Sulfate transport in porcine thyroid cells. Effects of thyrotropin and iodide.

In porcine thyroid cells, thyroglobulin sulfation is controlled by thyrotropin (TSH) and iodide, which contribute to regulating the intracellular sulfate concentration, as we previously established. Here, we studied the transport of sulfate and its regulation by these two effectors. Kinetic studies were performed after [(35)S]sulfate was added to either the basal or apical medium of cell monolayers cultured without any effectors, or with TSH with or without iodide. The basolateral uptake rates were about tenfold higher than the apical uptake rates. TSH increased the basolateral and apical uptake values (by 24 and 9%, respectively, compared with unstimulated cells), and iodide inhibited these effects of TSH. On the basis of results of the pulse-chase experiments, the basolateral and apical effluxes appeared to be well balanced in unstimulated cells and in cells stimulated by both TSH and iodide: approximately 40-50% of the intracellular radioactivity was released into each medium, whereas in the absence of iodide, 70% of the intracellular radioactivity was released on the basolateral side. The rates of transepithelial sulfate transport were increased by TSH compared with unstimulated cells, and these effects decreased in response to iodide. These results suggest that TSH and iodide may each control the sulfate transport process on two sides of the polarized cells, and that the absence of iodide in the TSH-stimulated cells probably results in an unbalanced state of sulfate transport.

Regulation of thyroid cell volumes and fluid transport: opposite effects of TSH and iodide on cultured cells.

Cell volume regulation by thyrotropin (TSH) and iodide, the main effectors involved in thyroid function, was studied in cultured thyroid cells. The mean cell volume, determined by performing 3-D reconstitution on confocal microscopy optical slices from living octadecylrhodamine-labeled cells cultured with both TSH and iodide (control cells), was 3.73 +/- 0.06 pl. The absence of iodide resulted in cell hypertrophy (136% of control value) and the absence of TSH in cell shrinkage (81%). These changes mainly affected the cell heights. The effect of TSH on cell volume was mediated by cAMP. The proportion of cytosolic volume (3-O-methyl-D-glucose space vs. total volume) decreased in the absence of iodide (85% of control value) and increased in the absence of TSH (139%), whereas protein content showed the opposite changes (121 and 58%, respectively). The net apical-to-basal fluid transport was also inversely controlled by the two effectors. Iodide thus antagonizes TSH effects on cell volumes and fluid transport, probably via adenylylcyclase downregulation mechanisms. The absence of either iodide or TSH may mimic the imbalance occurring in pathological thyroids.

Sulfated tyrosines of thyroglobulin are involved in thyroid hormone synthesis.

Thyroid hormone synthesis is under the control of thyrotropin (TSH), which also regulates the sulfation of tyrosines in thyroglobulin (Tg). We hypothesized that sulfated tyrosine (Tyr[S]) might be involved in the hormonogenic process, since the consensus sequence required for tyrosine sulfation to occur was observed at the hormonogenic sites. Porcine thyrocytes, cultured with TSH but without iodide in the presence of [(35)S]sulfate, secreted Tg which was subjected to in vitro hormonosynthesis with increasing concentrations of iodide. A 63% consumption of Tyr[S] (1 residue) was observed at 40 atoms of iodine incorporated into Tg, corresponding to a 40% hormonosynthesis efficiency. In addition, hyposulfated Tg secreted by cells incubated with sodium chlorate was subjected to in vitro hormonosynthesis. With 0.5 Tyr[S] residue (31% of the initial content), the efficiency of the hormonosynthesis was 29%. In comparison, when hormonosynthesis was performed by cells, with only 0.25 Tyr[S] residue (16% of the initial content), the hormonosynthesis efficiency fell to 18%. These results show that there exists a close correlation between the sulfated tyrosine content of Tg and the production of thyroid hormones.

Thyrotropin regulates tyrosine sulfation of thyroglobulin.

OBJECTIVE: To study the regulation of thyroglobulin sulfation by thyrotropin (TSH) and iodide. Sulfation, a widespread post-translational modification of proteins, is involved in various biological activities. Thyroglobulin has been reported to be sulfated but, to date, the role of sulfate residues in the metabolism and function of thyroglobulin is not known; moreover, the regulation of thyroglobulin sulfation has not been yet investigated. METHODS: The effect of TSH on thyroglobulin sulfation was studied in porcine thyroid cells cultured on porous collagen-coated filters. Cells cultured with or without TSH and with or without iodide (KI) were incubated for 4 days with radioactive sulfate. The specific radioactivity of thyroglobulin subunit (330kDa) was determined from apical media analyzed by electrophoresis. Enzymatic hydrolysates of the purified thyroglobulin were separated by oligosaccharide affinity chromatography and thin-layer chromatography; alkaline hydrolysates were analyzed only by thin-layer chromatography. RESULTS: Thyroglobulin secreted by TSH-stimulated cells incorporated about twofold less radioactive sulfate. Iodide slightly modified this incorporation. Enzymatic hydrolysates of purified thyroglobulin showed sulfate residues bound essentially to complex oligosaccharide units. Alkaline hydrolysis was necessary to release all sulfated amino acids (tyrosine and serine). In the absence of TSH the proportion of tyrosine sulfate was dramatically increased: 24% compared with 7% (+KI) or 5% (-KI). The ratio of specific radioactivity of thyroglobulin to the specific radioactivity of intracellular inorganic sulfate (determined in each culture condition) gave the number of sulfated residues incorporated: 46 (-TSH) and 31 (+TSH) per mol thyroglobulin. From this distribution, we deduced the number of residues bound to complex oligosaccharide units and to tyrosine. Thus TSH decreased the number of sulfate residues on tyrosine from 11 to 2 per mol thyroglobulin. CONCLUSIONS: TSH regulates the binding of sulfate groups to tyrosine residues. Iodide exerts a slight control over this process.

Thyroid hormone synthesis in thyroglobulin secreted by porcine thyroid cells cultured on porous bottom chambers. Effect of iodide.

The long-term iodination of thyroglobulin secreted into the apical medium of thyroid cells cultured as monolayers on porous bottom chambers reached 5.87 +/- 1.66 atoms of iodine/mol thyroglobulin after 11 days incubation in the presence of TSH (0.1 mU/ml) and iodide (0.5 microM) in the basal medium. This iodinated thyroglobulin contained thyroid hormones (T3 + T4) which involved 22.7% of the thyroglobulin iodine content. The iodoamino acid content was, in residues per mole, 2.2 +/- 0.35 for monoiodotyrosine, 0.74 +/- 0.04 for diiodotyrosine, 0.23 +/- 0.04 for T4, and 0.098 +/- 0.02 for T3. Kinetic studies showed that a minimal level of iodination (2.05 +/- 0.26 atoms iodine/mol thyroglobulin) was necessary for hormonogenesis. A maximal level of iodination and hormonogenesis was obtained with 0.5 microM iodide added daily to the basal medium. In these conditions, hormonogenesis efficiency reached about 40% (a value close to this one observed in vivo). Above 0.5 microM iodide, both iodination and T4 synthesis were inhibited (28.3% and 73.9%, respectively, for 1 microM iodide). Our culture system makes it possible to demonstrate that this high iodide concentration in the basal medium did not increase apical iodide concentration above 10 microM but decreased apical thyroglobulin concentration. The inhibitory effect of iodide on hormonogenesis cannot be due to a competition with tyrosine residues of thyroglobulin for their binding to thyroperoxidase although it could be related, at least in part, to a decrease in protein synthesis.

Hormonogenesis in thyroid cells cultured on porous bottom chambers.

Different processes implied in thyroid hormonogenesis (thyroglobulin, thyroperoxidase and hydrogen peroxide generating system expressions) and their regulation by TSH and iodide have been studied using porcine thyroid cells cultured in porous bottomed chambers. This system allowed to reproduce the functional bipolarity. Cells form a tight and polarized monolayer. Both apical and basolateral poles of epithelial cells were independently accessible and the cell layer separated two compartments which can contain different media. A major polarized secretion of thyroglobulin into the apical compartment was observed; it was increased in the presence of TSH as well as the thyroglobulin synthesis and mRNA level. These TSH effects were the consequence of adenylcyclase stimulation. Active transport of iodide, iodination of thyroglobulin and hormonosynthesis took place only in the presence of TSH. These steps occurred at the apical pole of cells. In the culture chamber system, thyroglobulin was weakly iodinated (6 atoms of iodide per mole of thyroglobulin; in vivo up to 40 atoms per mole) but hormonogenesis efficiency was close to this one observed in vivo (40%). Iodide concentrations higher than 0.5 microM daily added to the basal medium inhibited iodination of thyroglobulin and hormonosynthesis. Some components contained in culture media were inhibitors for iodination when they were present in the apical medium such as vitamins, amino acids and phenol red. The culture system appears to be interesting for pharmacological and toxicological studies.

Hormone formation in the isolated fragment 1-171 of human thyroglobulin involves the couple tyrosine 5 and tyrosine 130.

The 22 kDa fragment (Asn1-Met171) purified from iodine-poor human thyroglobulin (hTg) is capable by itself to synthesize thyroxine at Tyr5, the preferential hormonogenic acceptor site of the protein, after iodination in vitro. To identify the corresponding donor site in this model we studied the fate of the six Tyr residues present in the 22 kDa peptide after in vitro hormone synthesis. Structural studies of the tyrosyl peptides showed that Tyr5 was the only thyroxine-forming site, the other tyrosines (29, 89, 97 and 107) were noniodinated and Tyr130 was recovered in alanine form after CNBH4 treatment of the Tyr130-containing peptide. Taking into account that alanine could arise from aminoreduced pyruvate species, these results showed that in the 22 kDa fragment (1) hormone formation involves the couple Tyr5 (acceptor)-Tyr130 (donor), and (2) dehydroalanine, the resultant product of donor tyrosine after hormone synthesis, has evolved in pyruvoyl form. To test whether Tyr130 could also act as donor in hTg hormone synthesis, the 22 kDa peptide was isolated from hTg iodinated under conditions leading to iodotyrosine formation followed or not by hormone formation and the tyrosyl peptides were analyzed. After hTg iodination and before coupling (i.e. hormone synthesis) only Tyr5 and Tyr130 were recovered in iodotyrosine form; after coupling thyroxine was found at Tyr5 whereas Tyr130 disappeared. Taken together these results, correlated with the previously reported cleavage of hTg chain at Tyr130 occurring during in vivo hormone synthesis, support the theory that the couple Tyr5 (acceptor)-Tyr130 (donor) would be the preferential hormonogenic site in human Tg.

Characterization of the two oligosaccharides present in the preferential hormonogenic domain of human thyroglobulin.

The N-terminal fragment of human thyroglobulin (residues 1 to 171) contains the preferential hormonogenic site of the molecule and 2 potential sites of N-glycosylation (Asn57 and Asn91). This fragment was isolated from a human thyroglobulin purified from a single goiter. The tryptic peptides bearing the glycosylation sites were separated by Bio-Gel P-30 and HPLC columns. The oligosaccharides borne at each site were analyzed, after tritium labeling, by concanavalin A-Sepharose and HPLC. At both sites the structures observed are heterogenous, with a majority of biantennary complex type structures.

Hormone synthesis in human thyroglobulin: possible cleavage of the polypeptide chain at the tyrosine donor site.

At moderate iodination levels (20 iodine atoms/mol) human thyroglobulin (hTg) produces after reduction a hormone-rich peptide of 26 kDa which contains the preferential hormonogenic 'acceptor' tyrosine (Tyr 5) of the protein. The site of cleavage of the hTg chain was demonstrated by analysis of the 26 kDa tryptic hydrolysis products. It consistently yielded the peptide Gln-82-Val-129 which consequently made it possible to localize the hTg chain cleavage at tyrosine residue 130. Evidence for tyrosine involvement in hTg cleavage during thyroid hormone formation supports the hypothesis that peptide bond cleavage would occur at the 'donor' tyrosine residue and suggests that tyrosine 130 would be the donor site reacting with the major hormone-forming acceptor site (Tyr 5) of hTg.

Characterization of a hormonogenic domain from human thyroglobulin.

A polypeptide domain of molecular mass near 22 kDa was purified from CNBr-digest of iodine poor human thyroglobulin (hTgb). This fragment represents the N-terminal part of the hTgb molecule and consequently contains the preferential hormonogenic tyrosine 'acceptor' of the protein. This fragment could correspond to the non-iodinated and unreduced form of the thyroxinyl-containing 26 kDa peptide previously purified from reduced and iodinated hTgb. This 22 kDa fragment is capable by itself, i.e. independently of the remaining hTgb molecule, of synthesizing thyroxine with a high efficiency after in vitro iodination. Its study should constitute a valuable way to identify at least one of the hormonogenic tyrosine 'donor' residues of hTgb.

Amino acid sequence and disulfide bridges of subunit III, a defective endopeptidase present in the bovine pancreatic 6 S procarboxypeptidase A complex.

The sequence of the 240 amino acids and the position of the five S-S bridges of subunit III of the bovine pancreatic 6 S procarboxypeptidase A complex have been determined thus confirming its phylogenetic filiation with the pancreatic serine endopeptidase group. The subunit contains at equivalent positions all the elements of the catalytic site of these enzymes. The elements of a binding pocket very similar to that of porcine elastase I are also present in the protein thus accounting for its zymogen-like activity. The most obvious difference is the absence in the subunit of the two strongly hydrophobic amino acids (16 and 17 in the chymotrypsinogen numbering), which are known to participate in the stabilization of a fully functional binding pocket in active endopeptidases. Four of the five disulfide bridges of subunit III are homologous with those common to all pancreatic endopeptidases. In contrast the fifth bridge forms a very small loop of only four amino acids, which is not encountered in active endopeptidases. Other potentially lethal modifications in the structure of the subunit are not excluded.