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).     

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.     

Relationship among thyrotropin (TSH), thyroid stimulating immunoglobulins, and results of triiodothyronine (T3) suppression test in patients with Graves' disease

To investigate the relationship between TSH and abnormal thyroid stimulator(s) in patients with hyperthyroid Graves' disease in whom normal thyroid hormone levels in the serum were maintained by antithyroid drug therapy and in patients with euthyroid Graves' disease, determinations were made of the TSH concentration, action of thyroid stimulating immunoglobulins (TSAb and TBII), and T3 suppression. Out of thirty-three patients with hyperthyroid Graves' disease, twelve patients with subnormal TSH levels were all non-suppressible according to the T3 suppression test results and the detectability of TSAb and/or TBII was as high as 75%. In three out of five patients with euthyroid Graves' disease, the serum TSH level was subnormal. All three showed non-suppressibility in the T3 suppression test and positive action of either TSAb or TBII. One of them became clinically thyrotoxic when the TSAb activity was further increased and TBII became positive, and was therefore diagnosed as having hyperthyroid Graves' disease. The present findings suggest that there are still abnormal thyroid stimulator(s) in patients with hyperthyroid Graves' disease who have low TSH, even if their thyroid hormone concentrations remain normal. Moreover, it is likely that some of the patients with euthyroid Graves' disease are actually in a state of subclinical hyperthyroidism because of the presence of abnormal thyroid stimulator(s).     

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.     

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.     

Interaction of thyroid-stimulating antibody with Graves' thyroid-stimulating hormone-binding antibody

OBJECTIVE: Evidence of anti-thyroid-stimulating hormone (TSH) antibody in Graves' serum has been reported. We found that extremely high Graves' anti-TSH antibodies neutralized other Graves' thyroid-stimulating antibody (TSAb) activity. METHOD: TSAb-IgG was affinity-purified by Sepharose-bound Graves' anti-TSH antibody (extremely high). RESULT: The thyroid-stimulating activity in affinity-purified TSAb-IgG increased about 4-5 times compared to that before purification. TSH-binding inhibitory immunoglobulin (TBII) activity in affinity-purified TSAb-IgG also increased using TSH receptor-coated tube assay. A similar increase of thyroid-stimulating activity accompanied with TBII activity was also observed in affinity-purified TSAb-IgG-F(ab')(2). CONCLUSION: This suggests the possibility that either TSAb may be an anti-idiotypic antibody against anti-TSH antibody or anti-TSH antibody may be an anti-idiotypic antibody against anti-TSH receptor antibody.     

Thyrotropin receptor non-mediated thyroid stimulating immunoglobulin in Graves' disease.

There exists a consensus that hyperthyroid Graves' disease is caused by thyrotropin receptor (TSH-R) autoantibodies. To test the possibility that the TSH-R is the sole antigen for thyroid stimulating antibodies (TSAb), we compared bioactivities of Graves' IgGs between non-thyroid mammalian cells transfected with human TSH-R cDNA and the reference thyroid bioassay. A Graves' IgG with TSH-binding inhibitor immunoglobulin (TBII) activity (89%) markedly stimulated cAMP formation in both CHO-K1 cells transfected with TSH-R cDNA (340 microU/ml of TSH equivalent) and rat thyroid cells, FRTL-5, (410 microU/ml of TSH equivalent). In contrast, a TBII negative (-1.5%) IgG from another patient with Graves' disease showed a strong thyroid stimulating activity (87 microU/ml of TSH equivalent) when FRTL-5 cells were used for the assay. But no stimulating activity was observed in this IgG when CHO-K1 cells transfected with TSH-R cDNA were used, suggesting a possible existence of TSH-R non-mediated thyroid stimulating immunoglobulin in some cases of Graves' disease.     

Similarity and dissimilarity between clinical and laboratory findings, especially anti-thyrotropin receptor antibody in ophthalmic Graves' disease without persistent hyperthyroidism and hyperthyroid Graves' disease

The aim of this study was to investigate thyroid states, significance of anti-TSH receptor antibodies and the clinical courses of patients with euthyroid Graves' ophthalmopathy. The clinical and laboratory finding of 30 patients with euthyroid Graves' ophthalmopathy were briefly as follows: 1) normal sized thyroid or small goiter; 2) negative or weakly positive thyrotropin binding inhibitor immunoglobulin (TBII); 3) normal thyroid [99 m-Tc] pertechnetate uptake; and 4) frequent observations of low serum TSH values. Besides TBII, thyroid stimulating antibody (TSAb) was measured under low salt and isotonic conditions using FRTL-5 rat thyroid cells. Both TBII and TSAb titers were lower in euthyroid Graves' ophthalmopathy than in hyperthyroid Graves' disease. Serum TSH levels frequently became low in patients considered as euthyroid upon the first examination as well as in Graves' patients in remission, reflecting preceding or mild hyperthyroidism. In follow-up studies, these patients with mildly elevated thyroid hormone levels and low TSH levels seldom reached a state of persistent hyperthyroidism, when TBII was negative or only weakly positive.     

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.     

Inhibition of TSH binding to chicken thyroid by some cases of LATS (long acting thyroid stimulator)

TSH receptor antibody (TRAb) activity using chicken thyroid receptor (c-TRAb) and porcine thyroid receptor (p-TRAb) was determined by the incubation of 125I-bovine TSH with each receptor. Both c-TRAb and p-TRAb activity in LATS positive and negative Graves' sera were compared. 15 out of 39 LATS positive sera and 4 out of 46 LATS negative sera had positive c-TRAb activity. On the other hand, all LATS positive sera and 33 out of 46 LATS negative sera had positive p-TRAb activity. No relationship between c-TRAb and p-TRAb activity was observed, and there was also no correlation between c-TRAb and LATS activity. Changes in c-TRAb, p-TRAb and LATS activity in the clinical course of patients with Graves' disease were examined. These activities were parallel in some cases, but in others they were not. A weak c-TRAb activity was observed in 4 out of 29 Hashimoto's disease, but all cases with thyroid cancer and subacute thyroiditis showed no activity. Sera with positive c-TRAb activity did not stimulate chicken thyroid in chick bioassay. These results suggest that some cases of TRAb in Graves' disease (mainly LATS) inhibit TSH binding to chicken thyroid receptor (non-mammalian species) in the same way as mammalian thyroid, but may not have any stimulatory action on thyroid hormone synthesis. It is interesting to note that TRAb including LATS have the similar effect on TSH receptor even in nonmammalian species.     

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)     

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.     

Onset of subacute aggravation of chronic thyroiditis followed immediately by transient hypothyroidism during antithyroid drug therapy for Graves' hyperthyroidism.

A 56-year-old man presented with clinical and biochemical hyperthyroidism with high thyroid 99mTc uptake, positive result for antimicrosomal antibody (MCHA; 1:8,100) and markedly high activities of thyrotropin-binding inhibitory immunoglobulin (TBII; 90.0%) and thyroid-stimulating antibody (TSAb; 2,400%). Fifty days after the initiation of antithyroid drug therapy, he developed a painful tender enlarged thyroid and an accelerated erythrocyte sedimentation rate (ESR), which were followed immediately by hypothyroidism with a transient increase in MCHA titer (peak; 1:218,700) despite of maintenance of high TBII and TSAb activities. Two and a half months after the recovery from hypothyroidism, recurrent hyperfunction was observed with further elevation of TSAb activity (4,643%). After about 2 weeks, recurrences of a painful tender enlarged thyroid and an accelerated ESR, which were followed by abrupt progression to hypothyroidism, were found. Specimens obtained when he had still slightly tender goiter after the first and second episodes of neck pain showed microscopically extremely extended interstitial fibrosis with collapsed follicles and moderate lymphocytic infiltration. Thyroid-stimulation-blocking antibody was not detected at either onset of hypothyroidism. Thus, it is possible that Graves' disease, subacute aggravation of chronic thyroiditis and hypothyroidism coexist in the same individual. In such patients, thyroid status may be determined by the degree of each of the stimulating factors (TSH, TSAb and/or unknown factors) and suppressive or destructive factors (humoral and/or cellular) and may be changed in a very short interval.     

Cryopreserved human thyroid tissue for TSAb determination: comparison with fresh tissue

A thyroid-stimulating antibody assay using human normal thyroid slices was performed for studying whether the cryopreservation technique produced a sensitive substrate for cyclic-AMP generation. Cryopreservation was carried out in sterile 15% glycerol 0.9% NaCl placed in a hexane-nitrogen bath at -196 degrees C and stored at -80 degrees C for 1-5 weeks. Dose-response curves for untreated Graves' hyperthyroid patients IgG and bovine TSH were similar using fresh and cryopreserved slices. Assay sensibility was 5 mU/ml TSH. A high correlation (r = 0.91; p less than 0.001; n = 41) was found for percentage of cyclic-AMP increase to b-TSH and Graves' IgG comparing both methods. Studying 19 Graves' hyperthyroid patients, positive results were found in 63 and 52% for fresh and cryopreserved slices respectively. The cryopreservation technique used in the study was efficient for TSAb determinations.     

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.     

Detection of the novel autoantibody (anti-UACA antibody) in patients with Graves' disease

Uveal autoantigen with coiled coil domains and ankyrin repeats (UACA) is an autoantigen in patients with panuveitis such as Vogt-Koyanagi-Harada disease. The prevalence of IgG anti-UACA antibodies in patients with uveitis is significantly higher than healthy controls, suggesting its potential role as an autoantigen. Originally, UACA was cloned from dog thyroid tissue following TSH stimulation. So, we presumed UACA could be a novel autoantigen in autoimmune thyroid diseases. We measured serum anti-UACA antibody titer using ELISA in patients with autoimmune thyroid diseases (Graves' disease, Hashimoto's thyroiditis, subacute thyroiditis, and silent thyroiditis). The prevalence of anti-UACA antibodies in Graves' disease group was significantly higher than that in healthy group (15% vs. 0%). Moreover, the prevalence of anti-UACA antibodies in Graves' ophthalmopathy was significantly higher than that in Graves' patients without ophthalmopathy (29% vs. 11%). Especially, 75% of severe ocular myopathy cases showed high UACA titer. Immunohistochemical analysis revealed that UACA protein is expressed in eye muscles as well as human thyroid follicular cells. Taken together, UACA is a novel candidate for eye muscle autoantigens in thyroid-associated ophthalmopathy.     

The prediction of thyroid function in infants born to mothers with chronic thyroiditis

To elucidate the relationship between the mother's TSH-receptor antibody activities and the status of thyroid dysfunction in their offspring, blood was taken from 5 mothers with chronic thyroiditis with potent thyrotropin (TSH)-receptor blocking activity, and the potency of TBII and TSBAb activity was assayed more quantitatively. In those mothers whose infants suffered from neonatal hypothyroidism, the 50% inhibition of binding of labeled TSH to its receptors was obtained at more than 30 to 50-fold dilution, while in those mothers whose infants had transiently increased TSH or were euthyroid, the titers were of less than 30-fold dilution. Similarly, in those mother whose infants suffered from neonatal hypothyroidism, the 50% inhibition of TSH-induced cAMP accumulation was obtained at approximately 400 to 3000-fold dilution, while in those mothers whose infants had transiently increased TSH or were euthyroid, the titers were of less than 50-fold dilution. On the other hand TBII activity was much less potent in serum from patients with Graves' disease. These results suggested that the titration of serum with dilution to obtain 50% inhibition of labelled TSH binding to its receptor may be the simplest way to predict thyroid dysfunction of the newborn infants born to mothers with chronic thyroiditis.     

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.     

Stimulation of iodine organification in porcine thyroid cells by thyroid stimulators

Several Graves' sera were simultaneously assessed in a bioassay based on the ability of porcine thyroid cells to organify 125I and in a radioreceptor assay for TSH receptor binding activity. Both assay systems were sensitive to 1 mcU/ml (final concentration) of unlabelled bovine TSH. Six Graves' sera were studied in detail over a wide (0-1.0 mcl sera) dose response range in repeat determinations. Two sera exhibited parallel binding and stimulating. However, two sera revealed significant inhibition of 125I-TSH binding prior to the demonstration of stimulation and the other two sera showed stimulatory capabilities before significant binding was evident. IgG was prepared from one serum by ammonium sulphate precipitation and chromatography on Sepharose 6B and then subjected to preparative isoelectric focusing. The isoelectric distribution of the two activities were found to be identical with major peaks of activity at pl=9.5 and pl=8.5. In summary: 1) each Graves' sera exhibits different dose-response curves with respect to binding and stimulation, 2) at certain concentrations of sera, only binding or stimulation were evident, 3) neither assay was consistently more sensitive for the presence of Graves' immunoglobulins, 4) for one Graves' sera, binding and stimulation could not be separated by isoelectric focusing. These studies would suggest each Graves' immunoglobulin has inherently different characteristics in its interaction with the TSH receptor.     

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.