Hypervariability of the human thyroid peroxidase gene in Italy

Using a PCR based method, we determined hypervariable markers of the Thyroid Peroxidase gene (TPO-VNTR markers) by size classification of alleles in a total of 146 blood samples (76 from Sicily and 70 from Lombardy, South and North Italy respectively). A total of 22 alleles were identified. They varied in size from 6 (0.4 Kbp) to 27 (1.5 Kbp) repeats and showed a unimodal distribution (peak at 15 repeat number). Data were compared with those previously obtained in two other Italian samples from Calabria (South Italy) and from Sardinia. Heterogeneity G tests on allele frequency distributions led to the following conclusions: 1) as observerd for the majority of the known polymorphisms, the Sardinian sample is clearly distinguishable from all the others; 2) although on the whole no significant heterogeneity emerges from the comparison between southern and northern Italians, certain allelic frequencies are able to distinguish between groups.     

Regional localization of the gene for thyroid peroxidase to human chromosome 2pter----p12

A 2.0-kb thyroid peroxidase cDNA of human origin was used as probe for Southern blot hybridization of genomic DNA from human somatic cells and human-rodent somatic cell hybrids. The results showed that the gene coding for human thyroid peroxidase is located on chromosome. 2. Further analysis of hybrids derived from Burkitt lymphoma cells carrying a (2;8)(p12;q24) translocation revealed that the gene maps to the region 2pter----p12.     

Structural and functional aspects of thyroid peroxidase

Thyroperoxidase (TPO) is the enzyme involved in thyroid hormone synthesis. Although many studies have been carried out on TPO since it was first identified as being the thyroid microsomal antigen involved in autoimmune thyroid disease, previous authors have focused more on the immunological than on the biochemical aspects of TPO during the last few years. Here, we review the latest contributions in the field of TPO research and provide a large reference list of original publications. Given this promising background, scientists and clinicians will certainly continue in the future to investigate the mechanisms whereby TPO contributes to hormone synthesis and constitutes an important autoantigen involved in autoimmune thyroid disease, and the circumstances under which the normal physiological function of this enzyme takes on a pathological role.     

Studies on the promoter region of the c-Ha-ras gene in FRTL5 rat thyroid cells

The functional activity of the promoter region of the rat c-Ha-ras gene was examined in FRTL5 rat thyroid cells, the cell type from which this promoter was cloned. A plasmid (p035-ras-CAT) was constructed containing the untranslated-1 exon as well as 172 base pairs (bp)5' to this exon inserted upstream of the chloramphenicol acetyl transferase (CAT) reporter gene. These 172 bp of 5'-flanking region contain two 10 bp GC box consensus sites and two CAAT boxes. Very weak promoter activity was observed in experiments involving transient transfection of FRTL5 cells with this plasmid, as well as with another plasmid (p5kb-ras-CAT) containing a much more extensive (3.5 kb) 5'-flanking region of the gene. In contrast, strong promoter activity was observed when the same plasmids were transfected into mouse 3T3 fibroblasts. When other promoters (pfos, RSV, and MMTV) were used to drive CAT activity, CAT activity in FRTL5 cells was about 10-fold less than in NIH-3T3 cells and rat embryo fibroblasts. However c-Ha-ras promoter activity was reduced out of proportion in FRTL5 thyroid cells relative to the other cell types (approximately 50-fold less). DNA gel-shift assays performed using crude extracts of FRTL5 and 3T3 nuclear proteins revealed quantitatively similar binding to the same promoter region in the c-Ha-ras 5'-flanking sequence. These data demonstrate that promoter activity of the rat c-Ha-ras gene is contained within the 172 bp 5'-flanking region of the gene. This promoter activity is expressed at a much lower level in slow-growing FRTL5 cells relative to other more rapidly growing cell types.     

EcoRI RFLP in the human thyroid peroxidase (TPO) gene on chromosome 2

Summary The authors describe the source and characteristics of a new probe (pTP02/0.7EP).     

Iodothyronine-induced catalatic activity of thyroid peroxidase

Iodothyronines induced catalatic (H2O2-decomposing) activity of thyroid peroxidase and lactoperoxidase, the effect increasing in the order of thyroxine (T4) greater than triiodothyronine (T3) greater than diiodothyronine (T2). The iodothyronines served as electron donors in the peroxidase reactions, and during the reactions the catalytic intermediate of thyroid peroxidase was confirmed to be Compound II for T4 and Compound I for T3 and T2 and from the Soret absorption spectra obtained by stopped-flow measurements. Rate constants for the reactions between T4 and Compound II, T3 and Compound I, and T2 and Compound I were estimated at 1.9 x 10(5), 1.3 x 10(6), and 7.1 x 10(5) M-1.s-1, respectively. Unlike the case of thyroid peroxidase, the catalytic intermediate of lactoperoxidase observed during the oxidation of iodothyronines was invariably Compound II. From these and other data it was concluded that thyroid peroxidase catalyzed one-electron oxidation of T4 and two-electron oxidations of T2 and T3 while lactoperoxidase catalyzed exclusively one-electron oxidation of the iodothyronines. Iodide was released during the enzymatic oxidation of iodothyronines, irrespective of the mechanism of one-electron and two-electron oxidations. The amount of released iodide increased in the order of T4 greater than T3 greater than T2. The iodothyronines-induced catalatic activity of these peroxidases was ascribable to the release of iodide, but it was also found that the iodide-enhanced catalatic activity was stimulated by iodothyronines. In this case the effect of iodothyronines was greater in the order of T2 greater than T3 greater than T4, which was consistent with the order of iodothyronine activation for the iodinium cation transfer from enzyme to acceptor.     

Molecular cloning of the structural gene for porcine thyroid peroxidase

We have isolated and determined the nucleotide sequence of overlapping cDNA clones, representing the entire structural gene for pig thyroid peroxidase. The protein coding region extends from an ATG residue at base 252 to a termination codon at base 3030, coding for a 100.4-kDa apoprotein of 926 amino acids. The derived amino acid composition agrees well with the experimentally determined amino acid composition of purified pig thyroid peroxidase. Five potential glycosylation sites are present in the protein. Potential membrane spanning regions are present at the amino-terminal end (1-23) and near the carboxyl-terminal end (845-870) of the protein. These data indicate that pig thyroid peroxidase is synthesized as a single polypeptide that is membrane-bound.     

A fluorimetric guaiacol method for thyroid peroxidase activity

A sensitive fluorimetric method with guaiacol as the hydrogen donor for peroxidase activity is described. The gist of this method is measurement of the fluorescence (excitation, 300 nm; emission, 340 nm) in cyclohexane of mainly a guaiacol dimer which forms in the early phase of the color formation. Optimum conditions of the reaction were compared for horseradish peroxidase and rat thyroid peroxidase preparations. The fluorescence intensity obtained by this method using an enzyme preparation from $\text{1}\text{20}$ of a rat thyroid gland correlated well with the color development by the guaiacol method using the same preparation from whole glands of a rat.     

cDNA-directed expression of human thyroid peroxidase

A human thyroid peroxidase cDNA, hTPO-1 [(1987) Proc. Natl. Acad. Sci. USA 84, 5555–5559], was expressed in human Hep G2 cells using a vaccinia virus cDNA-expression system. When examined by immunoblot analysis, the level of hTPO-1 protein expression reached a maximum approx. 24 h after infection and remained at a similar level up to 72 h post-infection. The expressed protein was enzymatically active as measured by guaiacol oxidation. Monoclonal antibody-assisted immunoaffinity column chromatography was used for partial purification of vaccinia-expressed hTPO-1, resulting in more than 300-fold higher specific activity and a measurable difference spectrum of the hTPO-1 (Fe³⁺)-CN complex.     

Endogeneous peroxidase activity in the frog thyroid gland

Summary The fine structural localization of the endogeneous peroxidase activity in the thyroid of the young frog was studied. The reaction product for peroxidase was observed over the peripheral luminal colloid and apical region of the follicular epithelial cell. Most apical small granules and some parts of Golgi lamellae and a few Golgi vesicles were specifically stained. The cisternae of rough endoplasmic reticulum and the nuclear cisternae did not demonstrate any positive reaction for peroxidase activity with difference from that of various cells of mammalia. In this study, only mature peroxidase seems to be positive for its reaction and the enzyme in the rough endoplasmic reticulum is considered to be too immature to react for DAB method in the frog thyroid cell. The relationship between the localization of peroxidase reaction and the site of the iodination of thyroglobulin was discussed.     

Differential effects of methylmercuric chloride and mercuric chloride on the histochemistry of rat thyroid peroxidase and the thyroid peroxidase activity of isolated pig thyroid cells

This study was designed to characterize the interaction of CH3HgCl or HgCl2 with thyroid peroxidase (TPO). Two types of experiments were performed. First, the thyroids from rats that were given 5.6 mg/kg/day of either CH3HgCl or HgCl2 for 2 weeks by intubation were subjected to histochemical treatment and then to electron microscopy. TPO activities in all cell compartments were inhibited by HgCl2 but not by CH3HgCl. Morphological observation showed that taller epithelia were induced by HgCl2, whereas flattened epithelia forming large follicles were induced by CH3HgCl. The serum thyrotropin level was substantially lowered by CH3HgCl but was unchanged by HgCl2. Second, the guaiacol oxidation by TPO in isolated and ruptured pig thyroid cells was spectrophotometrically monitored in the presence of either CH3HgCl or HgCl2. The TPO was not inhibited by CH3HgCl but was inhibited by HgCl2. These results indicated that CH3HgCl induced a hypothyroid state without affecting TPO, whereas HgCl2 inhibited TPO and induced a hypertropic state owing to compensation for loss of enzyme activity, and that the lack of inhibitory activity of CH3HgCl was not due to the inability to penetrate the cells. Therefore, there appeared to be a differential interaction of organic and inorganic forms of mercurials with the thyroid.