergent and a cyclodextrin as 'artificial chaperones'. Compared with the non-refolded protein, the refolded molecule exhibited a dramatic improvement in terms of the binding of all anti-MIR mAb tested. Anti-MIR mAb that normally bind weakly to the denatured alpha subunit bound approximately 30-100 times better to the refolded polypeptide and other anti-MIR mAb that bind exclusively to completely conformationally dependent epitopes also bound quite efficiently. These results, in addition to providing a means for the thorough investigation of the antigenic structure of the AChR, show that the conformationally dependent MIR epitopes do not require the participation of the oligosaccharide moiety of the alpha subunit nor the contribution of neighboring subunits for antibody binding. Such AChR fragments may be used in structural studies of the AChR autoantigen, and should prove valuable in the understanding and development of therapeutic approaches for MG.

Compared structures of the free nicotinic acetylcholine receptor main immunogenic region (MIR) decapeptide and the antibody-bound [A76]MIR analogue: a molecular dynamics simulation from two-dimensional NMR data

Monoclonal antibodies against the main immunogenic region (MIR) of the muscle acetylcholine receptor (AChR) are capable of inducing experimental myasthenia gravis (MG) in animals. The epitope of these antibodies has been localized between residues 67 and 76 of the AChR alpha-subunit. The conformation in solution of the Torpedo californica MIR peptide and of its [A76] MIR analogue have been analyzed using molecular modeling based on nmr interproton distances and J-derived phi dihedral angles. Molecular dynamics simulations including dimethyl-sulfoxide as explicit solvent have been carried out on the free MIR peptide. Calculation of the structure of the [A76]MIR analogue bound to an anti-MIR monoclonal antibody have been performed in the presence of water molecules. A tightly folded structure appears for both peptides with alpha beta-folded N-terminal N68-P-A-D71 sequence of type I in the free state and type III in the mAb6-bound state. The C-terminal sequence is folded in two different ways according to the result in the free and bound state of the peptides: two overlapping beta/beta or beta/alpha turns result in a short helical sequence in the free MIR peptide, whereas the bound analogue is folded by uncommon hydrogen bond closing an 11-membered cycle. This structural evolution is essentially the result of the reorientation of the hydrophobic side chains that are probably directly involved in peptide--antibody recognition.

Treatment of passively transferred experimental autoimmune myasthenia gravis using papain

Antibody-mediated acetylcholine receptor (AChR) loss at the neuromuscular junction, the main cause of the symptoms of myasthenia gravis, is induced by bivalent or multivalent antibodies. Passive transfer of experimental autoimmune myasthenia gravis (EAMG) can be induced very efficiently in rats by administration of intact MoAbs directed against the main immunogenic region (MIR) of the AChR, but not by their monovalent Fab fragments. We tested whether papain, which has been used therapeutically in autoimmune and other diseases, is capable of preventing EAMG by in vivo cleavage of the circulating anti-AChR antibodies into Fab fragments. EAMG was induced in 4-week-old female Lewis rats by i.p. injection of anti-MIR mAb35. A total of 0.75 mg of papain was given as one or three injections 3-7 h after MoAb injection. The mAb35 + papain-treated animals developed mild weakness during the first 30 h and subsequently recovered, while all animals that received only mAb35 developed severe myasthenic symptoms and died within 24-30 h. Animals treated only with papain showed no apparent side effects for up to 2 months. Serum anti-AChR levels in mAb35 + papain-treated rats decreased within a few hours, whereas in non-papain-treated rats they remained high for at least 30 h. Muscle AChR in mAb35 + papain-treated animals was partially protected from antibody-mediated degradation. These results show that treatment of rats with papain can prevent passively transferred EAMG without any apparent harm to the animals, and suggest a potential therapeutic use for proteolytic enzymes in myasthenia gravis.

Prevention of passively transferred experimental autoimmune myasthenia gravis by Fab fragments of monoclonal antibodies directed against the main immunogenic region of the acetylcholine receptor

The muscle acetylcholine receptor loss, responsible for the clinical symptoms of myasthenia gravis, is due mainly to mechanisms dependent on the bivalent character of the anti-receptor antibodies. In cell culture, univalent Fab fragments of monoclonal antibodies (mAbs) directed against the main immunogenic region (MIR) of the acetylcholine receptor are able to protect the receptor against the action of the intact antibodies. To investigate the potential therapeutic use of this approach, we examined the ability of the Fab fragment of anti-MIR mAb195 (Fab195) to protect the receptor in vivo against two anti-MIR mAbs. Because of the rapid clearance of Fab fragments from the circulation, Lewis rats were treated repeatedly with Fab195. The Fab fragment significantly protected muscle receptors against antibody-mediated loss and was very efficient in providing protection against clinical symptoms when its administration was commenced before, simultaneously with, or 2 h after, mAb injection. Twenty-four hours after mAb injection, the protected rats only showed mild myasthenic symptoms, whereas those which only received intact antibodies were moribund or dead. These results suggest that, once modified to ensure their low immunogenicity and a long half-life, anti-MIR Fab fragments might be useful in the specific immunotherapy of myasthenia gravis.

The crystal structure of the Fab fragment of a rat monoclonal antibody against the main immunogenic region of the human muscle acetylcholine receptor

The crystal structure of the Fab fragment of a rat monoclonal antibody, number 192, with a very high affinity (Kd = 0.05 nM) for the main immunogenic region of the human muscle acetylcholine receptor (AChR), has been determined and refined to 2.4 A resolution by X-ray crystallographic methods. The overall structure is similar to a Fab (NC6.8) from a murine antibody, used as a search model in molecular replacement. Structural comparisons with known antibody structures showed that the conformations of the hypervariable regions H1, H2, L1, L2, L3 of Fab192 adopt the canonical structures 1, 1, 2, 1, and 1, respectively. The surface of the antigen-binding site is relatively planar, as expected for an antibody against a large protein antigen, with an accessible area of 2865 A2. Analysis of the electrostatic surface potential of the antigen-binding site shows that the bottom of the cleft formed in the center of the site appears to be negatively charged. The structure will be useful in the rational design of very high affinity humanized mutants of Fab192, appropriate for therapeutic approaches of the model autoimmune disease myasthenia gravis.

The third-dimensional structure of the complex between an Fv antibody fragment and an analogue of the main immunogenic region of the acetylcholine receptor: a combined two-dimensional NMR, homology, and molecular modeling approach

Binding of autoantibodies to the acetylcholine receptor (AChR) plays a major role in the autoimmune disease Myasthenia gravis (MG). In this paper, we propose a structure model of a putative immunocomplex that gives rise to the reduction of functional AChR molecules during the course of MG. The model complex consists of the [G(70), Nle(76)] decapeptide analogue of the main immunogenic region (MIR), representing the major antigenic epitope of AChR, and the single chain Fv fragment of monoclonal antibody 198, a potent MG autoantibody. The structure of the complexed decapeptide antigen [G(70), Nle(76)]MIR was determined using two-dimensional nmr, whereas the antibody structure was derived by means of homology modeling. The final complex was constructed using calculational docking and molecular dynamics. We termed this approach "directed modeling," since the known peptide structure directs the prestructured antibody binding site to its final conformation. The independently derived structures of the peptide antigen and antibody binding site already showed a high degree of surface complementarity after the initial docking calculation, during which the peptide was conformationally restrained. The docking routine was a soft algorithm, applying a combination of Monte Carlo simulation and energy minimization. The observed shape complementarity in the docking process suggested that the structure assessments already led to anti-idiotypic conformations of peptide antigen and antibody fragment. Refinement of the complex by dynamic simulation yielded improved surface adaptation by small rearrangements within antibody and antigen. The complex presented herein was analyzed in terms of antibody-antigen interactions, properties of contacting surfaces, and segmental mobility. The structural requirements for AChR complexation by autoantibodies were explored and compared with experimental data from alanine scans of the MIR peptides. The analysis revealed that the N-terminal loop of the peptide structure, which is indispensable for antibody recognition, aligns three hydrophobic groups in a favorable arrangement leading to the burial of 40% of the peptide surface in the binding cleft upon complexation. These data should be valuable in the rational design of an Fv mutant with much improved affinity for the MIR and AChR to be used in therapeutic approaches in MG.

Alpha subunit composition of nicotinic acetylcholine receptors in the rat autonomic ganglia neurons as determined with subunit-specific anti-alpha(181-192) peptide antibodies

The subunit composition of nicotinic acetylcholine receptors of rat autonomic ganglia neurons was studied by means of antibodies, which differentiated between different alpha subunits and specifically blocked acetylcholine-induced membrane currents. Polyclonal rabbit antibodies and mouse monoclonal antibodies were raised against synthetic peptides matching in sequence the alpha(181-192) region of alpha3, alpha4, alpha5, and alpha7 subunits of rat neuronal nicotinic acetylcholine receptors. The antibodies discriminated among alpha3, alpha4, alpha5, and alpha7 peptides in enzyme-linked immunosorbent assay and bound to native acetylcholine receptors expressed in PC-12 cells. By means of immunoperoxidase staining of cultured rat autonomic neurons followed by transmission, dark-field and phase-contrast microscopy, it was found that all cells of the superior cervical ganglia expressed the alpha3, alpha5, and alpha7 nicotinic acetylcholine receptors, whereas approximately half of the cells were clearly alpha4-positive. In contrast, only about one-third of the intracardiac neurons were alpha3-positive, about 50% were alpha4-positive, one-seventh were alpha5-positive, and one-fifth were alpha7-positive. All antibodies tested blocked acetylcholine-induced currents in the neurons of the superior cervical ganglia as was demonstrated by whole-cell patch-clamp studies. Although each antibody could block up to 80% of the current, the degree of inhibition varied considerably from cell to cell. It is concluded that alpha3, alpha5, and alpha7 subunits are expressed in all neurons of the superior cervical ganglion and in some intracardiac neurons, whereas alpha4 subunits are expressed in some but not all neurons of both tissues. The neurons of the superior cervical ganglion express heterogeneous acetylcholine receptors and differ in relative amounts of acetylcholine receptor subtypes expressed.

Detection of antibodies directed against the cytoplasmic region of the human acetylcholine receptor in sera from myasthenia gravis patients

The nicotinic acetylcholine receptor (AChR) is the autoantigen in the human autoimmune disease myasthenia gravis (MG). Anti-AChR antibodies in MG sera bind mainly to conformational epitopes, therefore the determination of their specificities requires the use of native AChR. Antibody competition studies suggest that most MG antibodies are directed against the extracellular part of the molecule, whereas antibodies directed against the cytoplasmic region of the AChR have not been detected. To determine whether even small quantities of such antibodies exist in MG sera, we performed competition experiments based on the inhibition by MG sera of the binding of MoAbs to the human AChR, rather than inhibition by MoAbs of the binding of MG sera performed earlier. When MoAbs directed against cytoplasmic epitopes on the alpha or beta subunits (alpha 373-380 and beta 354-360) were used as test MoAbs, 17% or 9% of MG sera inhibited the binding of the anti-alpha or anti-beta subunit MoAbs, respectively, by > or = 50%. Non-specific inhibition was excluded. These results suggest the presence, in several MG sera, of antibodies directed against cytoplasmic regions of the AChR; yet these antibodies seemed to represent a relatively small proportion of the total anti-AChR antibodies. The corresponding epitopes may be involved in the inducing mechanisms in certain MG cases, and knowledge of the presence of such antibodies may be useful in understanding the autoimmune mechanism involved in MG.

High affinity single-chain Fv antibody fragments protecting the human nicotinic acetylcholine receptor

Univalent antibody fragments directed against the main immunogenic region (MIR) of the human acetylcholine receptor (AChR) are capable of protecting the AChR against loss induced by antibodies from myasthenia gravis (MG) patients. Our aim was to construct single-chain Fv (scFv) antibody fragments as a first step towards the production of therapeutic protecting molecules, from two high-affinity anti-MIR monoclonal antibodies (mAb 192 and mAb 195). During the construction of scFv192 fragment, two light chains co-secreted from the hybridoma mAb192 were identified. N-terminal amino acid and cDNA sequence analysis showed that one of the two light chains corresponded to the antigen binding molecule while the other originated from the non-secreting myeloma S194/5.XXO.BU.1 which was used in the production of the hybridoma. Functional scFv 192 and 195 fragments were constructed, expressed in Escherichia coli and affinity purified. The binding affinities of scFv192 and scFv195 (K(D) = 0.6 and 0.8 nM for human AChR) were two orders of magnitude higher than that of the earlier constructed scFv198. The scFv192 almost completely protected human AChR against binding of intact anti-MIR mAbs. Human AChR was also very efficiently protected (74-85%) by the scFv192 against binding of autoantibodies from MG sera with high anti-alpha subunit antibody fractions. These scFvs are good candidates for protection of MG patients after appropriate genetic modifications.

Construction and characterization of a humanized single chain Fv antibody fragment against the main immunogenic region of the acetylcholine receptor

The single chain Fv fragment of mAb198 (scFv198) directed against the main immunogenic region (MIR) of the nicotinic acetylcholine receptor (AChR), can efficiently protect the AChR in muscle cell cultures against the destructive activity of human myasthenic autoantibodies. Humanization of the scFv198 antibody fragment should prove useful for therapeutic application by reducing its immunogenicity. Framework sequences from human immunoglobulins homologous to the rat scFv198 sequences were selected and a totally synthetic humanized scFv198 antibody fragment was constructed in vitro. Humanized VH and VL domains were synthesized using two overlapping sets of 225 bases long oligonucleotides overlap extension and polymerase chain reaction (PCR), then assembled into a full-length gene by overlap extension of single-stranded DNA (ssDNA) fragments and PCR. The initial humanized antibody fragment had a very low affinity for the AChR. Molecular modeling was then performed and four residues from the framework regions (FR) of the humanized VH domain were selected to be replaced by the corresponding amino acid from the rat sequence. Three mutants were constructed by overlap extension, using PCR. The humanized variant containing replacements at VH residues 27, 29, 30 and 71 showed very good recovery of AChR binding activity; its binding affinities for Torpedo or human AChR (K(D): 8.5 or 323 nM, respectively) being only four times lower than those of the parental scFv198 (K(D): 2 or 80 nM, respectively). This variant was able to protect the human AChR against the binding of anti-MIR mAb and anti-alpha autoantibodies from a myasthenic patient. It was also able to protect AChR against antigenic modulation induced by the anti-MIR mAb198.

Anatomy of the antigenic structure of a large membrane autoantigen, the muscle-type nicotinic acetylcholine receptor

The neuromuscular junction nicotinic acetylcholine receptor (AChR), a pentameric membrane glycoprotein, is the autoantigen involved in the autoimmune disease myasthenia gravis (MG). In animals immunized with intact AChR and in human MG, the anti-AChR antibody response is polyclonal. However, a small extracellular region of the AChR alpha-subunit, the main immunogenic region (MIR), seems to be a major target for anti-AChR antibodies. A major loop containing overlapping epitopes for several anti-MIR monoclonal antibodies (mAbs) lies within residues alpha 67-76 at the extreme synaptic end of each alpha-subunit: however, anti-MIR mAbs are functionally and structurally quite heterogeneous. Anti-MIR mAbs do not affect channel gating, but are very effective in the passive transfer of MG to animals; in contrast, their Fab or Fv fragments protect the AChR from the pathogenic effects of the intact antibodies. Antibodies against the cytoplasmic region of the AChR can be elicited by immunization with denatured AChR and the precise epitopes of many such mAbs have been identified; however, it is unlikely that such antibodies are present in significant amounts in human MG. Antibodies to other extracellular epitopes on all AChR subunits are present in both experimental and human MG; these include antibodies to the acetylcholine-binding site which affect AChR function in various ways and also induce acute experimental MG. Finally, anti-AChR antibodies cross-reactive with non-AChR antigens exist, suggesting that MG may result from molecular mimicry. Despite extensive studies, many gaps remain in our understanding of the antigenic structure of the AChR; especially in relation to human MG. A thorough understanding of the antigenic structure of the AChR is required for an in-depth understanding, and for possible specific immunotherapy, of MG.

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 alpha 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 alpha subunit (H alpha1-210), and to portions of it that encompass either the MIR (H alpha1-121) or the ligand binding site of AChR (H alpha122-210), 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 H alpha1-121 and H alpha1-210 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 H alpha1-121 and H alpha1-210 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 H alpha122-210 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.

Triphosgene: an efficient carbonylating agent for liquid and solid-phase aza-peptide synthesis. Application to the synthesis of two aza-analogues of the AChR MIR decapeptide

The N alpha/C alphaH exchange in aza-peptides has the advantage of preserving the side chain. Bis(trichloromethyl)carbonate or triphosgene is a solid, stable phosgene substitute which retains its high reactivity. Temperature and coupling times are greatly reduced with reference to other usually recommended carbonylating agents, while purity and yield are increased. It has been used, in both liquid- and solid-phase procedures, for the synthesis of various aza-analogues of dipeptides, tripeptides and decapeptides containing the alanine, aspartic acid and asparagine aza-residue.

Expression of human-Torpedo hybrid acetylcholine receptor (AChR) for analysing the subunit specificity of antibodies in sera from patients with myasthenia gravis (MG)

The nicotinic AChR, a pentamer composed of alpha2betagamma(or epsilon)delta subunits, is the autoantigen in the human autoimmune disease MG. Anti-AChR antibodies in MG sera bind mainly to conformational epitopes, therefore determination of their specificities requires the use of intact AChR. Indirect antibody competition studies have suggested that most MG antibodies are inhibited from binding to AChR by MoAb to the main immunogenic region (MIR) on the alpha-subunits. More recently, based on the knowledge that MG antibodies show little detectable cross-reaction with Torpedo AChR, we have shown, using mouse-Torpedo hybrid AChR, that most MG antibodies that detectably cross-react with the mouse AChR bind to the alpha-subunit. To analyse the whole anti-AChR antibody repertoire in MG sera, we expressed on stably transfected fibroblasts a novel human alpha+ Torpedo betagammadelta AChR and compared the antibody titres against human, Torpedo, and the hybrid AChR. Direct information was provided for the subunit specificity of several MoAbs and sera from 50 MG patients. On average, at least 48% of the anti-AChR antibodies in the sera were directed against the alpha-subunit. Interestingly, the anti-alpha-subunit antibodies predominated in low titre (0.6-7.4 nM) but not in high titre (10-386 nM) sera, where they comprised on average 68% versus 23% of the antibodies, respectively. Finally, the directly determined anti-alpha-subunit antibodies and the anti-MIR antibodies defined by antibody competition were significantly correlated, thus suggesting that at least a significant fraction of the anti-MIR antibodies in MG sera bind to the alpha-subunit.

Characterisation, crystallisation and preliminary X-ray diffraction analysis of a Fab fragment of a rat monoclonal antibody with very high affinity for the human muscle acetylcholine receptor

The Fab fragment of a rat monoclonal antibody (no. 192) with very high affinity for the main immunogenic region of the human muscle nicotinic acetylcholine receptor (AChR) has been purified, characterised and crystallised using vapour diffusion techniques. Its Kd for human AChR was determined to be 5 X 10(-11) M. Its cross-reactivity pattern suggests that residue alpha23 of the AChR strongly affects its epitope. Crystals suitable for X-ray analysis, obtained by micro- and macroseeding techniques, belong to the orthorhombic space group C222(1) and they diffract to 2.8 A resolution using synchrotron radiation. The unit cell dimensions are alpha=83.4 A, b=110.0 A and c=212.2 A and there are two Fab molecules per asymmetric unit.

Antibodies to acetylcholinesterase cross-reacting with thyroglobulin in myasthenia gravis and Graves's disease

In the present study we analysed by ELISA the ability of sera from 50 patients with myasthenia gravis (MG), 20 with Hashimoto's thyroiditis (HT), 53 with Graves' disease (GD) and 36 healthy controls (CR) to react with acetylcholinesterase (AChE) from Electrophorus electricus and human thyroglobulin (Tg). Significantly increased anti-AChE activity was exhibited by a high proportion of MG (IgG 36%) and GD (IgG 21%) sera, while increased anti-Tg activity was detected in all three patient groups (MG, IgG 26% and IgA 26%; HT, IgG 85% and IgA 40%; and GD, IgG 51%). Interestingly, a significant proportion of MG and GD sera exhibited both IgG anti-AChE and anti-Tg activities (MG, 18%; P < 0.001; and GD, 15%; P < 0.001, versus CR, 0%). This bi-reactivity was exhibited by anti-AChE antibodies cross-reacting with Tg (anti-AChE/Tg activity); (i) serum anti-AChE activity was effectively inhibited by soluble Tg, and (ii) affinity-purified anti-Tg antibodies cross-reacted with AChE. Cross-reactivity seems to be a property of pathological (auto)antibodies; induced (rabbit) antibodies to AChE or Tg were highly monospecific. Analysis of clinical data showed that increased IgG anti-AChE/Tg activity was well associated with: (i) overlapping GD in MG (P < 0.02), and (ii) ophthalmopathy in GD (P < 0.01). In contrast, no correlation was noted in MG between anti-AChE activity units and anti-Tg activity units or acetylcholine receptor antibody titres. The clinical significance of anti-AChE/Tg antibodies remains to be elucidated.

Monoclonal antibodies against the acetylcholine receptor gamma-subunit as site specific probes for receptor tyrosine phosphorylation

Tyrosine phosphorylation of the nicotinic acetylcholine receptor (AChR) may be involved in AChR desensitization and clustering. Torpedo AChR gamma-subunit is phosphorylated at Tyr365. Using overlapping synthetic peptides, we have precisely mapped the epitopes of five anti-gamma-subunit monoclonal antibodies (mAbs) and found that the epitope(s) for the mAbs 154, 165 and 168 (gamma 365-370) all contain Tyr365. mAb 168 is a known blocker of AChR channel function. Using peptide analogues, Tyr365 was found to be indispensable for mAb165 binding; furthermore its binding was selectively inhibited by in vitro AChR tyrosine phosphorylation. The possible connection between gamma-subunit phosphorylation and regulation of AChR function and the proven usefulness of these mAbs as tools should facilitate functional studies of AChR gamma-subunit phosphorylation.