Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.4.21.4 (trypsin)
 42,187 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Two patients (G2, G3) with iodine organification defect were studied. The first patient (G2), a 25-year-old women with no clinical hypothyroidism, had had her goiter for 10 years; 62% of the thyroidal iodine was released by perchlorate indicating iodine organification defect. The thyroid tissue obtained at thyroidectomy contained a normal concentration of thyroid peroxidase (I2 formation from I-) when tested after solubilization of the enzyme by trypsin and digitonin treatment of the particulate material. 1. The enzymatic activity (G2-TPO) behaved on DEAE cellulose chromatography very differently from those of hog (P-TPO) or another human goiter peroxidase (G1-TPO) (Pommier, et al., J Clin Endocrinol Metab 39: 69, 1974): the molarity of elution was 2M NaCl instead of 0.15 mM. 2. Both P-TPO and G2-TPO catalyzed iodide peroxidation (I- leads to I2) but the Km (iodide) value for G2-TPO was much lower (2.3 x 10(-2) M) when compared with that of P-TPO (3.7 x 10(-3) M) or G1-TPO (3.5 x 10(-3) M). In addition, the optimum pH for this reaction differed markedly (pH 6.1 instead of 7.9). 3. G2-TPO was poorly efficient in catalyzing the oxidation of gaiacol to tetragaiacol. 4. G2-TPO was unable to perform the iodination of non-iodinated goiter thyroglobulin whatever the pH and the iodide concentration. 5. Thyroglobulin from this goiter (G2) was almost not iodinated (0.0014%), i.e., 0.07 atoms iodine/mole thyroglobulin), and its total content in the gland was very low (0.3-4 g/1000 g wet tissue instead of 25 g). A clear discrepancy was thus shown between the euthyroid state of this patient and the total lack of iodinating activity of the isolated peroxidase. The second patient (G3), a 17-year-old man with clinical hypothyroidism, had had his goiter for 5 years. 100% of the thyroidal iodine was released by perchlorate indicating a complete iodine organification defect. The thyroid tissue obtained at thyroidectomy contained no peroxidase activity when tested before and after treatment of the particulate material by trypsin and digitonin and even in the presence of hematin. Thyroglobulin from this goiter, which was almost non-iodinated (0.0014%), was present in normal amounts in the gland (congruent to 25 g/1000 g).
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PMID:Thyroid iodine organification defects: a case with lack of thyroglobulin iodination and a case without any peroxidase activity. 126 32

To characterize the binding substance(s) for botulinum C2 toxin, the hemagglutinating activity of component II of botulinum C2 toxin (C2II) was studied by hemagglutination and hemagglutination inhibition. Human and animal erythrocytes were agglutinated by trypsinized C2II much more strongly than by untreated C2II. Trypsinized C2II agglutinated neuraminidase-treated erythrocytes more strongly than intact, trypsin- and pronase-treated ones. On the other hand, trypsin- and pronase-treated erythrocytes were more weakly hemolyzed by trypsinized C2II than intact and neuraminidase-treated ones, and trypsinized C2II showed both hemagglutinating and hemolytic activities to these erythrocytes. Hemagglutination of trypsin-treated human type B erythrocytes was inhibited by galactose, N-acetylgalactosamine, N-acetylglucosamine, L-fucose and mannose. Thyroglobulin and bovine salivary mucin were much stronger inhibitors. From these findings, the binding substance(s) for botulinum C2 toxin on erythrocytes is(are) suggested to be glycoprotein(s).
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PMID:Hemagglutinating and binding properties of botulinum C2 toxin. 235 92

We report the first isolation of purified coated vesicles (CVs) from thyroid gland. Bovine thyroid CVs were isolated by differential centrifugation, including a step through sucrose-D2O, using a modification of the method described by Nandi et al. (1) for bovine brain CVs. The CVs were characterized by electron microscopy, sedimentation properties, and SDS-PAGE of the protein components. Thyroglobulin (Tg) was found to be associated with the purified CVs. When the thyroid CVs were exposed to conditions known to remove the protein coat from brain CVs, such as low ionic strength at pH 8.5, most of the Tg dissociated from the vesicles along with the coat proteins. Moreover, the Tg remaining with the uncoated vesicles (UVs) was trypsin sensitive, and therefore judged to be associated with the external surface of the vesicle. Since ligand-receptor complexes are normally located within CVs and not on their outer surface, no evidence was found for Tg-receptor complexes within thyroid CVs. Thyroid slices were incubated in the presence of [35S] methionine with subsequent isolation of labeled CVs in order to study the incorporation of newly-synthesized proteins into these structures. At 0.5 and 2 hours of incubation, the 180K MW subunit of clathrin, as well as other proteins, but not Tg, had become labeled in the purified CVs. Extracellular 19S-[35S] thyroglobulin was isolated from the incubation medium, however, demonstrating release of newly-synthesized Tg (presumably into cut follicles). It is concluded that thyroid CVs do not seem to be involved in the secretion of newly-synthesized Tg from the rough endoplasmic reticulum into the follicular lumen. While a possible role of thyroid CVs in the reabsorption of small quantities Tg by micropinocytosis cannot be completely excluded, the present data do not support a primary role for thyroid CVs in either endocytosis or exocytosis of Tg.
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PMID:Coated vesicles from the thyroid gland: isolation, characterization, and a search for a possible role in thyroglobulin transport. 286 11

Thyroglobulin (Tg) from turtles previously injected with 125I was reduced, alkylated, and digested with trypsin. We purified the resultant peptides on HPLC columns, determined their amino acid sequences and the locations of [125I]T4 and [125I]T3 residues, and compared them with established sequences from humans, cows, rabbits, rats, and guinea pigs. We found five major T4 peptides, three of which were homologous with the major hormonogenic sites A, B, and D of mammalian Tg. Site A, the highly conserved major T4 site in mammals, had substitutions in three residues near the T4 residue and had much less of Tg's newly synthesized T4 than is found in mammalian Tg (25% in turtle vs. 44% in rabbit). Site B contained correspondingly more of Tg's new T4 (42% vs. 24% in rabbit). Turtle Tg contained little [125I]T3, and we did not find site C (Ser-T3/T4-Ser, the major T3 site in guinea pig and rabbit) in turtles, but did find Val-T4, a possible homolog. Site D was quantitatively less important than in mammals. The fifth turtle hormonogenic site, containing 12% of Tg's newly formed T4, had a tyrosyl residue substituted for the phenylalanine at residue 632 in the human sequence. We conclude that Tg's major hormonogenic sites are generally conserved across a considerable evolutionary distance, but that differences in primary structure occur and may contribute to changes in priority of hormone synthesis among these sites.
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PMID:The hormonogenic sites of turtle thyroglobulin and their homology with those of mammals. 291 15

Thyroglobulin (mol. wt. 660 kDa) is the specific protein of the thyroid gland in which are synthesized and stored the thyroid hormones (thyroxine and 3,5,3'-triiodothyronine). It is formed of equal-sized subunits (330 kDa) containing each identical polypeptide chains to which are associated two types of oligosaccharide units representing 8 to 10% by weight of the protein. The studies reported in this paper describe the presence in thyroglobulin of discrete hormonogenic sites. After chemical (CNBr) and enzymatic (trypsin and protease V8 of S. aureus) treatments of the protein, four different hormone-containing peptide segments have been isolated, purified and sequenced. They correspond to the hormonogenic tyrosine-containing sites of the protein. One tyrosine is located at 4 amino acid residues from the N-terminal asparagine of the chain and is a major site for thyroxine synthesis. Another one which represents the triiodothyronine site is situated 2 amino acids before the C-terminal lysine. Finally, two other sites, one of low affinity and the other of high affinity for iodine and thyroxine formation, are equally located in the C-terminal part of the chain. The hormone-forming regions localized at the opposite far ends of the thyroglobulin chain(s) likely represent zones more accessible to iodination and with a conformation suited for the coupling of iodotyrosine into iodothyronine residues and ultimately protease attack to release the free hormones into the circulation. The presence of hormonogenic sites of different affinities for iodine allows thyroglobulin to modulate adaptively its hormonogenic capacity to external iodine supply. The molecular mechanism of this process is still unknown.
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PMID:[Thyroglobulin and the biosynthesis of thyroid hormones]. 316 Apr 35

Thyroglobulin from colloid as well as from membrane fractions became radiolabeled upon incubation of calf thyroid slices with [35S]sulfate. The identity of the sulfate-labeled molecule was established by immunoprecipitation, polyacrylamide gel electrophoresis, Bio-Gel A-5m filtration, and DEAE-cellulose chromatography. Size analysis by gel filtration of [35S]glycopeptides and hydrazine-released oligosaccharides indicated that the sulfate was primarily located in the complex (unit B) carbohydrate units of thyroglobulin. Moreover, although [35S]sulfate-labeled oligosaccharides were cleaved by N-glycanase to the same extent as those labeled with [3H]mannose, they were not released by endo-beta-N-acetylglucosaminidase under conditions that led to the complete removal of polymannose carbohydrate (unit A). The failure of 35S-labeled glycopeptides and oligosaccharides to bind to immobilized Concanavalin-A indicated that the sulfate residues in calf thyroglobulin are located in carbohydrate units with three or more branches. No evidence for the occurrence of tyrosine sulfate was found upon examination of Pronase digests of radiolabeled thyroglobulin, and chemical analyses excluded the presence of this amino acid down to a level of 0.5 residues/polypeptide subunit. Studies with density gradient-separated membrane fractions as well as with puromycin indicated that sulfate addition is a late event in thyroglobulin biosynthesis which occurs in the Golgi compartment. Furthermore, it was observed that the nondimerized thyroglobulin subunit was much less sulfate labeled than the mature molecule. The location of the sulfated carbohydrate in a terminal portion of the calf thyroglobulin peptide chain was suggested by the observation that the subunit [mol wt (Mr) = 330,000] can undergo a transformation, presumably mediated by an endogenous protease, to a sulfate-free component (Mr = approximately 270,000) with the appearance of a 35S-labeled 60,000 Mr fragment; the release of a single sulfate-labeled peptide (Mr = 60,000) by mild trypsin treatment was consistent with a sequestration of sulfate groups in the thyroglobulin molecule.
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PMID:Biosynthesis of sulfated asparagine-linked complex carbohydrate units of calf thyroglobulin. 338 87

The coupling of iodotyrosine (coupling reaction) is one of the least studied in the formation of thyroid hormone, particularly in human thyroid diseases. This paper describes a method of measuring iodotyrosine coupling catalyzed by human thyroid peroxidase (TPO) in vitro. There were two important requirements to demonstrate the coupling reaction: 1) thyroglobulin with a low thyroid hormone content, and 2) partially purified TPO. Thyroglobulin with low thyroid hormone content was obtained from Grave's and follicular adenoma tissues after propylthiouracil (PTU) therapy and L-T4 therapy, respectively. TPO was prepared from Graves' thyroid by solubilizing the 100,000 X g pellet of thyroid homogenate with sodium deoxycholate and trypsin, followed by Sephacryl S-300 gel filtration. Before the coupling reaction, thyroglobulin was iodinated with chloramine-T and potassium iodide, followed by dialysis. The coupling reaction was carried out by incubating newly iodinated thyroglobulin with TPO, diiodotyrosine, a coupling stimulator, and a H2O2-generating system (glucose and glucose oxidase) for 20 min at 37 C. After thyroglobulin was digested with Pronase, the thyroid hormone content of the thyroid digest was measured by RIA. Coupling activity was measured by the amount of newly formed T3 (nanograms of T3 per mg thyroglobulin). The time course of coupling reaction showed a progressive increase in coupling activity up to 30 min, and the reaction was temperature and pH dependent, with a pH optimum of 7.0. Coupling activity in the presence of H2O2 and TPO was 43 +/- 5.0 ng T3/mg thyroglobulin (mean +/- SD of triplicate samples), and addition of diiodotyrosine to the H2O2-TPO system caused a nearly 3-fold increase in coupling activity. This method has potential utilization for measurement of peroxidase coupling activity, since there was a linear relationship between the measured coupling activity and the amount of added TPO when the TPO concentration was over 3 micrograms/300 microliter. Methimazole (MMI) and PTU had similar potencies in inhibiting the TPO-catalyzed coupling reaction, whereas MMI was distinctly more potent than PTU as an inhibitor of TPO-mediated iodination in vitro. The different potencies of MMI in the two reactions suggest that different inhibitory mechanisms may be involved in iodination and coupling. The reducing agent, sodium metabisulfite, was also found to be a more potent inhibitor of the TPO-mediated coupling reaction than of the TPO-mediated iodination reaction. The method of iodotyrosine coupling described here may be useful to investigate the coupling step of thyroid hormone formation in human thyroid diseases.
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PMID:Coupling of iodotyrosine catalyzed by human thyroid peroxidase in vitro. 383 97

The orientation of thyroid peroxidase in hog thyroid microsomes was studied by trypsin treatment, gel filtration, binding to Concanavalin A Sepharose and iodination of thyroglobulin. Trypsin treatment of microsomes did not solubilize the thyroid peroxidase activity completely but solubilized the NADPH-cytochrome c reductase activity almost completely. The apparent molecular size of thyroid peroxidase was not altered by trypsin treatment of microsomes. It was, however, decreased by the same treatment of deoxycholate-treated microsomes. On the other hand, the apparent molecular size of NADPH-cytochrome c reductase was reduced by trypsin without prior deoxycholate treatment. Thyroid peroxidase of microsomes did not bind to Concanavalin A Sepharose. Thyroglobulin added exogenously was not iodinated by microsomes, but endogenous thyroglobulin, which had been associated with microsomes, was iodinated. Similar results were obtained with rough microsomal membranes prepared from crude microsomes by sucrose density gradient centrifugation. These results suggest that thyroid peroxidase is oriented toward the luminal side of the microsomal vesicles.
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PMID:Orientation of thyroid peroxidase in hog thyroid microsomes. 661 7

Thyroglobulin is an iodinated glycoprotein (m.w. 660 kD) required for the storage and formation of thyroid hormone. Thyroglobulin was digested by trypsin in distilled water and the resulting peptides were identified by TOF-secondary ion mass spectrometry, using TFA as a matrix to catalyze the ionization of the peptides. Cryostate sections of pig thyroid glands were incubated with trypsin in distilled water, followed by deposition of TFA. The sections were analyzed with TOF-secondary ion mass spectrometry, and the peptides formed were identified through comparison with the peptides of the thyroglobulin reference sample. The thyroglobulin fragments were localized in the thyroid follicle cells with a spatial resolution of 3 microns, a mass resolution m/Delta m of >6000 and a mass accuracy of <60 ppm. The thyroglobulin was found localized heterogeneously in the follicle cells. The heterogeneity may be due to thyroglobulin synthesis, uptake and degradation or globules representing insoluble polymers of thyroglobulin considered to be a mechanism for storing hormone at high concentrations.
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PMID:High-resolution imaging and proteomics of peptide fragments by TOF-SIMS. 2018 56