Development of chicken antibodies toward the human thyrotropin receptor peptides and their bioactivities.

We have synthesized four peptides (P2, P4, E3 and P1) corresponding to different segments of human thyrotropin (TSH) receptor. We have obtained antibodies by immunizing them to chickens, and antibodies are evaluated for their thyroid stimulating antibody (TSAb), thyroid stimulation blocking antibody (TSBAb) and TSH-binding inhibitor immunoglobulin (TBII) activities. None of the antibodies had TSAb activity. Antibodies against human TSH receptor specific region such as P2 and P4 (P2: No. 372-397, P4: No. 341-358) had TSBAb and TBII activities. Anti-E3 antibody (E3: the third putative extracellular loop, No. 649-661) had only TSBAb activity. Anti-P1 antibody (P1: high homology with pig LH/CG receptor, No. 398-417), however, had none. These results suggest that anti-TSH receptor antibodies to different antigenic epitopes show heterogeneity in their biological activities.     

TSBAb (TSH-stimulation blocking antibody) and TSAb (thyroid stimulating antibody) in TSBAb-positive patients with hypothyroidism and Graves' patients with hyperthyroidism.

There are two types of TSH receptor antibodies (TRAb); thyroid stimulating antibody (TSAb) and TSH-stimulation blocking antibody (TSBAb). TSAb causes Graves' hyperthyroidism. TSBAb causes hypothyroidism. Both TSAb and TSBAb block TSH-binding to thyroid cells as TSH receptor antibodies (TRAb). TSBAb-positive patients with hypothyroidism and Graves' patients with hyperthyroidism may have both TSBAb and TSAb. We studied TSBAb and TSAb in 43 TSBAb-positive patients with hypothyroidism and in 55 untreated Graves' patients with hyperthyroidism. TSBAb-activities were expressed as percentage inhibition of bovine (b) TSH-stimulated cAMP production by test IgG. Two formulas were used to calculate TSBAb-activities; TSBAb-A (%) = [1 - (c - b)/(a - b)] x 100 and TSBAb-B (%) = [1 - (c - d)/(a - b)] x 100, where a: cAMP generated in the presence of normal IgG and bTSH, b: cAMP generated in the presence of normal IgG, c: cAMP generated in the presence of test IgG and bTSH, and d: cAMP generated in the presence of test IgG. TSAb (%) = [d/b] x 100. All of the 43 TSBAb-positive patients with hypothyroidism had strongly positive TSBAb-A and -B. Some of them had weakly positive TSAb (<240%). All 55 untreated Graves' patients had positive TSAb (205-2509%). Some of them had both TSAb and TSBAb. TSBAb-positive patients with hypothyroidism had a limited distribution of TSBAb- and TSAb-activities (TSBAb-A + 75 - + 103%, TSBAb-B + 87 - + 106%, TSAb 92-240%), but Graves' patients with hyperthyroidsim had a wide distribution of TSAb- and TSBAb-activities (TSAb 205-2509%, TSBAb-A - 158 - + 43%, TSBAb-B - 14 - + 164%). TSBAb-A ignores TSAb activity in serum, and might give low TSBAb activity. However, TSBAb-A clearly differentiates TSBAb-positive patients with hypothyroidism from Graves' patients with hyperthyroidism; thus, we favor TSBAb-A over TSBAb-B. Some of TSBAb-positive patients with hypothyroidism and Graves' patients with hyperthyroidism have both TSBAb and TSAb.     

Sensitive assay to detect thyroid stimulating antibody (TSAb) in the presence of thyroid stimulation blocking antibody (TSBAb) in serum.

The detection of thyroid stimulating antibody (TSAb) activity in the presence of thyroid stimulation blocking antibody (TSBAb) in Graves' serum is difficult because TSBAb blocks TSAb activity. We recently demonstrated that polyethylene glycol (PEG) augments TSAb activity in porcine thyroid cells (PTC) assay. This PEG-induced augmentation makes it possible to develop a sensitive assay to detect TSAb in the presence of TSBAb. We studied the effects of PEG on TSAb- and TSBAb-activities in PTC using 4 different preparations of the samples; (1) crude IgG using PEG 22.5% precipitated fraction (PF) from Graves' serum (0.2 ml), (2) crude IgG using PEG 12.5% PF, (3) serum (50 microl), and (4) serum (50 microl) in the presence of 5% PEG (final). When the effects of PEG on TSAb activity using crude IgG were examined, PEG 22.5% PF showed significantly higher TSAb activity than PEG 12.5% PF as reported previously. The augmentative effect of PEG on TSAb activity was also observed by the addition of 5% PEG to serum. We also demonstrated that PEG augmented TSAb-activities even in TSBAb-positive serum by two methods (crude IgG using PEG 22.5% PF and the addition of 5% PEG to serum). TSBAb activities were expressed by two calculation methods (A= [1 - (a - b)/(c - d) x 100] and B = [1 - (a - d)/(c - d) x 100], where a is cAMP produced in the presence of bTSH and patient's IgG, b is cAMP produced in the presence of patient's IgG, c is cAMP produced in the presence of bTSH and normal IgG, and d is cAMP produced in the presence of normal IgG). In the presence of TSAb, the values of A method were always higher than those of B method, since TSAb stimulated cAMP synthesis. We have developed two sensitive methods to detect TSAb even in the presence of TSBAb in serum using PEG; 1) incubation of crude IgG using PEG 22.5% PF from serum (0.2 ml), and 2) co-incubation of 5 % PEG with test serum (50 microl).     

Activity of thyroid stimulating antibody and thyroid stimulation blocking antibody determined by radioiodine uptake into FRTL-5 cells

To investigate the pathophysiology of patients with autoimmune thyroid diseases, we measured serum thyroid stimulating antibody (TSAb) activity and thyroid stimulation blocking antibody (TSBAb) activity by determining the radioiodine (125I) uptake into FRTL-5 cells. FRTL-5 cells were pre-incubated for seven days with 5H medium and then incubated for 48 hours with patients' crude IgG prepared by polyethylene glycol precipitation. In order to measure TSBAb, 10 microU/ml TSH was also added. 125I was added one hour before the end of the 48 hour incubation period. After the incubation, the medium was aspirated, and the radioactivity in the cells was counted. In patients with untreated hyperthyroid Graves' disease, TSAb was detectable in 18 of 20 patients, the detectability being 90%, and activity showed a statistically significant positive correlation with TSAb activity determined by c-AMP accumulation. Out of 41 patients with hypothyroidism, TSBAb determined by 125I uptake was positive in six cases, the detectability being 14.6%. The inhibition of 125I uptake by one of these six IgGs was suggested to be at the TSH receptor level because it inhibited TSH induced c-AMP accumulation and showed positive thyrotropin binding inhibitor immunoglobulin (TBI I) activity, but did not inhibit the forskolin- and (Bu)2cAMP-induced 125I uptake. Inhibition of another IgG was suggested at the post-receptor level because it did not inhibit TSH induced cAMP accumulation and showed negative TBI I activity, but inhibited forskolin- and (Bu)2cAMP-induced 125I uptake.(ABSTRACT TRUNCATED AT 250 WORDS)     

A case of Graves' disease and papillary thyroid carcinoma with predominant production of thyroid-stimulation-blocking antibodies (TSBAb) persisted after total thyroidectomy.

A 42-year-old female with Graves' disease and papillary thyroid carcinoma with lung metastasis was referred to our hospital. After treatment of thyrotoxicosis with methimazole and Lugol's solution, she underwent total thyroidectomy. She was then given 131I twice to treat lung metastasis. However, 131I uptake into the lung was not clear in the scintigram. Both thyroid-stimulating antibodies (TSAb) and thyroid-stimulation-blocking antibodies (TSBAb) were detected in her sera before and after the treatments. Compared with TSAb activities, TSBAb activities were extremely high. Changes in the titers of these two antibodies were not clear after total thyroidectomy. These results indicate that lymphocytes outside the thyroid gland are the major source of TSAb and TSBAb in this patient.     

Non-suppressed thyroidal radioactive iodine uptake (RAIU) in thyrotoxic phase in a case of subacute thyroiditis with thyroid-stimulating antibodies (TSAb).

In this paper, we report a 49-year-old female with subacute thyroiditis who had thyroid-stimulating antibodies (TSAb) and thyroid-stimulation-blocking antibodies (TSBAb) in serum. Although she was in the thyrotoxic phase and TSH was suppressed in May, 1990, her radioactive iodine uptake (RAIU) was not suppressed (35.5%) and a thyroid scan disclosed a diffuse goiter with no defect. Serum assays revealed the presence of TSAb, but TSBAb were negative. In August, 1990, the right lobe became undetectable by thyroid scan when the RAIU was 20.7% with the TSH level remaining suppressed. At that time, TSAb were negative, while TSBAb were positive. When the RAIU was 31.1% in October, 1990, both thyroid lobes became visible and the TSH level was normalized. TSBAb became negative, and although TSAb reappeared it later became undetectable. These results indicate that the changes in the patient's thyroid scan and RAIU were attributable to the presence of TSAb.     

Biological activities of rabbit antibodies against synthetic human thyrotropin receptor peptides representing thyrotropin binding regions.

Recently, we have shown that the thyrotropin (TSH) binding regions of human thyrotropin receptor (TSHR) reside in two areas within residues 12-44 and 308-344. Serial antisera were raised against four overlapping synthetic peptides representing these two regions of TSHR (peptides 12-30, 24-44, 308-328, and 324-344) and were investigated for their ability to stimulate or block the cultured porcine thyroid cells. In addition, serum concentrations of triiodothyronine (T3) and thyroxine (T4) in serial sera obtained from each rabbit were examined. It was shown that residues of 12-30 and 324-344 of TSHR, respectively, are the site (at least a part of the site) where stimulating (TSAb) and blocking type (TSBAb) immunoglobulins are directed.     

Clinical usefulness of TSAb assay with high polyethylene glycol concentrations.

We previously demonstrated the stimulatory effect of polyethylene glycol (PEG) on thyroid-stimulating antibody (TSAb)-IgG-stimulated cAMP production (thyroid stimulating (TS) index) in porcine thyroid cell (PTC) assay. In the present study the clinical usefulness of the practical method using high PEG concentrations was examined. TS activity using PEG 22.5% precipitated fraction (PF) was significantly higher compared to standard TSAb activity using 12.5% PF from TSAb-positive serum, but the maximum TS activity was observed with PEG 12.5% PF + 4% PEG or PEG 22.5% PF + 2% PEG. In all cases of untreated Graves' patients, TSAb activity determined by PEG 22.5% PF was higher compared to standard TSAb activity using PEG 12. 5% PF from test serum, but the highest TSAb activity was observed by PEG 12.5% PF + 4% PEG without increased cAMP production to normal serum. TSAb was positive in 85% (40/47), 98% (46/47) and 100% (47/47) of untreated Graves' patients by the method of PEG 12.5% PF, PEG 22.5% PF and PEG 12.5% + 4% PEG, respectively. Increased TSAb activity by PEG 12.5% PF + 4% PEG method was also observed even if the standard TSAb activity using PEG 12.5% PF method was negative in the euthyroid states of Graves' patients during antithyroid drug therapy. The stimulatory effect of PEG on TS activity was not found in other thyroidal diseases [thyroiditis chronica (with high serum TSH), thyroid stimulation-blocking antibody (TSBAb)-positive sera (with low serum TSH), adenomatous goiter, subacute thyroiditis, and thyroid cancer]. The stimulatory effect of 5% PEG on TS activity produced directly by small amounts of Graves' serum (50 microl) was also found, although the sensitivity was lower than with PEG-precipitated IgG from 0.2 ml serum. The clinical usefulness of the sensitive TSAb assay using PEG-precipitated IgG or direct serum assay in the presence of high PEG concentrations was demonstrated.     

Site-directed mutagenesis of a portion of the extracellular domain of the rat thyrotropin receptor important in autoimmune thyroid disease and nonhomologous with gonadotropin receptors. Relationship of functional and immunogenic domains.

Residues 287 to 404 of the rat thyrotropin (TSH) receptor exhibit little homology to gonadotropin receptors. A large segment of this region, residues 303-382, has no determinants important for TSH to bind or elevate cAMP levels nor for the activity of thyroid-stimulating autoantibodies (TSAbs) from the sera of Graves' patients, i.e. deletions, substitutions, or mutations in this segment do not result in a loss of any of these activities in transfected Cos-7 cells. Critical residues for these activities do, however, flank both sides of this segment. Of particular interest, deletion or mutation of residues 299-301 and 387-395 results in a marked decrease in high affinity TSH binding but preserves the ability of a TSAb to increase cAMP levels. Tyrosine 385 is also of particular interest since its mutation to phenylalanine, alanine, threonine, or glutamine results in a receptor with a 20-fold decrease in the ability of TSH to bind or increase cAMP levels, but one whose TSAb activity is, once again, preserved. Because one activity is preserved, we can conclude that (a) the receptor must be fully integrated within the membrane of the cell without malfolding, (b) these sequences represent determinants involved in the high affinity TSH binding site, and (c) separate determinants exist for high affinity TSH binding and TSAb activity, consistent with the existence of autoantibodies in Graves' sera which inhibit TSH binding (TBIAbs) or which increase cAMP levels (TSAbs). Additionally, we show that a 16-mer peptide (residues 352-367), which reacts with the sera of greater than 80% of patients with Graves' disease, can induce the formation of antibodies to a peptide with no sequence homology, residues 377-397. This peptide flanks the region, residues 303-382, with no determinants important for TSH receptor binding or activity. As noted above, it contains residues involved in the high affinity TSH binding site but whose deletion or mutation has no effect on TSAb activity, i.e. residues which would appear to be required at an epitope important for TBIAb but not TSAb antibody activity.     

Role of N-terminal region of the thyrotropin (TSH) receptor in signal transduction for TSH or thyroid stimulating antibody.

To identify the site(s) on the thyrotropin (TSH) receptor that interacts with TSH or thyroid stimulating antibody (TSAb), we examined the effect of the synthetic TSH receptor peptide (termed N2 peptide, No. 35-50) on the cAMP accumulation induced by TSH or TSAb. Preincubation of bovine TSH with N2 peptide resulted in a significant and dose-dependent decrease in cAMP accumulation. This decrease was not observed when bovine TSH was preincubated with P1 peptide, which was used as a control (No. 398-417). In contrast, the N2 peptide did not affect TSAb activity in immunoglobulin fractions from three TSAb-positive patients with Graves' disease. P1 peptide also had no effect on TSAb activity. These results suggest that the N-terminal region of the TSH receptor is important for TSH action, and also that TSAb activity cannot be suppressed only by the application of the synthetic peptide corresponding to the N-terminal region.     

Identification of separate determinants on the thyrotropin receptor reactive with Graves' thyroid-stimulating antibodies and with thyroid-stimulating blocking antibodies in idiopathic myxedema: these determinants have no homologous sequence on gonadotropin receptors.

Deletions, substitutions, or mutations of the rat TSH receptor extracellular domain between residues 20 and 107 (all residue numbers are determined by counting from the methionine start site) have been made by site-directed mutagenesis of receptor cDNA. After transfection in Cos-7 cells, constructs were evaluated for their ability to bind [125I]TSH or respond to TSH and thyroid-stimulating antibodies (TSAbs) from Graves' patients in assays measuring cAMP levels of the transfected cells. Assay results were compared to results from Cos-7 cells transfected with wild-type receptor constructs or vector alone. We identify threonine-40 as a TSAb-specific site whose mutation to asparagine, but not alanine, reduces TSAb activity 10-fold, but only minimally affects TSH-increased cAMP levels. We show that thyroid-stimulating blocking antibodies (TSBAbs), which block TSH or TSAb activity and are found in hypothyroid patients with idiopathic myxedema, continue to inhibit TSH-stimulated cAMP levels when threonine-40 is mutated to asparagine or alanine, suggesting that TSBAbs interact with different TSH receptor epitopes than the TSAb autoantibodies in Graves' patients. This is confirmed by the demonstration that these TSBAbs interact with high affinity TSH-binding sites previously identified at tyrosine-385 or at residues 295-306 of the extracellular domain of the TSH receptor. This is evidenced by a loss in the ability of TSBAbs to inhibit TSAb activity when these residues are mutated or deleted, respectively. Since the TSAb and TSBAb epitopes are in regions of the extracellular domain of the TSH receptor that have no homology in gonadotropin receptors, these data explain at least in part the organ-specific nature of TSH receptor autoantibodies in autoimmune thyroid disease. Data are additionally provided which indicate that residues 30-37 and 42-45, which flank the TSAb epitope at threonine-40, appear to be ligand interaction sites more important for high affinity TSH binding than for the ability of TSH to increase cAMP levels and that cysteine-41 is critical for TSH receptor conformation and expression on the surface of the cell. Thus, despite unchanged maximal values for TSH-increased cAMP levels, substitution of residues 42-45 or deletion of residues 30-37 results in receptors, which, by comparison to wild-type constructs, exhibit significantly worsened Kd values for TSH binding than EC50 values for TSH- or TSAb-increased cAMP activity.(ABSTRACT TRUNCATED AT 400 WORDS)     

Rabbit antibodies toward extracellular loops of the membrane spanning region of human thyrotropin receptor possess thyroid stimulating activities.

We have synthesized three different peptides, E1 (amino acid residues 478-497), E2 (amino acid residues 561-580) and E3 (amino acid residues 649-652), corresponding to the first, the second and the third extracellular loops of the membrane spanning region of human thyrotropin receptor (TSH-R), respectively. We have produced rabbit antibodies toward these peptides and evaluated their thyroid stimulating antibody (TSAb) and TSH-binding inhibitor immunoglobulin (TBII) activities. Although only slight TSAb activity was observed in E1 antibodies, E2 and E3 antibodies possessed strong TSAb activities, the values of which were 1118% and 910%, respectively. None of these antibody had TBII activities. These results suggest that antibodies against the extracellular loops of the TSH-R can stimulate cAMP formation in thyroid cells and that these regions may be one of the candidates for the epitope against autoantibodies from patients with Graves' disease.     

Heterogeneous responses of recombinant human thyrotropin receptor to immunoglobulins from patients with Graves' disease.

Non-thyroid mammalian cells, CHO-K1 cells, stably expressing human thyrotropin receptor (CHO-TSH-R cells) were used for the assay of thyroid stimulating antibody (TSAb) activities of IgGs from 24 patients with Graves' disease and we compared them with the values obtained in porcine thyroid cells. A significant positive correlation was observed between the results given by CHO-TSH-R cells (hTSAb) and porcine thyrocytes (pTSAb) (r = 0.94, p less than 0.001). However, we found that hTSAb values of IgGs from 5 patients were extremely different from their hTSAb values. Four out of these 5 IgGs showed strong pTSAb activity but exhibited a weak or negative hTSAb activity. Conversely, one out of 5 autoantibodies was very strong for hTSAb but its pTSAb was low. These heterogeneous responses of recombinant hTSH-R to Graves' IgGs suggest that there exist different types of TSAb and also that the epitope(s) for TSAb may be different from case to case.     

Thyroid-stimulating antibody (TSAb) of Graves' disease

The current knowledge of thyroid-stimulating antibody (TSAb) and its significance in Graves' disease is reviewed under 4 headings. 1) Methods of assay; these are categorized as thyroid-stimulation or thyrotropin-receptor-modulation type methods. The latter are convenient but non-specific and the former are inconvenient but specific. The use of guinea pig fat cell membranes as a source of receptor for thyrotropin may improve the specificity of the thyrotropin-binding inhibition (TBI) system. 2) Immunochemistry of TSAb; evidence for the restricted heterogeneity, or oligoclonality, of the antibody as it occurs in some sera, viz. selected for the very high titer, includes a relatively constant pI on isoelectric focussing, restriction to IgG1 and having only lambda or k as the light chain. 3) Are antibodies other than TSAb pathogenic in hyperthyroidism? data are provided indicating the presence in one serum of an antibody that inhibits the action of TSAb in vitro. Clinically this novel antibody caused delayed onset of neonatal hyperthyroidism in 2 children. The prevalence of the antibody and its general clinical significance are unknown, but ways of testing for its presence are reviewed. 4) Clinical significance of the assay of TSAb; TSAb occurs in at least 90% of patients but should not be necessary for the diagnosis of Graves' disease. Its persistence at the end of a course of antithyroid drugs predicates relapse; a high level on first diagnosis may forecast such persistence and be an indication for ablative therapy for hyperthyroidism. A high level of TSAb in the third trimester of pregnancy is a reliable index of neonatal hyperthyroidism. It should be recognized that there is a marked tendency for TSAb values to fall throughout the course of pregnancy.     

Augmentative effect of polyethylene glycol, polyvinyl alcohol and dextran on thyroid-stimulating antibody stimulated cAMP production in FRTL-5 cells and CHO cells expressing human TSH receptor

Previously we reported the augmentative effect of nonionic hydrophilic polymers such as polyethylene glycol (PEG), polyvinyl alcohol (PVA) and dextran on thyroid-stimulating antibody (TSAb) activity in porcine thyroid cell assays. We examined whether a similar phenomenon occurs in FRTL-5 thyroid cells and CHO cells expressing the human (h) TSH receptor (CHO-hTSHR cells). As with porcine thyroid cells, PEG 22.5% precipitated crude IgG from serum of patients with Graves' disease, significantly increased cAMP production as compared with PEG 12.5% precipitated crude IgG in both FRTL-5 cells and CHO-hTSHR cells. PEG 5% augmented purified-TSAb-IgG-stimulated cAMP production in both cell assays. TSAb activities and positivity by the direct assay using whole serum (0.05 ml) in the presence of 5% PEG in untreated Graves' patients were significantly increased as compared with the absence of 5% PEG. The augmentative effects of PVA 10% or dextran T-70 10% on TSAb-IgG-stimulated cAMP production were also observed in both cell assays. PVA 10% did not augment TSH-stimulated cAMP production in spite of weak augmentation by dextran 10% in both cell assays. Lack of the augmentative effects of PEG 5%, PVA 10% and dextran 10% on cAMP produced by GTPgammaS, forskolin and pituitary adenylate cyclase activating polypeptide was observed in both cell assays. The augmentative effects of these polymers in both cell assays similar to porcine thyroid cells suggest that there is no apparent species specificity among human, porcine and rat thyroid cells as far as TSH receptor linked cAMP production in cell membranes existed.     

A case of Graves' disease with false hyperthyrotropinemia who developed silent thyroiditis.

We encountered a patient who developed silent thyroiditis during the course of Graves' disease. The diagnosis of silent thyroiditis was made on the basis of a low thyroidal 131I uptake, no response to the thyrotropin releasing hormone (TRH) test, and subsequent hypothyroidism despite the presence of high titers of thyrotropin (TSH) receptor antibody (TRAb) and thyroid stimulating antibody (TSAb). The patient, in addition, had a discrepancy between serum TSH and thyroid hormone values. This was due to the presence of interfering substances that react to mouse IgG in the sera since serum TSH levels were decreased in a dose dependent manner by the addition of increasing amounts of mouse IgG to the sera. It should therefore be noted that silent thyroiditis can develop in patients with Graves' disease. Furthermore, clinicians should be aware that two-site immunoassay kits that use mouse monoclonal antibodies are subject to interference by some substances, possibly antibodies which react to mouse IgG.     

A synthetic oligopeptide derived from human thyrotropin receptor sequence binds to Graves' immunoglobulin and inhibits thyroid stimulating antibody activity but lacks interactions with TSH.

An 11-residue oligopeptide, P-195, was synthesized to match human thyrotropin (TSH) receptor structure from No. 333 to 343 of amino acid sequence. Preincubation of 5 Graves' IgGs with P-195 up to 10 micrograms resulted in dose-dependent reductions of thyroid stimulating antibody (TSAb) activity. [125I] labeled P-195 was found to bind Graves' IgG. The bound radioactivity correlated significantly with their TSAb activity (N = 25, r = 0.587, p less than 0.01). A peptide having a completely reverse sequence as P-195 did not show such biological activity. The peptide did not affect TSH and thyrotropin binding inhibitor immunoglobulin (TBII) on their receptor binding nor biological activities. P-195 was concluded to have a part of TSAb binding sites.     

Changes in thyroglobulin release-stimulating activity (Tg-RSA) in immunoglobulin G from patients with Graves' disease during therapy with thionamide drug

We have reported previously a new method for detecting thyroglobulin release stimulating activity (Tg-RSA) by human thyroid monolayer cells in IgGs from Graves' patients. We report here changes in Tg-RSA in sera of patients during treatment with thionamide drug. Nineteen untreated patients had their Tg-RSA, TSAb, TBII and serum Tg concentration (STg) followed up. Before treatment, Tg-RSA and TSAb were positive in all 19 patients. Three of them were TBII negative. During treatment with thionamide, of 16 patients who had positive Tg-RSA, TSAb and TBII before treatment, 6 patients continued so during the period of observation. Of the remaining 10 patients, 8 became TBII negative. TSAb only was found negative in one patient and Tg-RSA only declined to negative in another patient. Three patients whose TBII was initially negative, were observed to be negative in all three indicators after treatment. STg was higher than normal in all patients before therapy and changes in Tg-RSA in almost all patients were parallel with those in STg during treatment. From the observation during treatment with thionamide, our results suggest that Tg-RSA in Graves' patients appears to have similar properties to TSAb.     

Immunoglobulins from Graves' disease patients interact with different sites on TSH receptor/LH-CG receptor chimeras than either TSH or immunoglobulins from idiopathic myxedema patients

To examine the identity of binding sites for thyrotropin (TSH) and thyroid stimulating antibodies (TSAbs) associated with Graves' disease, we constructed eight human TSH receptor/rat LH-CG receptor chimeras. Substitution of amino acid residues 8-165 of the TSH receptor with the corresponding LH-CG receptor segment (Mc1 + 2) results in a chimera which retains high affinity TSH binding and the cAMP response to TSH but loses both the cAMP response to Graves' IgG and Graves' IgG inhibition of TSH binding. Two of three IgGs from idiopathic myxedema patients which contain thyroid stimulation blocking antibodies (TSBAbs) still, however, react with this chimera. Chimeras which substitute residues 90-165 (Mc2) and 261-370 (Mc4) retain the ability to interact with TSH, Graves' IgG, and idiopathic myxedema IgG. The data thus suggest that residues 8-165 contain an epitope specific for TSAbs and that TSH receptor determinants important for the activities of TSAbs and TSH are not identical. Further, binding sites for TSBAbs in idiopathic myxedema may be different from receptor binding sites for both Graves' IgG TSAb as well as TSH and may be different in individual patients.     

Polyethylene glycol augments thyroid cAMP responses by fragments from protease-digested TSAb or TSBAb-IgG

In the previous reports, we have demonstrated (1) that polyethylene glycol (PEG)(5%) augmented TSAb (thyroid stimulating antibody)-stimulated cAMP responses of porcine thyroid cells, and (2) that fragments from papain-digested TSBAb (thyroid stimulation blocking antibody) could stimulate thyroid cAMP synthesis. Thus, we studied the effect of 5% PEG on cAMP responses stimulated by the protease-digested TSAb- or TSBAb-fragments. Stimulatory effect of 5% PEG on cAMP production by Fab fragment (Mr 50 KDa) and the retarded fraction (Mr 20 KDa) from the gel-filtration on Sephadex G-100 using papain-digested TSAb-IgG unbound to Protein A-Sepharose was observed. Similar stimulatory effect of 5% PEG on the second fraction (Fc with trace amounts of Fab) in the gel-filtration on Sephadex G-100 using papain digested TSAb-IgG bound to Protein A-Sepharose was observed. Stimulatory effect of PEG on the second fraction was derived from Fab fragment. PEG (5%) also showed stimulatory effect on cAMP production by F(ab')2 fragment (Mr 100 KDa) from the gel-filtration on Sephadex G-100 using pepsin-digested TSAb-IgG unbound to Protein A-Sepharose. PEG (5%) augmented cAMP responses by both Fab and the retarded fractions from the gel-filtration using papain-digested TSBAb-IgG unbound to Protein A when these fractions could stimulate cAMP synthesis. In conclusion, PEG (5%) augments cAMP responses stimulated by F(ab')2, Fab and the smaller molecular components (Mr 20 KDa) separated from protease-digested TSAb-IgG. PEG also augments cAMP responses stimulated by Fab and the smaller molecular components with thyroid stimulating activity separated from papain-digested TSBAb-IgG.