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Query: EC:4.6.1.1 (
adenylate cyclase
)
19,190
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
In the present report the mechanisms responsible for the expression of the thyroid microsomal
autoantigen
(M-Ag) were studied in primary cultures of human thyroid cells prepared from Graves' or non-toxic goitres. The indirect immunofluorescence (IFL) technique using human sera positive for anti-microsomal antibody (anti-MAb) was employed to detect M-Ag. Studies were performed to ascertain whether M-Ag recognized by anti-MAb could be identified with thyroid peroxidase (TPO). Preabsorption experiments showed that, similarly to solubilized thyroid microsomes, purified human TPO abolished the binding of anti-MAb to thyrocytes, while no inhibition was obtained with control human tissues. The identity of M-Ag and TPO was also demonstrated using a double layer IFL technique which allowed a simultaneous staining of the antigen(s) recognized by anti-MAb and by a monoclonal anti-TPO antibody. After 5-15 days of TSH withdrawal from the culture medium the M/TPO-Ag disappeared from the surface and the cytoplasm of human thyroid cells. Readdition of TSH (0.1-100 mU/ml) to cells lacking M/TPO-Ag elicited its reappearance within 48-72 h. This effect of TSH was prevented by 10 microM cycloheximide but not by methimazole (0.1-2 mM). Two stimulators of the
adenylate cyclase
-cAMP system, cholera toxin and forskolin, and 8-bromo-cAMP mimicked TSH in inducing M/TPO-Ag. Thyroid stimulating antibody (TSAb) of Graves' disease also reproduced the effect of TSH on M/TPO-Ag reexpression in human thyroid cells. By contrast, epidermal growth factor, oestradiol or NaI were ineffective in inducing M/TPO-Ag. The present data indicate that: (i) the expression of M/TPO-AG in human thyroid cells is dependent on TSH stimulation, through pathways which involve cAMP production and protein synthesis, (ii) TSAb reproduces this effect of TSH; (iii) oestradiol and NaI have no direct influence on the expression of M/TPO-Ag.
...
PMID:The expression of the microsomal/peroxidase autoantigen in human thyroid cells is thyrotrophin-dependent. 266 Oct 62
The thyrotropin receptor (TSHR) has been used as an example to illustrate how disease may be the consequence of: 1. Modifications or inappropriate production of the natural ligand. 2. Production of abnormal agonists or antagonists such as autoantibodies. 3. Modifications in receptor structure resulting in constitutive activation or the absence of activation following ligand binding. 4. Changes in the cellular machinery which transduces the signal from the receptor to the cytoplasmic or nuclear endpoint target. This chapter concentrates on mechanisms (2) and (3). Since the cloning of the TSHR it has been shown that approximately 50% of cases of toxic adenoma can be explained by somatic point mutations in the nucleotide sequence of the receptor gene which causes single amino acid substitutions. The resulting modified TSHR structure constitutively activates
adenylate cyclase
(via Gs), intracellular cAMP levels are increased and, since cAMP controls both growth and function of the human thyrocyte clonal expansion of the mutated cell ensues. Similarly, activating mutations of the TSH receptor gene in the germline are responsible for hereditary hyperthyroidism with goitre, which is transmitted in the autosomal dominant mode. Changes in receptor primary structure, i.e. a modified
autoantigen
, do not seem to be responsible for the escape from tolerance which must precede production of thyroid stimulating antibodies (TSAB) which cause hyperthyroid Graves' disease and thyroid blocking antibodies (TBAB) which are responsible for some cases of hypothyroid idiopathic myxoedema. The eukaryotic expression of wild-type, experimentally mutated and chimeric TSHR has enabled some progress in delineating the residues involved in binding TSH, TSAB and TBAB. All three ligands bind numerous discontinuous residues in the extracellular domain of the receptor. The difference between the bioactivity of TSAB and TBAB cannot be explained completely by different binding sites on the receptor. Subtle differences in, for example, glycosylation and sialation of the immunoglobulins may be implicated, since bioactivity of TSH itself seems to depend on these. Attempts to define T cell epitopes have not identified a major immunogenic region. Indeed heterogeneity seems to be a hallmark of TSHR autoantibodies (TRAB). The possibility that thyroid-associated ophthalmopathy and pretibial myxoedema may be receptor antibody diseases is discussed. Further progress awaits large-scale production of TSHR able to bind TSH to facilitate X-ray crystallographic studies, the development of specific T cell clones and the cloning of TSAB autoantibodies.
...
PMID:The thyrotropin receptor as a model to illustrate receptor and receptor antibody diseases. 772
Antigenic mimicry or cross-reactivity between Group A streptococcal antigens and cardiac autoantigens may initiate an autoimmune response resulting in cardiovascular damage in acute rheumatic fever. This study describes a molecular biological approach to the identification of such cross-reactive cardiac antigens. Two human heart cDNA libraries were constructed in the expression vector lambda gt11 and screened with patient sera, monoclonal antibodies and rabbit immune sera cross-reactive with streptococcal and cardiac antigens. Using the serum of a patient with a recurrent acute attack of rheumatic fever containing high titres of antibodies cross-reactive with both sets of antigens, we were able to identify three positive clones with insert sizes of 1.0 kb, 1.4 kb and 0.9 kb in these libraries. Acute rheumatic fever (ARF) sera reacted more strongly with these
autoantigen
clones than did normal sera. Autoantibodies eluted from the purified plaques of all three clones displayed different patterns of cross-reactivity against immunoblots of streptococcal M5, M6, M19 and M24 protein extracts. The cDNA inserts were sequenced and compared with known sequences in the EMBL and Genbank databases. One clone was 98% homologous with human cytokeratin 8 and showed homologies of 40 to 50% with human cardiac heavy chain myosin, tropomyosin and streptococcal M5 protein--all members of the alpha-helical coiled-coil family of proteins. Another clone was completely homologous to the G-protein alpha-subunit of
adenyl cyclase
, whilst the sequence of the third clone was not found in any of the data banks.
...
PMID:Identification of cardiac autoantigens in human heart cDNA libraries using acute rheumatic fever sera. 803 42
IA-2, a member of the protein tyrosine phosphatase family, represents a major target
autoantigen
in type 1 diabetes. To study the regulation of IA-2 gene expression, we used INS-1 insulinoma cells to analyze beta-cell signal transduction pathways as well as the effect of metabolic and hormonal factors involved in the regulation of the insulin secretory pathway. Quantitative competitive reverse transcriptase-polymerase chain reaction revealed that an increase of cellular cAMP mediated by forskolin (10 micromol/l, 24 h) or 3-isobutyl-1-methylxanthine (100 micromol/l, 24 h) induced maximal stimulation of IA-2 mRNA levels (451 +/- 85 and 338 +/- 86% compared with basal conditions; P < 0.001). In contrast, activation of protein kinase C (PKC) by short-term treatment with phorbol 12-myristate 13-acetate (PMA) (1 micromol/l, 6 h) did not alter IA-2 expression, whereas depletion of PKC by prolonged culturing (24 h) exerted a significant inhibition (57 +/- 24%; P < 0.05). cAMP-dependent upregulation was confirmed by the findings that glucagon (10 micromol/l, 24-48 h) increased levels of IA-2 mRNA (190 +/- 35%; P < 0.05), whereas short-term incubation with high glucose concentration showed no effect. However, prolonged incubation in high glucose (21 mmol/l) induced a time- and dose-dependent increase of IA-2 mRNA expression, reaching maximal values after 144 h (285 +/- 68%; P < 0.05). These studies demonstrate that stimuli of insulin secretion that operate by activation of
adenylate cyclase
generating cAMP significantly increase IA-2 gene expression. In contrast, activation of PKC by high glucose concentration or PMA exerted no effect, suggesting that IA-2 gene expression is not simply coupled to insulin secretion, but may be involved in the fine regulation of beta-cell function. These findings may be important to clarify the function of IA-2 in beta-cells and elucidate mechanisms involved in the induction of autoimmunity to IA-2.
...
PMID:Regulation of the diabetes-associated autoantigen IA-2 in INS-1 pancreatic beta-cells. 1090 70
