Antibodies to Yersinia enterocolitica in immunogenic thyroid diseases

In 1976 Shenkman et al. revealed that in patients with thyroid disorders antibodies against Yersinia enterocolitica could be demonstrated in increased frequency. In 1983 Ingbar et al. first established that the gram-negative bacterium Yersinia enterocolitica shows on its surface saturable binding sites for thyrotropin (TSH). If such binding sites resemble immunologically human TSH receptors this would indicate that TSH receptor antibodies could be produced in selected individuals having been infected with bacteria showing TSH receptors. The aim of our study was to compare the incidence of antibodies against Yersinia enterocolitica in two groups of thyroid disorders which are either immunogenic (Graves' disease and Hashimoto thyroiditis) or non-immunogenic (toxic adenomas, endemic goitre). In our series of 111 patients antibodies against Yersinia enterocolitica were demonstrated in a significantly higher percentage (36.3%) in patients suffering from immunogenic than in patients with non-immunogenic thyroid disorders (19.6%). The antibody titres were mainly directed towards Yersinia subtypes 8 and 3. It may, therefore, be assumed that the gram-negative bacterium Yersinia enterocolitica may have an active part in triggering immunogenic thyroid diseases such as Graves' disease or Hashimoto thyroiditis.     

Morphological demonstration and quantification of TSH binding sites in neoplastic and non-neoplastic thyroid tissues

Summary We have developed a morphological method to portray TSH binding sites in intact tissue specimens. Frozen sections were incubated with¹²⁵I-labelled TSH so as to localise binding sites by autoradiography. The proof of specificity was substantiated by: the competitive inhibition of¹²⁵I-TSH-labelling with cold TSH, the lack of binding in non-target tissues and a lack of binding in TSH target tissues after incubation with¹²⁵I-hCG or free¹²⁵I.In applying this method to a total of 22 surgical specimens of thyroid, striking differences came to light in respect of the degree to which¹²⁵I-TSH binding occurred in the various thyroid disorders. When compared with histologically normal tissue, labelling was generally decreased in toxic adenomas, non-functioning adenomas (cold nodules), and thyroids affected by Graves' disease, whereas non-toxic colloid goitre cases clearly exhibited denser binding. Medullary and anaplastic carcinomas exhibited no specific labelling whilst binding varied in the differentiated carcinomas between no effective binding or a level resembling that found in normal thyroid tissue.     

Changes in thyrotropin receptor antibody after subtotal thyroidectomy in Graves' disease: comparison with the degree of lymphocytic infiltration in the thyroid

To evaluate changes in TSH receptor antibody after surgery in Graves' disease and its relationship with the degree of lymphocytic infiltration, serial serum levels of TSH receptor antibody were measured before and after the subtotal thyroidectomy in 50 patients with Graves' disease. In 22 (44%) out of 50 patients, thyrotropin binding inhibitor immunoglobulin (TBII) levels gradually decreased and disappeared completely within 12 months after surgery (TBII disappearing group). Twenty-eight (56%) patients showed persistent TBII activity and their levels were not changed until 12 months after surgery (TBII persistent group). The changes of thyroid stimulating antibody (TSab) levels were very similar to those of TBII in both groups. The thyroidal lymphocytic infiltration was more prominent in the TBII disappearing group. The degree of the decrease of TBII levels after surgery correlated with the grade of thyroidal lymphocytic infiltration. There was no significant difference of TSH receptor antibody (both TBII and TSab) levels between the thyroid and peripheral venous blood. These data suggest that the persistence or disappearance of TSH receptor antibody after surgery may reflect the difference between patients in whom the thyroid is the major site of TSH receptor antibody and those in whom additional sites of TSH receptor antibody synthesis exist.     

Heterogeneity of thyrotropin binding inhibitor immunoglobulins in serum from untreated patients with hyperthyroid Graves' disease.

We have previously established an assay for the simultaneous assessment of thyrotropin (TSH) binding inhibitor immunoglobulin (TBII) and thyroid stimulating autoantibody activities in cultured rat thyroid cells (FRTL-5 cell), and found a discrepancy in some patients with untreated Graves' disease between the activities of TBII measured in FRTL-5 cells (TBII-rc) and in solubilized thyroid membranes (TBII-pm). In three selected patients with untreated Graves' disease, the different dose-response relationship between TBII-rc and TBII-pm clearly indicated the heterogeneous populations of TBII-pm in patients' sera, with different binding affinities for TSH receptor in intact cells.     

Immunoblotting for the detection of TSH receptor autoantibodies.

Immunoblotting was optimized to detect autoantibodies to TSH receptors from human and porcine thyroid tissue and to determine their epitope specificity. Autoantibodies to putative TSH receptor proteins in thyroid particulate membranes were detected in approximately 35% of sera from patients with Graves' disease. However, despite modifications to increase immunoblotting sensitivity and specificity, only a minority (less than 15%) of Graves' disease sera contained autoantibodies that identified epitopes within TSH affinity-purified human or porcine receptor proteins. In these sera there was no correlation between the TSH receptor antibody titre, determined by radioreceptor assay, and receptor epitope reactivity. The sensitivity of immunoblotting was limited by reduced transfer of purified receptor from the gel. However, in addition, the inability to immunoblot the purified receptor with a majority of Graves' sera, under conditions designed to enhance receptor renaturation, appears to reflect a strict conformational requirement for immunoreactivity. Immunoblotting of purified receptors therefore has a limited application in detecting, and defining the epitope reactivity of, TSH receptor autoantibodies.     

A study of human-human hybridomas from patients with autoimmune thyroid disease

Human-human B-cell hybridomas were established using peripheral blood lymphocytes from patients with autoimmune thyroiditis and Graves' disease. Peripheral mononuclear cells (PMC), with or without mitogen prestimulation, were fused with HGPRT-negative human myeloma cell lines (Gm4672 and Gm0462) using 44% polyethylene glycol. Developing hybridomas were screened by enzyme-linked immunosorbent assays (ELISAs) for human IgG and IgM and antibodies to human thyroglobulin (hTg) and microsomal antigen (M-Ag). A¹²⁵I-TSH binding inhibition assay was utilized for detecting antibodies to TSH receptor (TSH-R) protein. Hybridoma formation was observed only after prior mitogen stimulation of PMC. The amount of antibody secreted by the human-human hybridomas was highly variable (10 ng-100 µg/ml IgG/IgM). Nine and six-tenths percent of the hybrids secreted anti-hTg and 8.4% secreted anti-M-Ag. A 5% cloning efficiency was achieved, with detection of specific thyroid autoantibody secretion in one-third of the clones derived from positive hybridomas. Immunoglobulin secretion decreased with time and long-term stable clones were not achieved. Thyroid monoclonal autoantibodies to hTg, M-Ag, and TSH-R (IgG and IgM) detected during these studies were of a low affinity. In addition, antibodies were identified which exhibited marked specificity crossover between hTg, M-Ag, and nonthyroid antigens, suggesting the presence of recurrent epitopes. Such observations may help explain the multiplicity of thyroid autoantibodies in human thyroid disease and indicate a common defect in immunoregulation. We suggest that cross-reacting epitopes may be important in the derivation of thyroid-specific B-cell clones.     

Determination and clinical significance of anti-idiotypic antibody--in model experiments of thyroglobulin and TSH]

Anti-idiotypic (anti-ID) antibody in test serum was determined by the direct binding assay using 125I-anti-human thyroglobulin (hTg). Several positive cases were found in Graves' disease and thyroiditis chronica. Positive anti-ID antibodies could be classified into two types. Type 1 showed the positive anti-hTg antibody and high Tg levels by RIA using double antibody method. Type 2 showed the positive anti-hTg antibody but low Tg levels by RIA. The binding of 125I-hTg to anti-hTg antibody was displaced by anti-ID antibody in type 1, but was not anti-ID antibody in type 2. A case of coexistence of autoantibody to hTSH and auto-anti-ID antibody to anti-hTSH antibody was found. She showed normal thyroid function (T4, T3), but TSH level showed discrepancy by different assay methods. Both autoantibodies for hTSH and for anti-hTSH antibody were demonstrated by the reaction of patient's antibody with both 125I-hTSH and 125I-anti-hTSH (MoAb). These two autoantibodies belong to the polyclonal IgG. The autoantibody for hTSH recognized only the beta-subunit of hTSH. Neither stimulating type of TSH receptor antibody (TRAb) nor blocking type of TRAb interfered with the binding of patient's anti-ID to 125I-anti-hTSH. This binding reaction could be inhibited by the unlabeled hTSH. This anti-ID might represent the internal image of the non-biological active site of TSH molecule, because of absence of thyroid stimulating activity. These anti-ID antibodies may provide evidence supporting a network theory of the immune system.     

Immunology of the thyrotropin receptor.

Antibodies to the thyrotropin receptor appear to be responsible for hyperthyroidism in Graves' disease. The antibodies, described as thyroid-stimulating antibodies (TSAb) mimic the effects of thyrotropin (TSH) by binding to the TSH receptor and activating adenylate cyclase. TSAb consist of an electrophoretically heterogeneous population of IgG and the thyroid-stimulating site is formed by combination of heavy and light chains in the Fab part of the molecule. Binding studies indicate that the TSAb molecule interacts monovalently with membrane bound TSH receptors and that TSAb consists of an antibody population which shows a restricted heterogeneity with regard to TSH receptor affinity. Studies in patients with Graves' disease and hyperthyroidism indicate that the levels of TSAb correlate well with thyroidal iodine uptake and the absence of pituitary control of thyroid function. However in some patients with ophthalmic Graves' disease or autoimmune thyroiditis there is evidence of serum antibodies which interact with the TSH receptor but are unable to stimulate thyroid function.     

Current topics on immunological laboratory tests-thyroid diseases

Current topics in the field of thyroid disease are the development of the second generation assay for TSH receptor antibody (TRAb) using recombinant human TSH receptor and the appearance of antineutrophil cytoplasmic antibodies(ANCA) in Graves' disease patients treated with propylthiouracil(PTU). This new TRAb assay is very useful, since the sensitivity and the specificity were almost 100%, respectively, in the diagnosis of Graves' disease. Furthermore, a new coated tube assay for the detection of blocking TRAb has been developed by using TSH/LH receptor chimera. The prevalence of ANCA is high in Graves' disease patients treated with PTU, but the clinical significance of ANCA is under controversy, since only a part of them develop vasculitis, and recently it has been reported that ANCA is frequently positive in Graves' disease patients before the onset of methimazole treatment. The 7th version of guidelines for the diagnosis of thyroid disease have been prepared by the Japan Thyroid Association, and opens to public inspection. They show the importance of immunological laboratory tests in this field.     

Heterogeneity of thyroid autoantigens identified by immunoblotting

Autoimmune thyroid disease in man is commonly associated with autoantibodies against thyroglobulin, microsomes, and the TSH receptor, and the character and specificity of these antithyroid antibodies have been extensively utilized in investigating these conditions. In the present study we have asked whether other thyroid-related antigens exist, against which autoantibodies may be directed. A crude thyroid extract was separated by polyacrylamide gel electrophoresis followed by immunoblotting with serum obtained from patients with Graves' disease or Hashimoto's thyroiditis. Antibodies in sera from patients with Graves' disease and Hashimoto's thyroiditis reacted with many antigenic determinants in immunoblots of the thyroid membrane preparation (2000g supernatant). These determinants were disease specific in that sera from normals and patients with Addison's disease and rheumatoid arthritis did not react, but there was no difference between the patterns of reactivity with Graves' disease or Hashimoto's thyroiditis sera. Thyroglobulin produced two predominant bands of reactivity at 320 and 200 kDa, whereas purified microsomal antigen produced a triplet of bands around 105 kDa, when these preparations were reacted with appropriate autoimmune sera. Nonetheless, some sera produced additional bands with the microsomal antigen blots, indicating that some of the antigens which were detected using crude thyroid membrane remained in the microsome preparation to produce multiple antibody binding reactivities. We were unable to inhibit any of the antibody binding with TSH. Purification of individual thyroid antigens on the basis of their molecular weights should standardize current antibody assays and permit more detailed evaluation of the cellular immune responses in Graves' disease and Hashimoto's thyroiditis.     

Binding of bovine and porcine pituitary glycoprotein hormone alpha-subunit to TSH antibody in serum of patients with Graves' disease.

The characteristics of autoantibodies reactive with bovine (b) TSH were examined in the sera of six patients with Graves' disease selected on the basis of highly negative values in the TSH receptor assay. Test sera were incubated with other 125I-labeled pituitary glycoprotein hormones and their isolated subunits (alpha and beta) [human (h) TSH, bTSH, porcine (p) TSH, pFSH, bFSH, bLH and equine (e) chorionic gonadotropin (CG)] (purity was confirmed by gel-filtration on Sephadex G-100 and SDS-PAGE), and the antibody bound fraction was precipitated by the addition of anti-human gamma-globulin (goat). Almost all sera showed detectable binding to bTSH, pTSH, pFSH, pTSH-alpha, bFSH-alpha, bLH-alpha, but not to hTSH, hTSH-alpha, hTSH-beta, hFSH, hLH, hCG, pTSH-beta, bLH-beta, eCG-alpha. Exceptions were very low binding to bLH-beta by one serum and to pTSH-beta, by two sera. The level of binding (B/T%) of the patients' sera to pTSH-alpha, bFSH-alpha and bLH-alpha was 3.0-27.7%, 2.6-45.3% and 2.2-39.0%, respectively; that of sera from normal healthy adults was 1.9 +/- 0.3%, 0.8 +/- 0.2% and 0.9 +/- 0.2% (mean +/- SD), respectively. These results indicate that the TSH antibodies recognize mainly an epitope in the alpha subunit of bovine and porcine pituitary glycoprotein hormones (TSH, FSH, LH).     

Unaltered thyroid function in mice responding to a highly immunogenic thyrotropin receptor: implications for the establishment of a mouse model for Graves' disease.

Grave's disease (GD) is a common disorder characterized by the presence of autoantibodies to the thyrotropin receptor. In the past, the exceedingly low expression of the thyrotropin receptor on thyrocytes has not allowed its purification in quantities sufficient to investigate the establishment of an animal model for this disease. In this study, we have purified the 398-amino acid, extracellular region of the human thyrotropin receptor (TSH-R.E) from insect cells using recombinant baculovirus, and explored its immunopathogenic properties in H-2b,d,q,k,s strains of mice. The receptor preparation was highly immunogenic since it elicited strong specific proliferative T cell responses as well as IgG responses in all strains tested. In addition, hyperimmunization with TSH-R.E induced (i) serum antibodies that blocked the binding of 125I-TSH to its receptor, a common feature of GD autoantibodies; and (ii) IgG that reacted with a synthetic peptide (residues 32-54) from the N-terminus of the receptor, a region implicated in the binding of thyroid stimulating antibodies. In SJL animals only, a weak antibody response to two other thyroid antigens, thyroglobulin and thyroid peroxidase, was also observed. The presence of these antibodies, however, was not accompanied by a detectable alteration in thyroid function as assessed by the measurement of serum TSH, T4 and iodine levels. Also mononuclear infiltration of the thyroid gland or morphological changes compatible with an activation state of thyrocytes were not apparent in TSH-R-challenged mice. In contrast, mice treated with the anti-oxidant aminotriazole showed a dramatic increase in serum TSH levels and an activated follicular epithelium. These data demonstrate that a highly immunogenic TSH-R.E in mice does not necessarily provide a proper stimulus for the induction of a hyper- or hypothyroid status as defined by hormonal or histological criteria. Main reasons for the inability to induce receptor-specific antibodies that affect thyroid function such as those generated in GD are likely to be the inappropriate folding of the recombinant extracellular domain of the receptor, or the xenogeneic nature of the autoantigen.     

Secretor status and infection in patients with Graves' disease

We have demonstrated that the inability to secrete the water soluble glycoprotein form of the ABO blood group antigens into saliva is significantly more common in patients with Graves' disease than control subjects (40% vs 27%: P less than 0.025) but not among those with Hashimoto's thyroiditis or spontaneous primary atrophic hypothyroidism. Non-secretion is associated with increased susceptibility to infection and to asymptomatic carriage of some microorganisms. Although Yersinia enterocolitica has been found to express antigen cross reactive with the TSH receptor, we did not find an increased prevalence of Yersinia species in the faeces of 107 patients with Graves' disease. The isolation rate (less than 1%) was similar to that observed in the local population with diarrhoeal illness. Salivary IgA levels determined by whole cell ELISA with Y. enterocolitica 03 were not elevated in the majority of specimens examined. The results suggest that in contrast to reports from Scandinavia, there is no strong evidence that yersiniae play a role in the pathogenesis of Graves' disease among patients in South east Scotland. Non-secretors are significantly over represented among patients with several other autoimmune diseases; however, with the exception of antitubulin antibodies, non-secretors with Graves' disease did not have more antibodies to other human antigens than secretor patients.     

Adenovirus encoding the thyrotropin receptor A-subunit improves the efficacy of dendritic cell-induced Graves' hyperthyroidism in mice

Stimulating the immune system by in vivo expression of the thyrotropin receptor (TSHR) is an efficient means to induce Graves' disease experimentally. For example, BALB/c mice injected with dendritic cells (DCs) infected with adenovirus encoding the full-length TSHR (AdTSHR) develop hyperthyroidism, albeit at a low incidence (36%). Recent observations suggest that the shed TSHR A-subunit, rather than the full-length receptor, is the autoantigen responsible for initiating/enhancing immune responses leading to thyroid stimulating antibodies (TSAb) and hyperthyroidism. Therefore, we attempted to improve the efficacy of the DC-based approach for Graves' disease using adenovirus encoding the TSHR A-subunit (AdTSHR289). Three injections of DCs infected with AdTSHR289 induced hyperthyroidism in 70% of BALB/c mice, approximately twice the disease induction rate with AdTSHR. TSAb activity was detected in most hyperthyroid mice, whereas virtually all immunized mice developed antibodies that inhibit [125I]TSH binding to the TSHR or recognize linear or conformational epitopes on the TSHR. TSHR antibodies were of IgG1 and IgG2a, indicating mixed T-helper type 1 (Th1)/Th2 immune responses. In conclusion, immunization with DC infected with adenovirus expressing the TSHR A-subunit is a highly efficient protocol to induce Graves' hyperthyroidism in BALB/c mice. This improved model will permit studies of the pathogenic role and therapeutic potential of DCs in Graves' hyperthyroidism.     

Immunological of the Thyrotropin Receptor

Antibodies to the thyrotropin receptor appear to he responsible for hyperthyroidism in Graves disease. The antibodies, described as thyroid-stimulating antibodies (TSAb) mimic the effects of thyrotropin (TSH) by binding to the TSH receptor and activating adenylate cyclase. TSAb consist of an electrophoretically heterogeneous population of IgG and the thyroid-stimulating site is formed by combination of heavy and light chains in the Fab part of the molecule. Binding studies indicate that the TSAb molecule interacts monovalently with membrane bound TSH receptors and that TSAb consists of an antibody population which shows a restricted heterogeneity with regard to TSH receptor affinity. Studies in patients with Graves disease and hyperthyroidism indicate that the levels of TSAb correlate well with thyroidal iodine uptake and the absence of pituitary control of thyroid function. However in some patients with ophthalmic Graves' disease or autoimmune thyroiditis there is evidence of serum antibodies which interact with the TSH receptor but are unable to stimulate thyroid function.     

Thyroid function tests

About 80% of thyroid disease consists of thyroid-specific autoimmune diseases, Hashimoto's disease and Grave's disease. To diagnose thyroid diseases, testings for (1) thyroid function and (2) pathogenetic autoantibodies are indispensable. To assess thyroid function, serum hormone concentrations, such as TSH, FT4 and FT3 are measured. Among these hormones, serum TSH concentrations are the most reliable and informative regarding thyroid function, correcting indicating a hyperthyroid, euthyroid or hypothyroid state. Therefore, TSH measurement appears to be the first choice in selecting the hormone determination. Reference intervals for normal healthy subjects of TSH are around 0.4-5.0 microU/ml. The second choice for thyroid function assessment are FT4 which supersedes total T4(TT4). TT4 is affected by changes in serum thyroid hormone binding proteins(TBG, TTR, Albumin). For example, euthyroid pregnant women whose serum TBG are physiologically higher than those of non-pregnant women show augmentation of TT4. However, FT4 depicts within reference intervals, although measurement of FT4 alone is unable to detect any abnormality of thyroid hormone binding proteins. According to its plasma concentration and binding affinity, FT3 measurement deserves no more significance than T3. Another important test for thyroid diseases is to detect serum autoantibodies against thyroid tissues, such as TgAb, TPOAb. Much more important is TSH receptor antibody which differentiates Graves' disease from Hashimoto's thyroiditis. In patients who show hyperthyroidism and some very uncommon hypothyroidism, TSH receptor antibodies should be measured. Three indicators are available as routine tests; TRAb measured by radioreceptor assay; TSAb determined by bioassay using cultured porcine thyroid cells. Usually, TRAb activity clinically correlates well with TSAb. TSBAb was initially discovered in patients with severe hypothyroidism with atrophic thyroid gland. TSBAb blocks thyroid stimulating activity of TSH and consequently causes severe hypothyroidism. TRAb and TSAb are very useful to diagnose and follow patients with Grave's disease.     

Thyroid-stimulating hormone receptor and its role in Graves' disease

The thyroid-stimulating hormone (TSH, or thyrotropin) receptor (TSHR) mediates the activating action of TSH to the thyroid gland, resulting in the growth and proliferation of thyrocytes and thyroid hormone production. In Graves' disease, thyroid-stimulating autoantibodies can mimic TSH action and stimulate thyroid cells. This leads to hyperthyroidism and abnormal overproduction of thyroid hormone. TSHR-antibodies-binding epitopes on the receptor molecule are well studied. Mechanism of TSHR-autoantibodies production is more or less clear but a susceptibility gene, which is linked to their production, is still unknown. Genetic studies show no linkage between the TSHR gene and Graves' disease. Among three common polymorphisms in the TSHR gene, only the D727E germline polymorphism in the cytoplasmic tail of the receptor showed an association with the disease, and this association is weak. The absence of a strong genetic effect of the TSHR polymorphisms in such a common and complex disorder as Graves' disease may be explained by a high degree of evolutionary conservation in TSHR. This can be shown by naturally existing germline and somatic mutations in the TSHR gene that cause various types of nonautoimmune and hereditary thyroid disease.     

Characterization of a recombinant Yersinia enterocolitica lipoprotein; implications for its role in autoimmune response against thyrotropin receptor

Autoimmune Graves' disease (GD), which is characterized by hyperthyroidism, is mediated by autoantibodies to the thyrotropin receptor (TSHR). Yersinia enterocolitica (Y.e.) has been shown to produce a lipoprotein (LP) that can cross-react with the TSHR and thus can act as a potential trigger of thyroid autoimmunity. In this study, to further characterize LP, we cloned the LP gene from Y. enterocolitica and expressed a recombinant LP. This recombinant LP was mitogenic for C3H/HeJ (LPS hyporesponsive) B cells and induced production and secretion of significant levels of IL-6 from splenocytes. A mouse antibody generated against the recombinant LP cross-reacted with TSHR as shown by western blot analysis. FACS analysis of splenocytes from mice immunized with LP revealed that LP could induce increased expression of B7.1 and B7.2. The immunomodulatory effects of LP including up-regulation of B7.1 and B7.2 coupled with its ability to induce antibodies that can cross-react with the TSHR showed several potential mechanisms by which it can cause breakdown of self-tolerance to TSHR.     

Inverse correlation between activated T cells and TSH receptor antibodies in Graves' disease

TSH receptor antibodies and peripheral blood lymphocyte subsets have been measured in fourteen patients with untreated Graves' thyrotoxicosis. CD8 (suppressor) cells were reduced (p less than 0.01) and helper/suppressor cell ratio was increased in Graves' patients. Increased levels of 4F2 positive (activated) T cells were found in the patients compared to controls (p less than 0.001) and there was a negative correlation between 4F2 positive cells and TSH receptor antibodies (TBII). It may be possible, with multiple immunological markers, to identify different stages in the pathogenesis of autoimmune thyroid disease.     

An anti-idiotypic antibody against Graves' IgG

Rabbit antibodies were raised against Graves' IgG adsorbed onto a TSH-receptor affinity and eluted thereof by [3H]NaCl. The rabbit serum absorbed against normal human IgG (ARI) still bound to Graves', control and Hashimoto's IgG preparations but in the latter two, binding was inhibited by bTSH (10 mU/ml). In addition, ARI stimulated thyroid cell cyclic AMP accumulation in both human and rat thyroid cells. The ARI preparation may, therefore, contain an "internal image" anti-idiotype causing thyroid (Ab2) stimulation, a Graves' disease specific anti-idiotype whose binding with Ab2 inhibits its ability to bind TSH and anti-anti-idiotype (Ab3) to "internal image" Ab2. In further studies, Graves' specific cross-reactive idiotype was found in 10/11 IgGs from patients with active Graves' disease. This study emphasizes the workings of Jerne's immunologic network and the complexity of polyclonal "anti-idiotypic" antibodies.