Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: EC:1.11.1.8 (thyroid peroxidase)
3,116 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We have postulated over many years that autoimmune thyroid diseases (AITD) are disorders of immunoregulation due to antigen specific defect(s) in suppressor (regulatory) T (Ts) lymphocyte function. Despite earlier skepticism, there is recent increased evidence to support this view. Several investigators working with animal models have demonstrated T lymphocyte subsets that are regulatory, i.e., will prevent AITD; conversely, depletion of these cells precipitates the lesion in the experimental models. These cells have been shown to be inadequately activated by specific antigen. In human AITD, recent studies have demonstrated that CD8+ (suppressor/cytotoxic) and CD8+CD11b+ ("pure suppressor") cells are activated by irrelevant antigen normally, but are significantly less well activated in response to thyroglobulin or thyroperoxidase. In further similar studies, CD8+ cells from patients with Graves' disease (GD) are induced normally in response to glutamic acid decarboxylase-65 (GAD-65), the putative beta cell antigen important in insulin-dependent diabetes mellitus (IDDM), but significantly less to synthetic TSH receptor (TSHR). Conversely, CD8+ cells from patients with IDDM are activated normally in response to TSHR, but significantly less to GAD-65. While these reductions in activation are partial only, and other additive factors playing on the immune system may be necessary to precipitate AITD, this disorder in the activation of Ts cells may be fundamental to the development of these disorders. This in turn may be due to molecular disturbances in MHC-related genes that dictate the mechanisms of presentation of specific antigen.
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PMID:Immunoregulation in autoimmune thyroid disease. 783 79

An in vitro transcription/translation (TnT) system was used to produce 35S-labeled full-length TSH receptor (TSHR) and TSHR extracellular domain (TSHRex). The interaction of the labeled proteins with TSHR autoantibodies in Graves' sera was then studied using an immunoprecipitation assay. In the assay, 35S-labeled TSHR or TSHRex were incubated with test sera, and any immune complexes formed were precipitated with protein A-Sepharose (in the case of mouse monoclonal antibodies, antimouse IgG-agarose was used). Rabbit antibodies to the TSHR and a mouse monoclonal antibody precipitated as much as 50% of the 35S-labeled TSHR preparations compared with about 2% for normal rabbit serum and 4% for a control monoclonal antibody. However, none of 34 Graves' sera (TSHR autoantibody levels ranging from 14-95% inhibition of [125I]TSH binding) were able specifically to immunoprecipitate 35S-labeled TSHR or TSHRex. These negative findings were confirmed by analysis of the immunoprecipitates on SDS-PAGE followed by autoradiography. Our results indicate that the TnT system is not useful for producing labeled TSHR preparations that can bind TSHR autoantibodies well. This is in contrast to TnT produced 35S-labeled glutamic acid decarboxylase, thyroid peroxidase, and 21-hydroxylase, which react well with their respective autoantibodies. One main difference between these 3 autoantigens and the TSHR is that the receptor is highly glycosylated, and this extensive glycosylation may be of critical importance for correct folding of the receptor. Consequently, the inability of the TnT system to glycosylate proteins could explain in part why TnT-produced 35S-labeled TSHR and TSHRex do not bind TSHR autoantibodies.
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PMID:Thyrotropin (TSH) receptor autoantibodies do not appear to bind to the TSH receptor produced in an in vitro transcription/translation system. 910 Jun 9

We report a 79-year-old woman case of slowly progressive IDDM (SPIDDM) with rheumatoid arthritis (RA) and Hashimoto disease. High titer of anti-glutamic acid decarboxylase antibody (GAD) with a value of 16,400 U/ml (normal value: less than 5 U/ml) and deteriorated secretion of insulin, and clinical course led to the diagnosis of SPIDDM. Both anti-islet cell and anti-insulin antibodies were negative. One year prior to the diagnosis, at 78 years of age, she was newly diagnosed with NIDDM and had been medicated with sulfonylurea and voglibose, resulting her glucose levels well-controlled. Four months before admission, a gradual increase of plasma glucose was noticed, while oral hypoglycemic agents were fully administrated. On admission, her glycemic control was revealed as follows; a fasting blood glucose level of 458 mg/dl and an HbA1 C level of 14.3%. Urinary CPR was 22.5 micrograms day. Her insulin secretion was proved not to be induced with intravenous glucagon injection. Hyperinsulinemic euglycemic glucose clamp test showed the normal glucose uptake ratio; 9.5 mg/kg/min. Moderate doses of subcutaneous insulin (20 units daily) were effective on her diabetes control. She was newly diagnosed with Hashimoto disease that required thyroid hormone replacement 50 micrograms per day after having developed NIDDM. High titer of anti-thyroglobulin antibody (46.9 U/ml) and anti-thyroid peroxidase antibody (81.5 U/ml) were observed. The patient had been medicated for RA with anti-inflammatory drugs since her early seventieth. Rheumatoid factor was elevated to 127.7 IU/L and, anti-nuclear antibody (x 80) and anti-DNA antibody (x 80) were present. It may be of interest that a specific phenotype of HLA; A24 (9) and DR9 recognized to be susceptible to IDDM was detected in the high-elderly onset SPIDDM. Taken together HLA typing with her history of both RA and Hashimoto disease, our case may provide the information to the mechanism of pathogenesis of SPIDDM. Furthermore, to out knowledge, this is the first case of SPIDDM in the aged; 75-year-old or more.
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PMID:[Slowly progressive IDDM with rheumatoid arthritis and Hashimoto disease in high elderly]. 977 59

The role of the thymus in the induction of tolerance to peripheral antigens is not yet well defined. One impending question involves how the thymus can acquire the diversity of peripheral nonthymic self-Ags for the process of negative selection. To investigate whether peripheral Ags are synthesized in the thymus itself, we have determined the expression of a panel of circulating and cell-bound peripheral Ags, some of which are targets of autoimmune diseases, at the mRNA level in total thymic tissue and in its main cellular fractions. Normalized and calibrated RT-PCR experiments demonstrated the presence of transcripts of nonthymic self-Ags in human thymi from 8 days to 13-yr-old donors. Out of 12 glands, albumin transcripts were found in 12; insulin, glucagon, thyroid peroxidase, and glutamic acid decarboxylase (GAD)-67 in six, thyroglobulin in five, myelin basic protein and retinal S Ag in three, and GAD-65 in one. The levels of peripheral Ag transcripts detected were age-related but also showed marked interindividual differences. Cytokeratin-positive stromal epithelial cells, which are a likely cellular source for these, contained up to 200 transcript copies of the most expressed peripheral Ags per cell. These results implicate the human thymus in the expression of wide representation of peripheral self-Ags and support the view that the thymus is involved in the establishment of tolerance to peripheral Ags. The existence of such central mechanism of tolerance is crucial for the understanding of organ-specific autoimmune diseases.
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PMID:Transcription of a broad range of self-antigens in human thymus suggests a role for central mechanisms in tolerance toward peripheral antigens. 983 72

The prevalence of autoantibodies against the 65 kD isoform of glutamic acid decarboxylase (GAD65Ab), insulin (IAA), islet cells (ICA), thyroid peroxidase (TPOAb) and thyroglobulin (TgAb), in relation to HLA-DR types, was assessed in 310 (HLA in 280) twelve-year-old children during three-year follow-up. Altogether, 26.8% (83/310) of the children were found to carry at least one autoantibody. The HLA-DR3/DR4 genotype was significantly more prevalent in the subgroup of children GAD65Ab-positive on at least one occasion than among GAD65Ab-negative children [33% (2/6) vs. 5% (12/274); p = 0.031, as was the HLA-DR4/x genotype among children seropositive for at least one thyroid autoantibody, compared to the corresponding seronegative subgroup 152% (34/65) vs. 34% (74/215); p=0.01]. The proportion of children seropositive in at least one of the three tests was 1.9% (6/310) for GAD65Ab, 2.6% (8/310) for IAA, 5.2% (16/310) for ICA, 11.3% (35/310) for TPOAb and 19.4% (60/310) for TgAb. All autoantibodies except GAD65Ab tended to disappear during follow-up, and at the three-year follow-up IAA had disappeared in 50% (2/4) of cases, ICA in 67% (6/9), TPOAb in 30% (6/20) and TgAb in 38% (18/47) of cases. The turnover of seropositive subjects and the large proportion of children seropositive for at least one islet or thyroid autoantibody during a three-year follow-up suggest transient autoantibodies to be more common than is discernible in cross-sectional investigations.
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PMID:Prevalence of beta-cell and thyroid autoantibody positivity in schoolchildren during three-year follow-up. 1073 34

Purified native human thyroid peroxidase (nTPO) isolated from thyroid tissue and recombinant (r)TPO produced in High Five insect cells have been compared. nTPO and rTPO were purified to about 95% homogeneity and showed similar UV and visual spectra and similar 412 nm per 280 nm absorbance ratios (0.4 for nTPO and 0.4 for rTPO). The nTPO and rTPO guaiacol oxidation enzyme activities were about 1,000 guaiacol units per milligram of protein. TPO autoantibody binding characteristics of nTPO and rTPO were analyzed in an assay based on 125I-labeled nTPO and precipitation with protein A. In the assay, the effect of unlabeled nTPO or rTPO on TPO autoantibody binding from 25 patients sera was studied. Unlabeled nTPO or rTPO (from 0 to 160 ng/mL) inhibited the binding of TPO autoantibodies in a dose-dependent manner in the case of each serum studied (from 100% in the absence of unlabeled TPO to 5%-10% in the presence of 160 ng/mL of TPO). The inhibition profile for each serum was essentially identical in the case of both TPO preparations. The effect of TPO autoantibodies on enzyme activity of rTPO was analyzed after incubation of rTPO with TPO autoantibody-positive serum immunoglobulin G (IgG) (n = 12), TPO monoclonal antibodies reactive with two different epitopes on the TPO, IgG (n = 3) from glutamic acid decarboxylase autoantibody positive patient sera, and IgG (n = 3) from healthy blood donors. Effective complexing of TPO by TPO autoantibodies was tested by precipitating the complexes with solid phase protein A and measuring the TPO enzyme activity in the resulting supernatants. These studies showed that the TPO enzyme activity was not affected by incubation with TPO autoantibody-positive IgG or monoclonal antibodies despite effective complexing of the autoantibodies with TPO. Overall, our studies demonstrate that nTPO and rTPO produced in insect cells are very similar in terms of enzyme activity, UV and visible spectra, and reactivity with autoantibodies. Furthermore, in our study, TPO autoantibodies did not appear to inhibit TPO enzyme activity.
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PMID:Recombinant human thyroid peroxidase produced in insect cells has similar properties to native human thyroid peroxidase. 1095 6

Autoimmune type 1 diabetic patients show a high prevalence of thyroid peroxidase (TPO), parietal cell (PCA), anti-adrenal (AAA) and anti-endomysium antibodies (EmA-IgA), which may be accompanied with clinical disease. We studied the grade of associated organ-specific autoimmunity and the pattern of prevalence of TPO and PCA by age, gender, duration, age at onset of diabetes, and HLA DR haplotype in 783 type 1 diabetic patients, consisting of 286 children and 497 adults (M/F: 389/394), with a mean diabetes duration of 11.8 +/- 10.1 years. The relationship between islet cell (ICA), glutamic acid decarboxylase-65 (GADA) and thyro-gastric auto-antibodies was also investigated. TPO were present in 21.6%, PCA in 18.3%, AAA in 2.2% and EmA-IgA in 2.1% of the patients. The presence of TPO is determined by gender (p < 0.0001), age (P = 0.0008), and PCA status (p = 0.029). The presence of PCA is only influenced by age (p = 0.0027) and TPO status (p = 0.0155). Patients with ICA+ > or = 3 years had a higher prevalence of thyro-gastric auto-antibodies (p = 0.045) than ICA- subjects. Also, PCA were more prevalent in GADA+ than GADA- patients (p = 0.005). We observed an association between HLA DR5 and PCA (p = 0.0012). Dysthyroidism was more prevalent in TPO+ than TPO- subjects (p < 0.0001). PCA+ subjects had a higher prevalence of iron deficiency anaemia (p = 0.0099) and pernicious anaemia (p < 0.0001) than PCA- patients. In conclusion, particularly type 1 diabetic patients with persisting ICA > or = 3 years or with GADA, show a high prevalence of thyro-gastric auto-antibodies. Based on antibody-positivity we observed a high prevalence of thyroid disease, iron deficiency anaemia and pernicious anaemia, which can compromise the health of the diabetic patient.
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PMID:[Diabetes mellitus type 1 and associated organ-specific autoimmunity]. 1100 7

Type 1 diabetes mellitus is an autoimmune disease in which the presence of different autoantigens can often be found. The aim of our study was to evaluate the prevalence of antibodies against insulin (IA) and autoantibodies against glutamic acid decarboxylase (anti-GAD), tyrosine phosphatase IA-2 (anti-IA-2), thyroid microsomal peroxidase (anti-TPO) and thyroglobulin (anti-TG) in 55 randomly selected Type 1 diabetic patients (34 males, 21 females). Mean age of these patients was 39 +/- 12 yrs, mean duration of diabetes 18 +/- 13 yrs. Positivity of anti-GAD was found in 29 (58%) patients, anti-IA-2 in 13 (25%) patients, IA in 46 (85%) patients, anti-TPO in 10 (21%) and anti-TG in 11 (23%) patients. Simultaneous positivity of thyroid and islet autoantibodies was found in 6 (11%) patients whereas the positivity at least one of them was in 38 (69%) patients. No relationship between glycated hemoglobin and autoantibody concentration was found in the whole group of patients. The autoimmune thyroid disease was newly detected in 4 patients from high concentration of thyroid autoantibodies together with impaired TSH and T4 values and ultrasonography finding. No clinical evidence of thyroid disease was previously found in these patients. Positivity of anti-GAD or anti-IA-2 was found in almost 65% and of any thyroid autoantibody in almost 30% of our patients. Four patients with autoimmune thyroid disease were newly identified. We conclude that the evaluation of thyroid autoantibodies in Type 1 diabetic patients may improve the diagnosis of thyroid disease in very early stage and thus prevent consequent complications.
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PMID:The evaluation of thyroid and islet autoantibodies in type 1 diabetes mellitus. 1122 67

A quarter of type 1 diabetic patients have thyrogastric autoantibodies (thyroid peroxidase and gastric parietal cell antibodies). Clinical, immune, and genetic risk factors help predict antibody status. First degree relatives of these patients may also frequently exhibit these antibodies. We assessed the prevalence of thyrogastric antibodies and dysfunction in first degree relatives in relation to age, gender, human leukocyte antigen-DQ type, beta-cell antibody (islet cell, glutamic acid decarboxylase-65, and tyrosine phosphatase antibodies), and proband thyrogastric antibody status. Sera from 272 type 1 diabetic patients (116 men and 156 women; mean age, 27 +/- 18 yr; duration, 10 +/- 9 y), 397 first degree relatives (192 men and 205 women; parents/siblings/offspring, 48/222/127; age, 22 +/- 10 yr), and 100 healthy controls were tested for islet cell antibodies and gastric parietal cell antibodies by indirect immunofluorescence and for tyrosine phosphatase, glutamic acid decarboxylase-65, and thyroid peroxidase antibodies by radiobinding assays. Glutamic acid decarboxylase-65 antibodies were present in 68% and 5%, islet cell antibodies were present in 36% and 2.5%, tyrosine phosphatase antibodies were present in 45% and 0.5%, thyroid peroxidase antibodies were present in 21% and 4.5%, and gastric parietal cell antibodies were present in 18% and 11% of diabetic patients and relatives, respectively. The presence of thyroid peroxidase antibodies in relatives was determined by age (beta = 0.22; P = 0.0001) and proband thyroid peroxidase antibodies status (beta = -2.6; P = 0.002; odds ratio = 11.1). Gastric parietal cell antibody positivity in relatives was associated with age (beta = 0.04; P = 0.026). Gastric parietal cell antibody-positive compared with gastric parietal cell antibody-negative relatives were more likely to have gastric parietal cell antibody-positive probands (P = 0.01; odds ratio = 3.0). beta-Cell antibody status and human leukocyte antigen-DQ type did not influence thyrogastric antibody status in relatives. (Sub)clinical dysthyroidism was found in 3%, iron deficiency anemia was present in 12% (26% gastric parietal cell antibody-positive and 9% gastric parietal cell antibody-negative subjects; P = 0.009), and pernicious anemia was found in 0.5% (5% gastric parietal cell antibody-positive and 0% gastric parietal cell antibody-negative subjects; P = 0.012) of relatives. They had less thyroid dysfunction (P < 0.0001) and pernicious anemia (P = 0.018) than diabetic probands. In conclusion, thyrogastric antibodies and dysfunction are more prevalent in type 1 diabetic patients than in first degree relatives. The presence of these antibodies in relatives is associated with age and proband antibody status, but not with beta-cell antibodies or human leukocyte antigen-DQ type.
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PMID:The presence of thyrogastric antibodies in first degree relatives of type 1 diabetic patients is associated with age and proband antibody status. 1154 75

The autoimmune attack in type 1 diabetes is not only targeted to beta cells. We assessed the prevalence of thyroid peroxidase (aTPO), parietal cell (PCA), antiadrenal (AAA) and endomysial antibodies (EmA-IgA), and of overt autoimmune disease in type 1 diabetes, in relation to gender, age, duration of disease, age at onset, beta-cell antibody status (ICA, GADA, IA2A) and HLA-DQ type. Sera from 399 type 1 diabetic patients (M/F: 188/211; mean age: 26 +/- 16 years; duration: 9 +/- 8 years) were tested for ICA, PCA, AAA and EmA-IgA by indirect immunofluorescence, and for IA2A (tyrosine phosphatase antibodies), GADA (glutamic acid decarboxylase-65 antibodies) and aTPO by radiobinding assays. The prevalence rates were: GADA 70%; IA2A, 44%; ICA, 39%; aTPO, 22%; PCA, 18%; EmA-IgA, 2%; and AAA, 1%. aTPO status was determined by female gender (beta = - 1.15, P = 0.002), age (beta = 0.02, P = 0.01) and GADA + (beta = 1.06, P = 0.02), but not by HLA-DQ type or IA2A status. Dysthyroidism (P < 0.0001) was more frequent in aTPO + subjects. PCA status was determined by age (beta = 0.03, P = 0.002). We also observed an association between PCA + and GADA + (OR = 1.9, P = 0.049), aTPO + (OR = 1.9, P = 0.04) and HLA DQA1*0501-DQB1*0301 status (OR = 2.4, P = 0.045). Iron deficiency anaemia (OR = 3.0, P = 0.003) and pernicious anaemia (OR = 40, P < 0.0001) were more frequent in PCA + subjects. EmA-IgA + was linked to HLA DQA1*0501-DQB1*0201 + (OR = 7.5, P = 0.039), and coeliac disease was found in three patients. No patient had Addison's disease. In conclusion, GADA but not IA2A indicate the presence of thyrogastric autoimmunity in type 1 diabetes. aTPO have a female preponderance, PCA are weakly associated with HLA DQA1*0501-DQB1*0301 and EmA-IgA + with HLA DQA1*0501-DQB1*0201.
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PMID:Beta-cell, thyroid, gastric, adrenal and coeliac autoimmunity and HLA-DQ types in type 1 diabetes. 1170 58


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