Secretion of sulfated thyroglobulin

Thyroid follicle cells from various mammalian species incorporate 35-SO4(2-). Light and electron microscopic autoradiographs show that the Golgi complex is the predominant site of sulfate incorporation and that the secretory product accumulating in the follicle lumen is sulfated. In order to determine which components of the luminal content carry the sulfate residues, inside-out follicles from pig thyroid glands were incubated in the presence of 35-SO4(2-) and the secretory product released into the culture medium was analyzed by polyacrylamide gel electrophoresis. The observations show that the secretory product consists of sulfated thyroglobulin and that approximately 13 sulfate residues are bound covalently to 1 molecule of dimeric thyroglobulin. Digestion of 35-SO4(2-)-thyroglobulin with endoglycosidase H removes 20 to 30% of the radioactivity, indicating that the high mannose carbohydrate side chains carry sulfate residues. The complex carbohydrate side chains are apparently free of sulfate since treatment with endoglycosidase D did not alter the sulfate content. About 2/3 of the sulfate is cleaved by hydrolysis with 1 M HCl (5 min, 95 degrees C) indicating the presence of tyrosine sulfate. Part of the sulfate is exposed and presumably located on the surface of the thyroglobulin molecule as suggested by the direct accessibility of 35-SO4(2-)-thyroglobulin to digestion with sulfatases. The sulfate residues contribute to the anionic state of thyroglobulin. It is postulated that the sulfate residues operate in the regulation of thyroglobulin transport in the cell and in the tight packaging of thyroglobulin in the follicle lumen.     

The subunits of thyroglobulin

1. Pig thyroglobulin was reduced with dithiothreitol in the presence of sodium dodecyl sulphate, 8m-urea or 6m-guanidinium chloride. 2. The molecular weights of the reduction products were about 165000. 3. Two stable subunits with molecular weights as low as 35000 and 20000 were separated by Sephadex chromatography after prolonged exposure of the reduction products to sodium dodecyl sulphate at pH8.7. Although a hydrolytic reaction is probably implicated, the nature of the chemical linkages broken was not established.     

N-terminal groups of buffalo thyroglobulin

N-Terminal analysis of purified buffalo thyroglobulin by the fluorodinitrobenzene method of Sanger yielded about 1.5 moles of DNP-glutamic acid per mole of buffalo thyroglobulin. No water-soluble DNP-amino acid was detectable as N-terminal. The presence of glutamic acid has been confirmed by Edman degradation and characterization of the PTH-amino acid in different solvent systems, and also after regeneration of free amino acid from PTH-amino acid in butanol-acetic acid-water (4:1:5, v/v) system. This is in contrast to the occurrence of aspartic acid or asparagine as N-terminals for several other mammalian thyroglobulins.     

Restriction mapping of synthetic thyroglobulin structural gene as a means of investigating thyroglobulin structure

Bovine 33 S thyroglobulin mRNA was reverse transcribed into double-stranded DNA under conditions allowing the synthesis of a complete 8 kilobase pair copy. A physical map of the resulting synthetic thyroglobulin structural gene was constructed using six restriction endonucleases. The following conclusions could be drawn: (i) the polypeptide chains in thyroglobulin subunits are identical; (ii) thyroglobulin is composed of a major class of molecules sharing the same primary structure; (iii) there is no evidence for precise internal repetition in the structure of thyroglobulin subunits.     

In vitro studies of the thyroglobulin degradation pathway: endocytosis and delivery of thyroglobulin to lysosomes, release of thyroglobulin cleavage products--iodotyrosines and iodothyronines

Iodinated thyroglobulin stored in the thyroid follicular lumen is subjected to an internalization process and thought to be transferred into the lysosomal compartment for proteolytic cleavage and thyroid hormone release. In the present study, we have designed in vitro models to study: 1) the transfer of endocytosed thyroglobulin into lysosomes, and 2) the intracellular fate of free thyroid hormones and iodinated precursors generated by intralysosomal proteolysis of thyroglobulin. Open follicles prepared from pig thyroid tissue by collagenase treatment were used to probe the delivery of exogenous thyroglobulin to lysosomes via the differentiated apical cell membrane. Open follicles were incubated with pure [125I]thyroglobulin with or without unlabeled thyroglobulin in the presence or in the absence of chloroquine. Subcellular fractionation on a Percoll gradient showed that [125I]thyroglobulin was internalized and present in low (for the major part) and high density thyroid vesicles. In chloroquine-treated open follicles, we observed the appearance of a definite fraction of [125I]thyroglobulin in a lysosome subpopulation having the expected properties of phagolysosomes or secondary lysosomes. In contrast, in control open follicles, the amount of [125I]thyroglobulin or degradation products found in high density vesicles was lower and associated with the bulk of lysosomes, i.e., primary lysosomes. The content in thyroglobulin and degradation products of lysosomes at steady-state was analyzed by Western blot using polyclonal anti-pig thyroglobulin antibodies. Under reducing conditions, immunoreactive thyroglobulin species correspond to polypeptides with molecular weights ranging from 130,000 to less than 20,000. The presence of free thyroid hormones and iodotyrosines inside lysosomes and their intracellular fate was studied in dispersed thyroid cells labeled with [125I]iodide. Neo-iodinated [125I]thyroglobulin gave rise to free [125I]T4 which was secreted into the medium. In addition to released [125I]T4, a fraction of free [125I]T4 was identified inside the cells. Lysosomes isolated from dispersed thyroid cells did not contain significant amounts of free [125I]T4. The free intracellular [125I]T4 fraction seems to represent an intermediate 'hormonal pool' between thyroglobulin-bound T4 and secreted T4. Evidence for such a precursor-product relationship was obtained from pulse-chase experiments. In conclusion: 1) open thyroid follicles have the ability to internalize thyroglobulin by a mechanism of limited capacity and to address the endocytosed ligand to lysosomes.(ABSTRACT TRUNCATED AT 400 WORDS)     

Production of anti-human thyroglobulin and anti-thyroid hormone antibodies in rabbits immunized with human thyroglobulin

Two rabbits (TG-1, TG-2) were immunized with human thyroglobulin (HTg) and bled serially. Antisera were obtained at different times after the first immunization and kept separately and studied. In both rabbits production of anti-HTg, and anti-thyroid hormone antibodies such as anti-thyroxine (T4) and anti-triiodothyronine (T3) antibodies was observed. Binding parameters of anti-HTg antibodies with HTg, T4, and T3 were calculated in two selected antisera (70-day and 249-day). The Scatchard's plots of these antibodies were all curve-linear and were analyzed in two components: one, higher binding constant (Ka1) and smaller binding capacity (Cap1) and the other, lower binding constant (Ka2) and larger binding capacity (Cap2). Ka1 values of anti-HTg, anti-T4, and anti-T3 antibodies in sera from TG-1 obtained from 70-day and 249-day bleeding were 1.1 X 10(10) M-1, 6.0 X 10(9) M-1. 7.9 X 10(8) M-1 and 1.7 X 10(10) M-1, 6.5 X 10(9) M-1, 1.0 X 10(9) M-1, respectively. Those from TG-2 were 1.7 X 10(10) M-1, 1.8 X 10(9) M-1, 6.4 X 10(8) M-1 and 2.0 X 10(10) M-1, 3.1 X 10(9) M-1, 1.6 X 10(9) M-1, respectively. The significance of the production of anti-HTg and anti-thyroid hormone antibodies in rabbits immunized with HTg in relation to the antigenic structure of HTg molecule was discussed.