The thyroid "microsomal" antigen is an epitope on the thyrotropin receptor

Antimicrosomal antibodies are present in the sera of most patients with autoimmune thyroiditis, and Graves' disease. It has, in general, been difficult to separate antimicrosomal activity from that directed against the thyrotropin (TSH) receptor in Graves' IgG preparations. The "microsomal" antigen has been localized to the endoplasmic reticulum and microfollicular aspect of thyrocytes; its structure is however unknown. In an attempt to identify the thyroid microsomal antigen, we studied the interaction of Hashimoto's IgG with high microsomal antibody titre and negative for thyroglobulin with purified thyroid plasma and light microsomal membranes. We allowed Hashimoto's, Graves', and control IgGs to bind to protein blots of thyroid plasma membranes resolved on SDS-PAGE under non-reducing conditions. All seven Hashimoto's IgG at a concentration of 2 mg/ml interacted with an M approximately 197,000 polypeptide corresponding to the TSH holoreceptor. By contrast to Graves' IgG (which were positive at 1 mg/ml), however, this binding was not blocked by pretreatment of the protein blots with TSH. Normal IgGs showed no binding at concentrations of up to 2 mg/ml. Both Hashimoto's and Graves' IgG interacted with TSH-affinity column-purified receptor preparations. Two of the Hashimoto's IgGs induced adenylate cyclase activation in thyroid plasma membranes, three inhibited TSH-stimulated enzyme activation, and two were without effect. Two classes of autoantibodies, other than TSH receptor directed, were encountered; one class raised to antigens common to all seven patients and another class unique to individual patients, eg, Mr 210,000 and Mr 20,000 polypeptides. We propose that the TSH receptor has multiple epitopes (functional domains), and the one to which antimicrosomal antibody bind is likely to be spatially separated from that with which Graves' IgG and TSH interact. Differences in affinity or number of sites allows for the demonstration of Graves' IgG against a background of antimicrosomal antibody.     

Characterization of the guinea pig adipocyte thyrotropin receptor

125I-TSH binding to porcine thyroid and guinea pig fat resulted in curvilinear Scatchard plots with similar dissociation constants for the high and low affinity binding components. Antibodies from the sera of patients with Graves' disease inhibited binding to the high and low affinity binding components of both tissues. Covalent cross-linking of 125I-TSH to membranes from each tissue resulted in the specific labeling of two protein bands. The guinea pig fat receptor subunits have Mr values of 52,000 and 38,000, whereas the porcine thyroid receptor subunits have values of 46,000 & 35,000. The labeling of the receptor subunits was inhibited by preincubation with Graves' autoantibodies. Despite possessing a different subunit composition, the receptors from these tissues exhibit similar affinity for TSH and share similar antigenic determinants for Graves' autoantibodies.     

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.     

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.     

A follow-up study of 85 patients with Graves' disease in remission who developed undetectable serum thyroid-stimulating hormone concentrations using sensitive TSH assays.

Eighty-five patients with Graves' disease in clinical remission after treatment for over 1 year by methimazole therapy (36 patients, group A) or subtotal thyroidectomy (49 patients, group B) who became undetectable for serum thyrotropin levels (TSH less than 0.05 mU/l), were further followed for 1 year or more. Eight patients in group A (22%) and 7 patients in group B (14%) relapsed. Eleven patients in group A (30%) and 5 patients in group B (10%) had fluctuating patterns of free T4 in the upper normal to slightly supranormal range indicative of subclinical hyperthyroidism. The remaining patients continued to have undetectable TSH levels or restored normal TSH levels and normal thyroid hormone concentrations in sera. The results of the present study indicate that the occurrence of undetectable serum TSH concentrations in Graves' disease patients previously treated with methimazole or surgery are not necessarily predictive of clinical relapse because the eventual outcome is variable.     

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.     

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.     

Thyroid autoantigens and their relevance in the pathogenesis of thyroid autoimmunity

Humoral and cellular immune responses are both involved in autoimmune disorders of the thyroid gland. In the last five years, new substantial data have been obtained on the nature and the expression of thyroid cell surface autoantigens and on the demonstration of the functional heterogeneity of autoantibodies to the thyroid stimulating hormone (TSH) receptor. In the present report, attention will be mainly focused on recent studies carried out in our laboratory. The main autoantigens so far identified include the 'microsomal' antigen, thyroglobulin and the TSH receptor. For many years the 'microsomal' antigen (M) was considered a poorly characterized constituent of the cytoplasm of the thyroid cell. In the last five years, several lines of evidence were provided indicating that M is also well represented on the surface of the follicular cell and is identical to thyroid peroxidase (TPO). The use of anti-TPO monoclonal antibodies, presently available, have confirmed this antigenic identity. Microsomal (anti-TPO) antibodies are very useful markers of autoimmune thyroid disorders and are generally present in Hashimoto's thyroiditis, idiopathic myxedema and Graves' disease. TSH receptor antibodies (TRAb) are present in the sera of patients with Graves' disease. TRAb are able to stimulate thyroid adenylate cyclase and also to mimic TSH in its thyroid growth stimulation. Thus, these antibodies may have a pathogenetic role in goiter formation and in thyroid hyperfunction in Graves' disease. TRAb were also shown to inhibit both TSH binding to its receptor and TSH-stimulated adenylate cyclase activity. Recently TRAb, which inhibited TSH-stimulated adenylate cyclase activity, were found in idiopathic myxedema patients and may be responsible for impairment of thyroid function.(ABSTRACT TRUNCATED AT 250 WORDS)     

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).     

Binding of immunoglobulin G from patients with autoimmune thyroid diseases to solubilized guinea pig fat cell membranes crosslinked with 125I-TSH

Binding of immunoglobulin G (IgG) to Triton-solubilized fat cell membranes crosslinked with 125I-TSH was studied by an indirect immunoprecipitation method. Guinea pig fat cell membranes (FCM) containing TSH receptors with an association constant of 1.92 X 10(9) M-1 were first reacted with 125I-TSH, then treated with a crosslinker, dissuccinimidyl suberate. The dissociation of 125I-TSH from the crosslinked 125I-TSH-FCM complexes due to the addition of 100 mU/ml unlabeled TSH was 9.0%, while it was 33% without the treatment. To the Triton-solubilized FCM crosslinked with 125I-TSH, 50 micrograms each of IgG from 20 normal controls, 20 patients with Graves' disease and 20 with Hashimoto's disease was added and precipitation was effected by adding anti-human IgG. In patients with Graves' disease, 125I-TSH-FCM complexes immunoprecipitated ranged from 1.10 to 4.18% with an average of 2.4 +/- 0.99 (S. D.) % which was significantly higher than those in normal controls (1.6 +/- 0.29%). The values in the patients with Hashimoto's disease averaged 1.7 +/- 0.53 (S. D.) which did not differ significantly from those of controls. The value did not correlate with either TSH-binding inhibiting activities or titers of anti-microsomal antibodies. These data suggest the presence of TSH-receptor antibodies which react with antigens other than TSH-binding sites in the patients with Graves' disease.     

Adipocyte-TSH-receptor-related antibodies in Graves' disease detected by immunoprecipitation

Fat cell TSH receptor-related antibodies were detected by immunoprecipitation of 125I-TSH-receptor complexes and the nature of the antibodies was analyzed. To 125I-TSH prebound to Triton-solubilized receptors from guinea pig fat tissues, 50 micrograms of immunoglobulin G (IgG) was added and precipitation was effected by the addition of antihuman IgG. Immunoprecipitation values in 13 patients with Graves' disease were significantly (p less than 0.05) higher than those in 11 normal subjects. No significant increase in the values was seen in 8 patients with Hashimoto's disease. No correlation was observed between immunoprecipitation values and titers of antimicrosomal and antithyroglobulin antibodies. Neither was there any correlation between the values and TSH-binding inhibitor immunoglobulins (TBII) detected by the radioreceptor assay. The IgG fractions positive for the immunoprecipitation antibody were found to be poor human thyroid stimulators (HTS) relative to their TBII activities. And a highly significant correlation was observed between TBII and HTS activities among IgGs without detectable antibody by immunoprecipitation (r=0.907; p less than 0.005; n=7). These findings 1) demonstrate that immunoprecipitation assay using fat cell TSH receptor may detect TSH receptor-related antibodies different from TBII in patients with Graves' disease and 2) suggest the antibodies may recognize determinants on the receptor or its vicinity that do not participate in the binding of TSH or thyroid stimulating antibody, and may interfere with thyroidal response to these stimulators.     

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.     

Possible binding site of thyrotropin binding inhibitor immunoglobulin (TBII) on the thyrotropin (TSH) receptor, which is different from TSH binding site

A synthetic decapeptide, P-194, which has the sequence No. 103 to 111 of hTSH receptor structure with an additional N-terminal tyrosine, did not bind TSH nor affected its receptor binding and thyroid stimulating activity. Preincubation of P-194 with sera from thyroid patients caused a significant decrease in TBII activity in almost all 12 TBII positive sera and an increase of thyroid stimulating activity in 3 of 7 Graves' IgG studied. In addition, [125I] P-194 bound to serum IgG fraction from thyroid patients with a positive correlation with TBII (N = 35, r = 0.509, p less than 0.01). The P-194 portion may be, at least a part of, TBII binding site distinct from the TSH binding site on the TSH receptor.     

Similar triiodothyronine releasing activity of thyroid stimulating antibodies in human and porcine thyroid slices

In an approach to addressing species specificity of thyroid stimulating antibodies (TSAb) stimulation of T3 release by Graves' sera was comparatively studied in human and porcine thyroid slices. A high sensitivity and specificity was found for the T3 bioassay independently on the use of human or porcine thyroid. Moreover, activity indices of the individual sera in both tissues were significantly correlated to each other and to circulating hormone levels in untreated disease. In conclusion, we suppose a lack of functionally relevant differences between target antigens, brought about probably by the TSH receptor itself and other membrane components, in human and porcine thyroid. Thus, for clinically applicable T3 releasing bioassay porcine thyroid may be alternatively used. In addition, this bioassay renders the advantage of reflecting the activity of disease.     

Covalent crosslinking of thyrotropin to thyroid plasma membrane receptors: subunit composition of the thyrotropin receptor

The subunit composition of the thyrotropin (TSH) receptor has been characterized using the bifunctional crosslinking agent, disuccinimidyl suberate (DSS), to covalently link [125I]TSH to its receptor. Purified thyroid membranes were labeled with [125I]TSH, and the hormone-receptor complex was crosslinked by incubation with 0.1 mM DSS. Analysis of this crosslinked complex by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) under reducing conditions indicated the presence of a specifically labeled hormone-receptor complex, corresponding to a Mr of 68,000 +/- 3000 before correction for the relative molecular mass of TSH. When reducing agents were absent during SDS solubilization, the mobility of the band increased slightly, suggesting the presence of intramolecular disulfide bonds. The labeling of the 68,000 band was specifically inhibited by TSH, but not by other glycoprotein hormones. Specific labeling occurred only in thyroid, and not in liver or muscle plasma membranes. Protease-free immunoglobulin G, isolated from sera of patients with Graves' disease and capable of competing with TSH for binding to its receptor, inhibited the labeling of the 68,000 complex. When the hormone-receptor complex was crosslinked with higher concentrations of DSS (greater than 0.3 mM), a second specifically labeled band was observed, with a Mr of 80,000 +/- 5000. This complex exhibited hormone, tissue, and immunologic specificities similar to those of the 68,000 band. Continuous sucrose density gradient analysis indicated that the intact solubilized receptor possessed a sedimentation coefficient of 10.5 S prior to correction for detergent binding. However, this value increased to 16 S when determined under conditions which took into account the change in hydrodynamic properties attributable to bound Triton X-100. These data suggest that the 80,000 and 68,000 bands represent binding components of the TSH receptor and that the receptor molecule most likely contains multiple subunits, linked by noncovalent forces.     

The Expression of Soluble, Full-Length, Recombinant Human TSH Receptor in a Prokaryotic System

For the first time soluble, full-length, recombinant, human thyroid-stimulating hormone (TSH) receptor (TSHR) has been expressed in a prokaryotic system. The full-length TSHR cDNA, obtained from normal human thyroid, was cloned into a pQE-9 vector, sequenced, and confirmed to be identical to the published sequence, to be full length, and to be in frame. Expression of the receptor was as a fusion protein with a hexahistidine tail at the amino terminal, in an Escherichia coli expression system. Approximately 2.5 mg of protein per liter of bacterial culture was recovered from the cell homogenate, after a single passage through a nickel-nitrilotriacetic acid resin column. An estimated 60% increase in purity of a band of expected size, 87 kDa, was observed upon gel electrophoresis and staining with Coomassie blue, after the single purification step. Immunoreactivity of the 87-kDa protein with Graves' sera was confirmed by Western blotting.     

Delineation of the discontinuous-conformational epitope of a monoclonal antibody displaying full in vitro and in vivo thyrotropin activity

An experimental murine model of Graves' disease was used to produce monoclonal antibodies (mAbs) with thyroid stimulating activity. Two of these, IRI-SAb2 and IRI-SAb3, showed particularly high potency (in the low nanomolar range) and efficacy. IRI-SAb2 behaved as a full agonist of the human TSH receptor (TSHr), even when tested in physiological salt concentrations. Both IRI-SAb2 and IRI-SAb3 were displaced from the TSHr by autoantibodies from patients with Graves' disease or harboring thyroid-blocking antibodies, but not from control subjects or patients with Hashimoto thyroiditis. The epitopes of IRI-SAb2 and IRI-SAb3 were precisely mapped, at the amino acid level, to the amino-terminal portion of the concave portion of the horseshoe structure of TSHr ectodomain. They overlap closely with each other and, surprisingly, with the epitope of a mAb with blocking activity. When injected iv in mice, both mAbs caused biological and histological signs of hyperthyroidism. Unexpectedly, they also triggered an inflammatory response in the thyroid glands. Delineation of the conformational epitopes of these stimulating antibodies opens the way to the identification of the molecular mechanisms implicated in the activation of the TSHr.     

The properties of proteoglycan prepared from human articular cartilage by using associative caesium chloride gradients of high and low starting densities.

Reduction of human thyroid membranes with dithiothreitol caused the release of a water-soluble glycoprotein which neutralized the thyrotropin (TSH) receptor-binding and thyroid-stimulating activities of Graves' serum. Analysis of the protein by gel filtration and sucrose density gradient centrifugation allowed estimates of 3.45 nm for the Stokes' radius, 3.6 S for the s20,w and 47 000 +/- 5000 (mean +/- S.D.; n = 4) for the Mr. The material released by dithiothreitol treatment could be crosslinked to 125I-labelled TSH coupled to N-hydroxysuccinimidyl 4-azidobenzoate (125I-HSAB-TSH), suggesting that it contained a component of the TSH receptor. Furthermore, analysis of the crosslinked material by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis indicated that it contained the TSH receptor A subunit (Mr 50 000). Several factors suggested therefore that the glycoprotein released by dithiothreitol treatment of human thyroid membranes was the TSH receptor A subunit. In particular, (a) both preparations were hydrophilic and were released from membranes by reduction, (b) they had similar Mr values and (c) both preparations crosslinked to 125I-HSAB-TSH. Material similar to the TSH receptor A subunit was released from thyroid membranes by treatment with papain, probably as a result of cleavage of the receptor A subunit at a site close to the interchain disulphide bridge. A similar mechanism, involving thyroid proteinases, was probably involved in release of material with similar properties to the TSH receptor A subunit during freezing and thawing of human thyroid homogenates.     

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.