ANTI-TSH ANTIBODY WITH HIGH SPECIFICITY TO HUMAN TSH IN SERA FROM A PATIENT WITH GRAVES'' DISEASE: ITS ISOLATION FROM, AND INTERACTION WITH, TSH RECEPTOR ANTIBODIES

A patient with thyrotoxic Graves' disease had an apparent measurable level of serum TSH (2.5 microU/ml) by double-antibody radioimmunoassay (RIA). The serum IgG bound with both [125I]human(h)TSH and [125I]bovine(b)TSH. The [125I]hTSH binding was more effectively displaced by human than bovine TSH, whereas [125I]bTSH binding was displaced exclusively by bTSH. Scatchard analyses revealed that [125I]hTSH binding showed two components, whereas [125I]bTSH binding had only one component. Serum TSH determined by RIA became undetectable 21 months after antithyroid drug treatment with a parallel decrease of [125I]hTSH binding IgG activity. Four thyrotrophin binding inhibitory immunoglobulins (TBII) from other patients did not interfere with the binding of the patient's serum to [125I]h- or bTSH. Furthermore, the in-vitro thyroid stimulating activities of three thyroid stimulating antibodies (TSAb) were not affected by the addition of this patient's IgG. On the other hand, this patient's Ig (3 mg/ml) abolished the in-vitro thyroid stimulation by bTSH (100 microU/ml), but did not affect that by hTSH (100 microU/ml). The anti-hTSH antibody, TSH receptor antibody and anti-bTSH antibody in the serum, which contains TSAb as well as anti-TSH antibodies, could be partially purified by hTSH-agarose and subsequently by guinea pig fat cell membrane affinity absorptions. However, the anti-hTSH antibody fraction obtained had both hTSH binding activity and thyroid stimulating activity, and this fraction did not show any inhibitory effect on the in-vitro thyroid stimulation of autologous TSH receptor antibody or hTSH. The possible significance of anti-TSH antibodies is discussed.     

A sensitive and precise radioimmunoassay for human thyroid-stimulating hormone.

A high-sensitivity radioimmunoassay for human thyroid-stimulating hormone (hTSH) has been developed utilizing a highly specific rabbit antibody (developed by AFP) to hTSH with an affinity constant of 4.4 x 10(11) M-1. Optimal conditions which minimized both 125I-hTSH radiation damage and 125I dissociation included storage at -60 C in 0.25% albumin. Repetitive freezing and thawing did not cause loss of structural integrity or of full immunochemical reactivity of 125I-hTSH. Effects of human and calf sera on the precipitation of first antibody-bound 125I-hTSH by second antibody have been tabulated; the addition of TSH-free human serum to the standard curve is necessary to compensate for the serum effect. The minimum detectable amount of TSH in the new assay at a 1:1,000,000 final dilution of the hTSH antibody is 0.02 muU/tube. The mean normal hTSH value of 1.5 +/- 1.0 muU/ml (mean +/- SD) fell within the central one-third of the logit (B/Bo) plot where antigen concentrations are measured with highest precision. This assay gives good precision and reproducibility of measurements throughout the normal range of serum TSH concentrations.     

Interference with thyrotropin receptor antibody determination by a spuriously occurring anti-bovine TSH antibody

Abnormally negative values of thyrotropin binding inhibitor immunoglobulin (TBII) were found in the sera from a patient with Graves' disease. This was due to the presence of potent bovine TSH (bTSH) binding activity in the sera. This activity was demonstrated to be in immunoglobulin G (IgG) with a lambda light chain isotype, which was shown to have an affinity for bTSH with a Ka value of 3.5 X 10(10) M-1 and a maximum binding capacity of 1.1 X 10(-14) M/mg IgG. F(ab')2 fragments obtained through pepsin digestion from the patient's IgG retained bTSH binding activity. [125I] bTSH binding to this IgG was inhibited by the TSH receptor. The inhibition was not completely competitive, suggesting the presence of different binding sites for this IgG and the TSH receptor on the TSH molecule. This IgG, however, could not bind labelled human TSH (hTSH). Since neither TSH nor other pituitary derivatives had ever been given to the patient, this bTSH binding activity was considered to be due to a spuriously occurring anti-bTSH antibody.     

Estimation of serum TSH receptor autoantibody concentration and affinity.

We have used the human monoclonal TSH receptor (TSHR) autoantibody (M22) as a labeled ligand in competition with individual patient TSHR autoantibodies (TRAb) to estimate their serum concentrations and affinities. TSHR coated tubes, (125)I-labeled M22 IgG and Fab, and patient sera IgG and Fab were used in these studies. In 15 patients with Graves' disease, TRAb concentrations ranged from 50 to 500 ng/mL of serum (5- 60 parts per million of total serum IgG) and TRAb IgG affinities from 3.0 +/- 1.0-6.7 +/- 1.54-10(10) L/mol (mean +/- SD; n=3). Fab fragment affinities were similar to those of intact IgG. Serum TRAb with blocking (TSH antagonist; 4 patients) activity had similar affinities (3.0 +/- 0.25-7.2 +/- 2.2-10(10) L/mol) to TRAb IgG from patients with Graves' disease, but blocking TRAb concentrations were higher (1.7 - 27 mg/mL of serum). The concentrations of TRAb that we observed in the sera of the 15 Graves' patient (0.33 - 3.3 nmol/L) can be compared with that of circulating TSH. In particular, a serum TSH concentration of 100mU/L (0.7 nmol/L) is in the same range as the concentrations of TRAb we observed. Such a TSH concentration (similar to that observed after injection of 0.9 mg of recombinant human TSH) would be expected to cause a similar degree of thyrotoxicosis as seen in Graves' disease. Consequently, the thyroid-stimulating potencies (i.e., activity per mol) of patient serum TRAb and human TSH appear to be of a similar magnitude in vivo as well as in vitro. Overall, our results indicate that serum TRAb affinities are high and show only limited variations between different sera whereas concentrations of the autoantibodies vary widely.     

Demonstration of anti-TSH antibody in TSH binding inhibitory immunoglobulin-positive sera of patients with Graves' disease

OBJECTIVES: The presence of anti-TSH antibodies in Graves' patients with unusually low TSH binding inhibitory immunoglobulin (TBII) has been reported. Recently, we found the first case of an anti-TSH antibody in TBII-positive sera of patients with Graves' disease. The prevalence and immunological specificity of this anti-TSH antibody were examined. DESIGN: The presence of 125I-bovine(b) TSH binding antibody in TBII positive serum was examined by prolonged incubation of more than 1 day because only weak binding occurred after 1 h incubation at 37 degrees C. The clinical course of these patients and binding characteristics of anti-bTSH antibody were examined. RESULTS: The corrected method-TBII activity (%)[1 - (a - b)/(c - d)] x 100 and the standard method-TBII activity (%) [1 - (a - d)/(c - d)] x 100 [a, 125I-bTSH binding with TSH receptor (R) in the presence of test serum; b, 125I-bTSH binding with test serum; c, 125I-bTSH binding with TSH R in the presence of normal serum; d, 125I-bTSH binding with normal serum] were calculated. The corrected method-TBII activity was always higher than the standard method-TBII activity in anti-bTSH antibody-positive serum. Anti-bTSH antibody-positive cases in TBII-positive Graves' disease were found in approximately 1% of Graves' patients. Anti-bTSH antibodies were confirmed as IgG from the increase of precipitated radioactivity by adding rabbit antihuman IgG antibody after the incubation of 125I-bTSH with test serum. These antibodies bind with not only bTSH, bTSH(alpha) and bLH, but also porcine (p)TSH, pTSH(alpha) and pFSH. However, these antibodies did not bind with human TSH. Binding of 125I-bTSH with patient's serum was neither inhibited by other Graves' thyroid stimulating antibody (TSAb), nor thyroid blocking antibody (TBAb) in primary hypothyroidism. CONCLUSIONS: The presence of anti-bTSH antibody in TBII-positive serum of high titre means that TBII-positive sera cannot rule out the absence of anti-bTSH. Thus, determination of 125I-bTSH binding with test serum in TSH receptor assays is necessary to determine the precise TBII activity and to detect anti-bTSH antibody.     

Differences in TSH receptor binding and thyroid-stimulating properties between TSH and Graves' IgG. Slowly-acting TSH receptor antibody moieties in Graves' sera affect assay data

We analyzed TSH receptor (TSHR) effects, both binding and thyroid-stimulation, of TSH and Graves' IgG. A new TRAb assay system utilizes rhTSHR coated tubes and is comprised of two step incubation, the first incubation with patient serum followed by a second incubation with 125I-bTSH. We called TRAb measured by this method as hTRAb. 125I-bTSH binding capacity of the tube was found close to saturation at 1 hr with 200 microl of 125I-bTSH. Up to 5 hr of first incubation for hTRAb assay revealed significant increases in all hTRAb activities. hTRAb was not affected by second incubation time or dose of 125I-bTSH. When 1 step incubation with 125I-bTSH and Graves' serum was performed, hTRAb again increased significantly with time. A simple competitive equilibrium model could not be applied to these ligands. Second, Graves' IgG and bTSH were compared for in vitro thyroid-stimulation sequentially up to 24 hr, measuring cAMP generation from cultured porcine thyrocytes. While bTSH yielded peak cAMP generation by 8 hr, TSAb revealed more cAMP generation by 24 hr than at 8 hr. We concluded that individual Graves' sera contain heterogeneous TRAb of variable avidities, and that slow-acting TRAb, which may lack biological activity, can be detected by prolonged incubation.     

Plasma immunoreactive TSH: spurious elevation due to antibodies to bovine TSH which cross-react with human TSH

A patient with thyroid carcinoma treated by thyroidectomy who received multiple injections of bovine (bTSH) exhibited elevated and nonsuppressible levels of plasma "immunoreactive TSH." Antibodies to TSH of the IgG class which bound bTSH and human TSH (hTSH) were demonstrated using specific radioimmunoassay and radioimmunoelectrophoretic techniques. Antibodies were present for more than one year and binding of bTSH was greater than that of hTSH throughout this period. Characterization of the antibodies with respect to the binding of human and bovine glycoprotein hormones and subunits revealed two populations of antibodies, one of which bound both bTSH and hTSH and the other which bound only bTSH. Both antibodies appeared to be directed toward antigenic sites on the beta subunit of TSH as both hTSH-beta and bTSH-beta displaced the binding of intact TSH from antibodies whereas the alpha subunits were virtually unreactive. The binding studies suggest that the cross-reactivity of the antibody to hTSH occurred on the basis of common antigenic determinants on the beta subunits of the two species. Documentation of a true elevation of plasma hTSH was achieved by gel filtration of plasma in which a peak of immunoreactivity co-eluting with [125I]-hTSH could be shown. Evidence for suppression of TSH secretion by thyroxine administration in the presence of interfering antibody was obtained by demonstrating that the level of plasma "immunoreactive TSH" did not change in response to TRH administration.     

Carbohydrate-dependent epitope mapping of human thyrotropin.

To probe possible effects of carbohydrate chains in the conformation of pituitary glycoprotein hormones, two radiolabeled derivatives of human thyroid-stimulating hormone (hTSH), either partially deglycosylated in the beta-subunit or fully deglycosylated in both the alpha- and beta-subunits, were compared to the native hormone for binding to monoclonal as well as polyclonal antibodies. Monoclonal antibodies were screened for their ability to bind the intact hormone (anti-hTSH), hTSH and its free alpha-subunit (anti-alpha) or its free beta-subunit (anti-beta). A panel of 14 monoclonal antibodies directed against at least eight out of the 12 epitopes known to be present in the hormone was tested in solid-phase assays for their capacity to bind intact and deglycosylated forms of hTSH. All of them displayed identical recognition of native and partially deglycosylated 125I-hTSH. In contrast, binding of fully deglycosylated 125I-hTSH to anti-hTSH and anti-beta antibodies was dramatically lost while that of anti-alpha was preserved. This clearly indicates that most of the epitopes specific for subunit association as well as those present on the beta-subunit are glycosylation dependent. No alteration was found in antibody recognition following deglycosylation of free individual subunits, indicating that the carbohydrate effect can only occur in the combined dimer. Using polyclonal antisera raised against the International Reference Preparations, we found that the deglycosylated hormone could be bound by the anti-beta antiserum although at a much lower dilution than the native antigen, suggesting the presence of at least one glycosylation-independent epitope in the beta-subunit. Competitive binding assays revealed that deglycosylated hTSH is 5 times less immunoreactive toward the anti-beta compared to the anti-alpha antiserum. The current data thus demonstrate the presence of the glycosylation-independent epitopes in the alpha-subunit of hTSH and the localization of most of the glycosylation-dependent domains in the beta-subunit.     

Affinity purification and diagnostic use of TSH receptor autoantibodies from human serum

Purification of TSH receptor autoantibodies (TRAb) from the serum of patients with Graves' disease (GD) might help to elucidate the nature of these disease causing autoantibodies. We describe here for the first time the successful affinity purification of human TRAb.Affinity purification was performed in a four step procedure with human recombinant TSH receptor (TSH-R) expressed in K562 cells. Purification from six different serum pools from patients with GD and two individual sera (one with only thyroid stimulating antibodies (TSAb) one with only thyroid blocking antibodies (TBAb)) resulted in a purity of 39.2+/-3.8 IU/mg TRAb or 25.7+/-2.1 microg IgG/IU (about 3.5-13.7 microg TRAb/ml serum). The average enrichment based on the respective original serum was 3420-fold (range 1200-10,000). The kDa of the purified TRAb were in the range of 0.7-2.6 x 10(-10)M. All purified TRAb (except from the TBAb serum which showed blocking activity) showed a more than 1000-fold stronger stimulation in the TSAb bioassay based on the IgG content than the original serum, and similar stimulation based on international units (IU/l) TRAb. When labelled purified TRAb were used in a competitive assay as tracer instead of bovine TSH, their binding to the human recombinant TSH-R on tubes was displaced by 99 of 100 GD sera (selected for TBII activity). Correlation to the standard TSH tracer was r=0.92. Interestingly, the use of TRAb tracer derived from a patient with TSAb and a patient with TBAb gave virtually identical results (r=0.93) with these patients, suggesting similar if not identical binding sites for both TRAb subtypes.In conclusion, this is the first report on the purification of human TRAb from the serum of patients with GD. The purified TRAb are of low concentration with high affinity, strong TBII and TSAb activity. Further characterisation may allow new insights in TRAb epitope localisation, the pathology of GD and the differences between TSAb and TBAb. Also, their use as tracer in a competitive assay is the first report on a completely homogenous assay with high sensitivity for TSH-R autoantibodies.     

Characteristics of a monoclonal antibody to the thyrotropin receptor that acts as a powerful thyroid-stimulating autoantibody antagonist.

Analysis of nine mouse monoclonal antibodies (mAbs) to the thyrotropin receptor (TSHR) with TSH antagonist activity showed that only one of the mAbs (RSR B2) was an effective antagonist of the human thyroid stimulating autoantibody M22. Crystals of B2 Fab were analyzed by x-ray diffraction and a crystal structure at 3.3 A resolution was obtained. The surface charge and topography of the B2 antigen binding site were markedly different from those of the thyroid-stimulating mAb M22 and these differences might contribute to the different properties of the two mAbs. B2 (but not other mouse TSHR-specific mAbs) was also an effective antagonist of thyroid stimulating autoantibody activity in 14 of 14 different sera from patients with Graves' disease. 125I-labeled B2 bound to the TSHR with high affinity (2 x 10(10) L/mol) and patient serum TSHR autoantibodies inhibited labeled B2 binding to the receptor in a similar way to inhibition of labeled TSH binding (r = 0.75; n = 20). Furthermore, labeled B2 binding was inhibited by patient serum TSHR autoantibodies with TSH antagonist activity and also by mouse and human thyroid stimulating mAbs. Overall, mAb B2 is a powerful antagonist of thyroid stimulating autoantibodies (and TSH) thus resembling closely patient serum TSH antagonist TSHR autoantibodies. Furthermore, B2 might have potentially important in vivo applications when tissues containing the TSHR (including those in the orbit) need to be made unresponsive to stimulating autoantibodies.     

Continued suppression of serum TSH level may be attributed to TSH receptor antibody activity as well as the severity of thyrotoxicosis and the time to recovery of thyroid hormone in treated euthyroid Graves' patients.

The cause of continued suppression of serum thyroid-stimulating hormone (TSH) levels during antithyroid drug therapy in some Graves' patients is unclear. Recently, there has been a notable explanation involving the direct inhibition of TSH receptor antibody (TRAb) on TSH secretion in the pituitary gland. The purpose of this study is to verify the relation between TRAb or other clinical parameters and the continued suppression of serum TSH level during antithyroid drug therapy in patients with Graves' disease. We reviewed the medical records of patients with Graves' disease between 1995 and 2002 at Samsung Medical Center. We selected 167 Graves' patients who had been euthyroid for at least 12 months after recovery of serum T3 and T4 levels during the antithyroid drug therapy. We analyzed the correlation of the interval until recovery of serum TSH with the pretreatment clinical parameters. We compared the recovery rates of suppressed TSH levels between pretreatment thyrotrophin-binding inhibitory immunoglobulin (TBII)-positive (>15%) and TBII-negative patients. We also compared the clinical parameters between two groups at the time of diagnosis and after recovery of thyroid hormone. Pretreatment serum T3 level, (131)I uptake, TBII activity, and the time to recovery of T3 or T4/free T4 level showed significant positive correlations with the interval until recovery of serum TSH level ( p < 0.05). Recovery rates of serum TSH levels at 3 months after recovery of thyroid hormone were significantly lower in pretreatment TBII-positive patients than those in TBII-negative patients ( p < 0.01). Serum TSH levels were significantly lower in TBII-positive patients at 3 months after recovery of thyroid hormone ( p < 0.05). TBII activities inversely correlated only with serum TSH levels at 3months after recovery of thyroid hormone ( p < 0.001). In conclusion, continued suppression of serum TSH level may be attributed to TRAb activity as well as the pretreatment severity of thyrotoxicosis and the time to recovery of thyroid hormone in patients with Graves' disease during antithyroid drug therapy.     

Triiodothyronine(T3) autoantibodies in a woman with nonthyroidal disorder: a study on preparation of serum IgG fraction employing protein A column chromatography

A 48-year-old non-goitrous woman, who had undergone cardiac surgery for mitral stenosis under the extracorporeal circulation, showed high levels of serum T3 and free T3 in a recent follow-up study, employing antibody coated-bead RIA for T3 and -Amerlex M particle RIA for free T3. However, other thyroid function tests (T4, free T4, TSH and TBG) were normal. We suspected that thyroid hormone autoantibodies (THAA) in her serum interfered with T3 and free T3 analyses. The presence of THAA was demonstrated by the use of various procedures as follows. Firstly, the patient's serum was directly incubated with 125I-T3 or -T4 analog which did not bind to TBG, followed by B/F separation with polyethyleneglycol, counting the precipitates. Secondly, after the serum was treated with an acid-charcoal solution to remove circulating thyroid hormone, the measurement of THAA was made as stated above. Normal sera were used as controls. Both the non- and acid-charcoal-treated sera showed much higher percentages of 125I-T3 analog precipitation as compared with controls. In the case of 125I-T4 analog, there was no difference between them. In the third study, the presence of IgG antibodies that bound T3 but not T4 was investigated. The IgG fraction of the patient's serum was separated employing a Protein A-Sepharose CL-4B column chromatography. Then, the prepared IgG fraction was purified by a technique of gel filtration chromatography (Sephacryl S 200). Non-purified and purified-IgG fractions both revealed higher binding percentages of 125I-T3 analog than the control IgG fraction and non-IgG fraction of the patient. Furthermore, a good dose response was observed between the binding percentage of 125I-T3 analog and each dose of the patient's serum or IgG fraction. From these observations, it was clarified that this woman had anti-T3 IgG autoantibodies using a Protein A column chromatography with confirmation of gel filtration chromatography.     

Growth stimulating antibody, as another predisposing factor of Graves' disease (GD): analysis using monoclonal TSH receptor antibodies derived from patients with GD

TSH receptor antibody (TRAb) is clinically classified into thyroid stimulating antibody (TSAb) and thyroid-stimulation blocking antibody (TSBAb). Although the former is considered to cause Graves' disease (GD), its activity does not necessarily reflect hormone production and goiter size. Moreover, uptake of 99mTcO4(-), the best indicator for GD, is correlated with activity of TSH binding inhibitor immunoglobulin better than activity of TSAb. Because uptake of 99mTcO4(-) reflects thyroid volume, these observations suggest that there exist TRAb with thyrocyte growth stimulating activity (GSA) other than TSAb. In this study, we analyzed GSA of monoclonal TRAb established from patients with GD or idiopathic myxedema (IME). GSA was measured as the degree of FRTL-5 cell growth stimulated by each TRAb. The signaling pathways of the cell growth were pharmacologically analyzed. The cell growth stimulated by TSH was strongly suppressed by protein kinase A (PKA) inhibitor, but was not affected by extracellular signal regulated kinase kinase (MEK) inhibitor. Although TSAb from GD stimulated the cell growth, both inhibitors suppressed it. Surprisingly, the cell growth was also induced by TSBAb from GD and was only suppressed by MEK inhibitor. TSBAb from IME did not have GSA and attenuated the cell growth stimulated by TSH. We concluded that 1; in GD, not only TSAb but some TSBAb could stimulate thyrocyte growth. 2; TSBAb might be classified with respect to their effects on thyrocyte growth; i.e., thyrocyte growth stimulating antibody and thyrocyte growth-stimulation blocking antibody.     

A case of thyrotropin-producing pituitary adenoma, accompanied by an increase in anti-thyrotropin receptor antibody after tumor resection

We describe a rare, but interesting, case of TSH-producing adenoma (TSHoma), accompanied by increases in both anti-TSH receptor antibody (TRAb) and thyroid-stimulating antibody (TSAb) after tumor resection. A 21-yr-old woman was referred to our department for further evaluation of pituitary tumor. In a nearby hospital, she had been diagnosed as having pituitary tumor. Her serum free T4, free T3, and TSH levels were all elevated concomitantly. On the basis of a diagnosis of pituitary adenoma with TSH production, transsphenoidal resection of the pituitary adenoma was performed. Two weeks after the operation, the blood concentrations of TSH were undetectable, whereas both TRAb and TSAb levels were elevated. TSAb levels gradually increased further from 2 weeks to 3 months after the operation, accompanied by an increase in TSH and free T4 levels. TSH is an important hormone in maintaining physiology and regulating immunomodulators in thyrocytes, as it can influence a variety of immune-regulating cytokine-like activities and inhibit expressions of Fas antigen, intracellular adhesion molecule-1, and class II trans-activator. Changes in TSH would modulate the immune circumstances in the thyroid, and then induce TRAb and TSAb. Autoimmune parameters with thyroid function should be observed carefully when managing patients with TSHoma.     

Fetal and neonatal hyperthyroidism and hypothyroidism due to maternal TSH receptor antibodies.

Autoimmune thyroid disease is a generic term that includes Graves' disease and Hashimoto's thyroiditis. In the former, there is overactivity of the thyroid due to the action of a thyroid-stimulating antibody (TSAb). Pathogenesis of Hashimoto's thyroiditis is largely cell-mediated immune destruction of the thyroid. Nonetheless, there may be either a goiter or an atrophic gland. There is evidence that in some patients the lack of goiter is associated with the presence in the blood of an antibody that inhibits the binding of TSH to its receptor. This TSH-binding inhibiting antibody (TBIAb), therefore, prevents TSH from stimulating the thyroid and constitutes an acceptable explanation for an agoitrous state. Collectively, TSAb and TBIAb, both of which are IgG, are known as TSH receptor antibodies (TRAb).     

Transient neonatal hypothyroidism: characterization of maternal antibodies to the thyrotropin receptor

Transient neonatal thyroid disease is known to occur as a result of transplacental passage of maternal immunoglobulin G (IgG) that contains antibodies to the TSH receptor (TRAb). Thyroid-stimulating antibody (TSAb) produces hyperthyroidism, and antibody that blocks TSH binding (TBIAb) results in hypothyroidism. We have analyzed in detail the IgG from four women who gave birth to children with transient neonatal hypothyroidism and have shown stimulating and inhibiting antibodies to coexist in three. Human and/or rat thyroid (FRTL5) cells were used to show stimulatory effects in vitro. Inhibition was assessed as prevention of stimulation of these cells (by TSH or TSAb) or by the blocking of binding of [125I] TSH to its receptor. The IgG from two mothers was tested to identify whether the inhibitory and stimulating bioactivities resided in molecules characterized by either or both kappa- or lambda-light chains. Evidence for restricted heterogeneity (implying oligoclonality) was obtained, in that with one, purely inhibitory IgG all activity was with IgG kappa. With the other, stimulating and inhibitory activities were predominantly in IgG kappa and IgG lambda, respectively. In addition, the latter IgG contained a second stimulator that was not suppressed by either its own or other inhibitory IgG. Despite the presence of stimulatory antibodies in these IgG, the clinical effect was neonatal hypothyroidism, reflecting the greater potency of the inhibitory IgG in all instances. Based on the histories of these four women and their offspring it is apparent that TRAb, and in particular TBIAb, can develop at any point in the course of autoimmune thyroid disease, i.e. either at the onset or long after the autoimmune process has been established.     

Characteristics of auto-antibodies to bovine TSH in the serum of two patients with Graves' disease

In this report we describe the characteristics of auto-antibodies to bovine TSH (bTSH) detected in the serum of 2 females among 102 patients with Graves' disease. These patients had never been injected with bTSH. One patient had high LATS activity and high bTSH binding activity after isotope therapy. The other patient showed no detectable LATS activity. Interestingly, the antibody showed a specifically high binding activity for the labelled TSH preparation purified by receptor. The auto-antibody could be demonstrated by the double antibody method, polyethylene glycol method, and by gel-filtration. The antibody was polyclonal immunoglobulin G (IgG). Because the binding of [125I]bTSH with the patient's antibody was inhibited by pituitary extracts from mammalian species other than human, this antibody may cross-react with bovine, rat, dog, rabbit and whale TSH. Although the incidence of the antibody in Graves' disease is low and the pathological significance remains obscure, the existence of this antibody in the serum of patients may suggest that autoimmune mechanisms may involve not only the thyroid but also the pituitary in Graves' disease.     

Suppression of serum TSH by Graves' Ig: evidence for a functional pituitary TSH receptor

Antithyroid treatment for Graves' hyperthyroidism restores euthyroidism clinically within 1-2 months, but it is well known that TSH levels can remain suppressed for many months despite normal free T(4) and T(3) levels. This has been attributed to a delayed recovery of the pituitary-thyroid axis. However, we recently showed that the pituitary contains a TSH receptor through which TSH secretion may be down-regulated via a paracrine feedback loop. In Graves' disease, TSH receptor autoantibodies may also bind this pituitary receptor, thus causing continued TSH suppression. This hypothesis was tested in a rat model. Rat thyroids were blocked by methimazole, and the animals were supplemented with L-T(4). They were then injected with purified human IgG from Graves' disease patients at two different titers or with IgG from a healthy control (thyroid hormone binding inhibitory Ig, 591, 127, and < 5 U/liter). Despite similar T(4) and T(3) levels, TSH levels were indeed lower in the animals treated with high TSH receptor autoantibodies containing IgGs; the 48-h mean TSH concentration (mean +/- SEM; n = 8) was 11.6 +/- 1.3 ng/ml compared with 16.2 +/- 0.9 ng/ml in the controls (P < 0.01). The intermediate strength TSH receptor autoantibody-treated animals had levels in between the other two groups (13.5 +/- 2.0 ng/ml). We conclude that TSH receptor autoantibodies can directly suppress TSH levels independently of circulating thyroid hormone levels, suggesting a functioning pituitary TSH receptor.     

The interaction of TSH receptor autoantibodies with 125I-labelled TSH receptor.

Detergent-solubilized porcine TSH receptor (TSHR) has been labeled with 125I using a monoclonal antibody to the C-terminal domain of the receptor. The ability of sera containing TSHR autoantibody to immunoprecipitate the labeled receptor was then investigated. Sera negative for TSHR autoantibody (as judged by assays based on inhibition of labeled TSH binding to detergent-solubilized porcine TSHR) immunoprecipitated about 4% of the labeled receptor, whereas sera with high levels of receptor autoantibody immunoprecipitated more than 25% of the labeled receptor. The ability to immunoprecipitate labeled TSHR correlated well with ability of the sera to inhibit labeled TSH binding to the receptor (r = 0.92; n = 63), and this is consistent with TSHR autoantibodies in these samples being directed principally to a region of the receptor closely related to the TSH binding site. Preincubation of labeled TSHR with unlabeled TSH before reaction with test sera inhibited the immunoprecipitation reaction, providing further evidence for a close relationship between the TSHR autoantibody binding site(s) and the TSH binding site. This was the case whether the sera had TSH agonist (i.e., thyroid stimulating) or TSH antagonist (i.e., blocking) activities, thus, providing no clear evidence for different regions of the TSHR being involved in forming the binding site(s) for TSHR autoantibodies with stimulating and with blocking activities. The ability of TSHR autoantibodies to stimulate cyclic AMP production in isolated porcine thyroid cells was compared with their ability to immunoprecipitate labeled porcine TSHR. A significant correlation was observed (r = 0.58; n = 50; P < 0.001) and the correlation was improved when stimulation of cyclic AMP production was compared with inhibition of labeled TSH binding to porcine TSHR (r = 0.76). Overall, our results indicate that TSHR autoantibodies bind principally to a region on the TSHR closely related to the TSH binding site, and this seems to be the case whether the autoantibodies act as TSH agonists or antagonists.     

Human recombinant TSH preceding a therapeutic dose of radioiodine for multinodular goiters has no significant effect in the surge of TSH-receptor and TPO antibodies.

Radioiodine (RAI) treatment has increasingly been used mostly in elderly patients with multinodular goiter (MNG) as an alternative for surgery. Recombinant human thyrotropin (rhTSH) has been demonstrated to increase the uptake of RAI and also to promote a more even distribution of radionuclide among the various nodules. We have compared the surge of autoantibodies to thyroid peroxidase (anti-TPO) and to the TSH receptor (TRAb) in two groups of patients with MNG. Group RAI (n = 15) received only RAI, and Group RAI+rhTSH (n = 15) received RAI 24 h after 0.45 mg of rhTSH intramuscularly. At baseline, all 30 patients had negative anti-TPO antibodies. After RAI, 16 patients (eight in each group) exhibited a positive anti-TPO test (range, 70-2359 U/mL). In the rhTSH-treated group, anti-TPO values were significantly higher (as compared to basal levels; p < 0.02) after 3 months of RAI treatment. After 12 months, the anti-TPO values decreased to lower but still positive concentrations in nine patients (Group RAI: three patients; Group RAI+rhTSH: five patients). Only one patient had a positive TRAb test at baseline (67.5% inhibition of the TSH binding). After RAI, positive TRAb values were present in 21/30 patients. After 6 months of RAI treatment, there was a significant increase of the TRAb values in Group RAI+rhTSH patients. After 12 months, only four patients had positive TRAb (Group RAI: three patients; Group RAI+rhTSH: one patient). Two patients, one of each group, had an elevation of free T4 levels and suppressed serum TSH values, indicating hyperthyroidism (Graves' disease). Bioassay of TSH receptor (TSHR) indicated absence of a significant elevation of cAMP in the medium before and after RAI treatment in all patients. Moreover, predominantly blocking TSHR autoantibodies were detected in six of the 30 patients (three of each group). Sera from these patients were able to reduce the TSH-stimulated cAMP generation by CHO cells. We conclude that the autoantibodies to the TSHR and to TPO may occur after RAI treatment of patients, either with or without previous stimulation by rhTSH. The antibodies to the TSH comprised a combination of agonist (stimulating) and antagonist (blocking) antibodies, which in most patients did not induce clinical and laboratory evidence of active Graves' disease.