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ABSTRACT

The association of HLA class I and class II antigens, particularly HLA-B8,DR3, with a variety of autoimmune diseases has been well documented. The C4A*Q0 (non-expressed C4A) allele which is in linkage disequilibrium with HLA-B8,DR3 has also been reported to be associated with systemic lupus erythematosus, insulin-dependent diabetes mellitus and Graves' disease. However, the number of studies has been limited by the requirement of family data for the assignment of the C4A*Q0 allele based on C4 protein typing. Recently, with the availability of a C4 cDNA probe, a C4A gene deletion associated with HLA-B8,DR3 has been reported in normal individuals. We have tried to resolve the problem of assigning the C4A*Q0 allele by using both phenotypic and genotypic approaches and have determined the significance of the C4A*Q0 allele in 80 unrelated patients with Graves' disease and in 50 normal control subjects. Our results demonstrate a strong association of the C4A*Q0 allele with Graves' disease (56 versus 26%; P< 0·002, relative risk=3·7) and in particular in association with HLA-B8 and/or DR3 (92 versus 70·6%; P<0·04) when compared with normal controls. All the C4A*Q0 alleles that were associated with HLA-B8 and/or DR3 were due to a C4A gene deletion. Of the C4A*Q0 alleles in Graves' disease, 94% (compared with 82% in the control group) could be detected by C4 DNA analysis using either TaqI or EcoRI restriction endonucleases. It is suggested that a combination of C4 protein typing with C4 DNA analysis is the best approach for the determination of the C4A*Q0 allele in unrelated individuals without access to family data.

ABSTRACT

Thyroid hormones are essential for the normal growth and development of many tissues. In the rat, hypothyroidism is associated with growth impairment, and hyperthyroidism with the development of a hypercatabolic state and skeletal muscle wasting but, paradoxically, cardiac hypertrophy. The mechanism by which thyroid hormone produces cardiac hypertrophy and myosin isoenzyme changes remains unclear. The role of IGF-I, an anabolic hormone with both paracrine and endocrine actions, in producing cardiac hypertrophy was investigated during this study in hyperthyroid, hypothyroid and control rats. A treated hypothyroid group was also included in order to assess the effect of acute normalization of thyroid function.

Body weight was significantly lower in the hyperthyroid (mean±s.e.m.; 535·5±24·9 g, P<0·05), hypothyroid (245·3±9·8 g, P<0·001) and treated hypothyroid (265·3±9·8 g, P<0·001) animals when compared with controls (618·5±28·6 g). Heart weight/body weight ratios were, however, significantly increased in the hyperthyroid (2·74 ± 0·11×10⁻³, P<0·01) and treated hypothyroid (2·87±0·07 ×10⁻³, P<0·001) animals when compared with controls (2·26±0·03 × 10⁻³). Serum IGF-I concentrations were similar in the control and hyperthyroid rats (0·91±0·07 vs 0·78±0·04 U/ml, P=0·26), but bioactivity was reduced by 70% in hyperthyroid serum, suggesting a circulating inhibitor of IGF. Serum IGF-I levels (0·12±0·03 U/ml, P<0·001) and bioactivity (0·12±0·04 U/ml, P<0·001) were significantly lower in the hypothyroid group. Liver IGF-I mRNA levels were not statistically different in the control and hyperthyroid animals, but were significantly reduced in the hypothyroid animals (P<0·05 vs control). Heart IGF-I mRNA levels were similar in the control and hypothyroid rats, but were significantly increased in the hyperthyroid and treated hypothyroid animals (increased by 32% in hyperthyroidism, P<0·05; increased by 57% in treated hypothyroidism, P<0·01). Cardiac IGF-I was significantly elevated in hyperthyroidism (0·16±0·01 U/mg heart tissue, P<0·01), was low in hypothyroidism (0·08±0·01 U/mg, P<0·01) and was normalized in the treated hypothyroid group (0·11 ± 0·01 U/mg vs control, 0·13±0·01 U/mg).

Low body mass during both hypothyroidism and hyperthyroidism is therefore associated with reduced systemic IGF bioactivity. In hypothyroidism there is a primary defect in the endocrine function of IGF-I, while in hyperthyroidism serum IGF bioactivity is reduced in the presence of normal endocrine production of this anabolic hormone. In contrast, the paracrine actions of IGF-I are increased in the heart during hyperthyroidism, and this hormone appears to play a part in the development of hyperthyroid cardiac hypertrophy.

ABSTRACT

Graves' disease is an autoimmune thyroid disease characterized by the presence of pathogenic autoantibodies to the TSH receptor (TSH-R). By using polymerase chain reaction, the extracellular region of the human TSH-R cDNA has been amplified and used to prepare recombinant TSH-R (extracellular) protein fused with glutathione-S-transferase (GST). Purification of the recombinant TSH-R (extracellular)-GST fusion protein was achieved by preparative gel electrophoresis in SDS or by preparative isoelectric focusing in urea. Following removal of SDS by detergent exchange or urea by dialysis, the purified recombinant receptor preparations were assessed for binding to the hormone or to autoantibodies from Graves' disease patients. The purified recombinant receptor preparations fail to show any binding to the hormone or autoantibodies either by inhibition of binding assays or by immunoblotting. The results imply that the correct folding and/or post-translational modifications of the polypeptide chain which are not achieved in recombinant proteins produced in Escherichia coli may be important for the binding of the hormone or Graves' disease autoantibodies to the TSH-R. The recombinant receptor prepared in this manner will be useful for immunological and cellular investigations in patients with Graves' disease.

ABSTRACT

Parathyroid hormone-related peptide (PTHrP) has been detected in fetal serum and amniotic fluid. Using a combination of immunocytochemistry and molecular biology we have detected the peptide and its mRNA in a variety of fetal tissues throughout gestation. Tissue-specific mRNA isoforms were observed, the pattern of hybridization of which changed throughout gestation. In addition, the intensity and pattern of immunocytochemical localization of the peptide was found to vary over the time-period studied (8∓30 weeks). PTHrP is expressed by a variety of tumours associated with the syndrome of humoral hypercalcaemia of malignancy and probably accounts for the hypercalcaemia by virtue of its limited amino acid homology with parathyroid hormone. These data demonstrate for the first time that PTHrP, a tumour-related peptide, is expressed during normal human fetal development, and suggest the possibility that it may function to regulate fetal calcium balance and growth in utero.

ABSTRACT

Murine monoclonal antibodies against human/rat corticotrophin-releasing factor-41 (CRF-41) were produced and characterized for use in the immunological and biological characterization of CRF-41. Spleen cells from BALB/c mice immunized with CRF-41 conjugated to bovine γ-globulin were fused with a BALB/c-derived non-secretor X-63 myeloma line. Hybridomas were selected for CRF antibody production by enzyme-linked immunosorbent assay, and positive hybridomas cloned twice. Three monoclonal antibodies were obtained (KCHMB001, KCHMB002 and KCHMB003) and characterized as IgG1, IgG1 and IgG2a isotypes respectively, with affinity constants for rat CRF-41 of 30, 53 and 34 nmol/l respectively. All three monoclonal antibodies recognize an epitope contained between residues 34 and 41 of the human/rat sequence. The antibodies were able to neutralize the ACTH-releasing activity of rat CRF-41, applied to rat pituitary fragments in vitro, in a dose-dependent manner. Isoelectric focusing showed that KCHMB 003 detected bands of synthetic rat CRF-41 and rat [Met(O)^21,38]-CRF-41 at pH 7·1 and 6·8 respectively. Use of KCHMB003 in a two-site enzyme-amplified immunoassay showed that this antibody recognizes both synthetic rat CRF-41 and immunoreactive CRF-41 in rat hypothalamic tissue extracts.

ABSTRACT

The enzyme thyroid peroxidase (TPO) plays a central role in thyroid hormone synthesis and is the target for the autoimmune attack in lymphocytic thyroiditis. We have examined the activation of the TPO gene in cultured human thyrocytes using slotblot hybridization with a synthetic 40 mer oligonucleotide probe derived from the nucleotide sequence of the human TPO gene. The oligonucleotide probe was shown by Northern blotting to hybridize specifically to an approximately 3 kb RNA species from thyroid tissue of patients with Graves' disease, but not to RNA preparations from human or bovine retinal tissue, providing compelling evidence for the specificity of the probe for TPO mRNA. Addition of TSH (10 mU/ml) to primary thyroid cultures for 4 h led to increased TPO mRNA levels which were maximal after 48 h and significantly higher than basal even after 7 days of co-culture. Activation of TPO mRNA by TSH showed dose dependency over a wide range (0·01–100 mU/ml), with a maximal effect at 10 mU TSH/ml in cells cultured for a period of 72 h.

Comparison of TPO mRNA levels with the accumulation of thyroglobulin mRNA levels following stimulation by TSH indicated that the induction of the gene encoding thyroglobulin precedes transcription of the TPO gene. The adenylate cyclase activator forskolin (1–100 μm) mimicked TSH in increasing TPO mRNA levels whilst, in contrast, the phorbol ester 12-O-tetradecanoyl phorbol 13-acetate (TPA; 0·01–1 μm) led to levels of TPO mRNA that were lower than basal. Thus TSH induces a specific dose-dependent activation of TPO mRNA which is mimicked by agents which increase cyclic AMP. In contrast, TPA-induced activation of protein kinase C inhibits this response.

ABSTRACT

Since the cloning of the TSH receptor (TSH-R), the target autoantigen of Graves' disease, the receptor has been expressed in a variety of eukaryotic cells to obtain a functional molecule. Despite this success, the levels of receptor expression have been marginally higher than the extremely low levels found in thyroid cells, preventing any progress on the purification of the molecule. In this study, the large extracellular region of the TSH-R, without the membrane spanning segments, has been expressed in insect cells using recombinant baculovirus to generate substantial quantities of the receptor protein. A monoclonal antibody previously generated to a bacterial TSH-R fusion protein was used to characterize and monitor the expression of the truncated receptor in insect cells. Two polypeptides of 63 and 49 kDa were recognized as the components of the truncated recombinant receptor. The 63 kDa protein was shown to be the glycosylated form of the smaller, 49 kDa, component. Expression in different insect cell lines showed that an increase in expression of approximately tenfold was apparent in High Five cells when compared with Sf21 cells. Very small quantities of the truncated receptor were secreted by the three insect cell lines examined, with the majority of the molecule being retained within the cells. Immunoaffinity purification of milligram quantities of the truncated receptor was achieved using the monoclonal antibody. The availability of the purified TSH-R has allowed the establishment of an enzymelinked immunosorbent assay to measure autoantibodies in the sera of patients with Graves' disease. Although the truncated receptor interacts with autoantibodies, our results show that it does not bind TSH and differs in this respect from other glycoprotein hormone receptors.

ABSTRACT

We have characterized four murine monoclonal antibodies (mAbs) to the extracellular domain of the human TSH receptor (TSH-R.E), the target autoantigen of Graves' disease. Recombinant TSH-R.E used as immunogen, was produced in E. coli as a fusion protein with glutathione-S-transferase or in a baculovirus-insect cell system, as a non-fusion glycoprotein. To increase the epitope specificity of the mAbs, two different strains of mice (H-2^b and H-2^d) were immunized. The epitopes recognized by the mAbs were characterized by immunoblotting with various recombinant constructs of TSH-R.E and by binding to overlapping synthetic peptides of the receptor. The four IgG mAbs characterized recognized epitopes localized to different regions on the TSH-R.E; amino acids 22–35 (A10 and All, both IgG2b from H-2^b animals), amino acids 402–415 (A7, IgG2b from H-2^b animals) and amino acids 147–228 (A9, IgG1 from H-2^d animals). Immunolocalization studies showed that mAb A9 recognized TSH-R.E on unfixed cryostat sections, where binding was localized to the basolateral plasma membrane of thyroid follicular cells, suggesting that this antibody reacts with the native receptor on thyroid cells. The binding of the mAbs A7, A10 and All was also restricted to the basal surface of thyroid cells, but only after acetone fixation of the sections, implying that the epitopes recognized on the amino and carboxyl terminus of the extracellular region of the receptor are not accessible on the native molecule. None of the mAbs stimulated cyclic AMP responses in COS-7 cells transiently transfected with full-length functioning TSH-R.E, whilst weak inhibition of binding of radiolabelled TSH to porcine membranes in a radioreceptor assay was apparent with mAb A10 and All, but only at high concentrations of IgG. The ability of mAb A9 to bind to the native receptor without stimulating activity or inhibition of TSH binding suggests that antibody can bind to the central region of the TSH-R.E without perturbing receptor function. The availability of mAbs that recognize epitopes on different regions of the extracellular domain of TSH-R will lead to a better understanding of the autoantigenic regions on TSH-R implicated in disease activity.