Acid-induced conformational change in hog thyroglobulin

The molecular behavior of hog thyroglobulin in acid solutions has been examined by fluorescence, absorption, proton binding, and velocity centrifugation. The precipitation of thyroglobulin which normally occurs in the pH region near its isoelectric point was prevented by reducing the salt concentration to 0.01 m and the protein concentrations to the lowest levels needed for measurements. The rate of denaturation is very slow near pH 5.0 but increases rapidly with decreasing pH. The molecular properties of acid-denatured thyroglobulin, though still retaining some aspects of its native tertiary structure, are quite different from those of the native protein. In the molecular transition: (a) buried tryptophanyl residues become exposed, (b) the anomalous dissociation of certain groups becomes normalized, (c) subunits are formed, and (d) the molecular form of thyroglobulin and its subunits becomes partially unfolded.     

Cross-linking with dimethylsuberimidate to study thyroglobulin conformation

The present investigation demonstrates that the cross-linking agent, dimethylsuberimidate, is an usefull tool to study thyroglobulin structure. In fact, while reproducible and discrete polymerization products are obtained in strictly controlled conditions, valuable information on the native assemblage of thyroglobulin subunits and the effects of its major post-translational modification (iodination) on its structure, are reported.     

Synthesis of thyroglobulin in the polyribosome cell-free system of the thyroid gland]

Protein synthesis (in particular, thyroglobulin) is studied in a cell-free system containing polyribosomes of thyroid gland. After the incubation with radioactive label, ribosomes were centrifugated, supernatant was dialyzed against 0.05 M Tris-HCl buffer, pH 7.2 for a night, concentrated by ficol and centrifugated in 5-20% linear sucrose gradient. 14C-radioactivity of 19S fraction (thyroglobulin) was shown to comprise about 25% of total radioactivity. The rest radioactivity was found in 3--8S fractions. The distribution of the radioactivity as it was shown by polyacrylamide gel electrophoresis is as follows: 27S--11.0%; 19S--14.2%; 12S--5.8% and 4S--7.6% of total radioactivity in polyacrylamide gel. It is supposed that two successive processes take place in thyroid gland: a synthesis of thyroglobulin subunits and an exchange of new synthesized subunits with presynthesized ones.     

A comparative review of the structure and biosynthesis of thyroglobulin

Thyroglobulin, the major iodoglycoprotein of the thyroid (M_r 669 kDa) has a sedimentation coefficient of 19 S and an isoelectric point (pI) of 4.4–4.7. The protein has been isolated and purified from saline extracts of the gland of several animal species, by methods such as ammonium sulfate fractionation, DEAE-cellulose chromatography and Sepharose 4B/6B gel-filtration. DEAE-cellulose chromatography of thyroglobulin from many species, by linear gradient, yielded a complex elution pattern, while camel thyroglobulin showed only a major and minor peak. As an iodoprotein, the protein has 0.1–2.0% iodine. The amino acid and iodoamino acid composition of thyroglobulins, in general, is similar. However, a high thyroxine content (15 mol/mol protein) has been noted for buffalo species. Asparagine or aspartic acid has been reported as the major N-terminal amino acid for thyroglobulins of several animal species whereas glutamic acid is the sole N-terminal amino acid for buffalo thyroglobulin. As a glycoprotein, thyroglobulin contains 8–10% total carbohydrate with galactose, mannose, fucose, N-acetyl glucosamine and sialic acid residues. The carbohydrate in the protein is distributed as two distinct units, A and B. In addition, human thyroglobulin has carbohydrate unit C. The occurrence of sulfate and phosphate as Gal-3-SO₄ and Man-6-PO₄, respectively, has been reported in few species. The quaternary structure of native thyroglobulin is comprised of two equal sized subunits of 330 kDa. However, the protein appears to contain 4–8 non-identical units in few species. The synthesis of thyroid hormones occurs in the matrix of the protein and is regulated by pituitary thyrotropin. The role of tyrosine residues 5 and 130 in thyroxine synthesis has been well documented.     

Synthesis of iodoamino acids during in vitro thyroglobulin iodination in different states of its molecule]

Iodotyrosine and iodothyronine residues are formed in the protein molecule during bovine thyroglobulin iodination in vitro. Dissociation and reassociation of the thyroglobulin molecule have no significant influence on its iodoaminoacid composition. Thyroglobulin iodination in the presence of 8 M urea does not result in thyroxine synthesis despite the increased formation of iodotyrosine residues. Similarly, during iodination of reassociated thyroglobulin the new molecules of thyroxine are not formed either. It is presumed that during reassociation of thyroglobulin subunits the native conformation of the protein is not completely reconstituted. The results obtained suggest that the structure of thyroglobulin controls the distribution of the iodine atoms incorporated by the iodoaminoacid residues.     

Dissociation of thyroglobulin by tetraphenylborate ion

Purified bovine and ovine thyroglobulins (19 S) are partially dissociated into 12-S subunits after treatment with sodium tetraphenyl borate. The extent of dissociation obtained by sodium tetraphenyl borate or sodium dodecyl sulfate treatment is the same. The electrophoretic mobilities on acrylamide gels of sodium tetraphenyl borate-resistant molecules and of native thyroglobulin are identical. Sodium dodecyl sulfate-resistant molecules move more slowly than the native protein.     

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.     

Number and types of peptide chains in thyroglobulin: tryptic peptides of noniodinated hog thyroglobulin

In order to identify the number and types of peptide chains in thyroglobulin, noniodinated 19-S thyroglobulin obtained from goitrogen-treated hogs was exhaustively digested with trypsin (EC 3.4.4.4) after reduction and S-carboxymethylation. The digestion mixture was preliminarily separated into 30 fractions on Sephadex G-100 or G-15 and SE-Sephadex columns. The number of various tryptic peptides contained in each fraction was determined on peptide maps, where spots were detected with ninhydrin for total peptides and with each specific reagent for arginine, histidine or tyrosine-containing peptides. The number of total peptides observed in most of the fractions was estimated to be half the number of lysine plus arginine residues found in each fraction per mole of thyroglobulin, and the number of specific peptides was also close to half the number of each specific amino acid. These findings imply that thyroglobulin has 2-fold symmetry in the structure at the level of tryptic fragments and thus probably at the level of intact peptide chains.     

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)     

Characterization of phosphate residues on thyroglobulin

Follicular 19 S thyroglobulin (molecular weight 660,000) from rat, human, and bovine thyroid tissues contains approximately 10-12 mol of phosphate/mol of protein. These phosphate residues can be radiolabeled when rat thyroid hemilobes, FRTL-5 rat thyroid cells, or bovine thyroid slices are incubated in vitro with [32P]phosphate. Thus labeled, the [32P]phosphate residues comigrate with unlabeled 19 S follicular thyroglobulin on sucrose gradients and gel filtration columns; are specifically immunoprecipitated by an antibody preparation to rat or bovine thyroglobulin as appropriate; and co-migrate with authentic 19 S thyroglobulin when subjected to analytic or preparative gel electrophoresis. Tunicamycin prevents approximately 50% of the phosphate from being incorporated into FRTL-5 cell thyroglobulin. Approximately one-half of the phosphate in FRTL-5 cell or bovine thyroglobulin can also be released by enzymatic deglycosylation and can be located in Pronase-digested peptides which contain mannose, are endo-beta-N-acetylglucosaminidase H but not neuraminidase-sensitive, and release a dually labeled oligosaccharide containing mannose and phosphate after endo-beta-N-acetylglucosaminidase H digestion. The remainder of the phosphate is in alkali-sensitive phosphoserine residues (3-4/mol of protein) and phosphotyrosine residues (approximately 2/mol of protein). This is evidenced by electrophoresis of acid hydrolysates of 32P-labeled thyroglobulin and by reactivity with antibodies directed against phosphotyrosine residues. The phosphoserine and phosphotyrosine residues do not appear to be randomly located through the thyroglobulin molecule since approximately 75-85% of the phosphotyrosine and phosphoserine residues were recovered in a approximately 15-kDa tryptic peptide or a approximately 24-kDa cyanogen bromide peptide, each almost devoid of carbohydrate. 31P nuclear magnetic resonance studies of bovine thyroglobulin confirm the presence and heterogeneity of the phosphate residues on thyroglobulin preparations.     

Sulfation of thyroglobulin: A ubiquitous modification in vertebrates

Summary Mammalian thyroglobulin is released by thyroid follicle cells as a sulfated glycoprotein; the sulfate residues are mostly linked to tyrosine, but they are also attached to the high-mannose carbohydrate side-chains. To decide whether sulfation of thyroglobulin is confined to mammals, representatives of other vertebrate classes were analyzed for the presence of sulfated thyroglobulin: fish (trout), amphibians (clawed toad) and birds (chicken). Mini-organs were prepared from thyroid tissue and suspended in a ³⁵SO ₄ ^-- -containing culture medium. Light- and electron-microscope autoradiographs prepared from the mini-organs showed that thyroid follicle cells from all species examined incorporate ³⁵SO ₄ ^-- and synthesize a sulfated secretory product which accumulates in the follicle lumen. The Golgi complex was detected as the primary intracellular site of sulfate organification. The ³⁵SO ₄ ^-- -radiolabeled secretory product of all species was shown by polyacrylamide-gel-electrophoretic analyses to consist of thyroglobulin, identified by comparison with biosynthetically ¹²⁵I-labeled thyroglobulin. The results indicate that the sulfation of thyroglobulin is a ubiquitous post-translational modification observed already in the thyroglobulin of lower vertebrates. Our observations suggest that sulfation of thyroglobulin was acquired in the early stages of thyroid evolution.     

Process of iodination of thyroglobulin and its maturation. II. Properties and distribution of thyroglobulin labeled in vitro or in vivo with radioiodine, 3H-tyrosine, or 3H-galactose in rat thyroid glands.

With the aim of obtaining information on the process of iodination of thyroglobulin, the properties and subcellular distribution of thyroglobulin labeled with radioiodine, 3H-tyrosine, or 3H-galactose were studied. The following results were obtained for 17-19S thyroglobulin isolated from rat thyroid lobes labeled in vitro. (a) The effect of sodium dodecyl sulfate (SDS) concentration (0.1-2.0 mM) on the dissociability of the proteins into 12S subunits showed that 3H-labeled, 131I-labeled, and preformed thyroglobulin behaved very differently; their dissociability decreased in that order. In addition, 0.3 mM SDS is most suitable for discriminating among these species. (b) The amount of 0.3 mM SDS-resistant 131I-thyroglobulin increased with the time of incubation of the lobes or with the amount of iodine atoms incorporated by chemical iodination. (c) Digestion of 3H-tyrosine-labeled thyroglobulin showed that 3H-monoiodotyrosine and 3H-diiodotyrosine were present after incubation of the lobes for 180 min. (d) The dissociability of 3H-galactose-labeled 17-19S thyroglobulin was higher than that of 131I-labeled protein, but its elution pattern on DEAE-cellulose chromatography resembled that of the latter. (e) 131I-Thyroglobulin was scarcely found in the incubation medium, although a considerable amount of 19S thyroglobulin was released into the medium during the incubation. As for the lobes, a significant amount of 131I-radioactivity as well as 3H-radioactivity was found in cytoplasmic particulates, especially in fractions containing apical vesicles and rough microsomes. On the other hand, the following results were obtained for 17-19S thyroglobulin isolated from rats injected with 125I. (a) Dissociability of the protein by 0.3 mM SDS and analysis of 125I-iodoamino acids of pronase digest showed that the iodination process was essentially similar to the case of in vitro incorporation, but was faster. (b) The effect of cyclohiximide treatment showed that the relative reduction of 0.3 mM SDS dissociable species was probably due to a shortage of newly synthesized proteins. All the results obtained in the present experiments are compatible with the view that iodine atoms are incorporated selectively into newly synthesized, less iodinated thyroglobulin, and that the iodination occurs intracellularly, at least to a certain degree, after carbohydrate attachment, probably in the apical vesicles. The possibility that iodination also occurs to some extent in the endoplasmic reticulum and in the colloid lumen of thyroglobulin-stimulated thyroids is discussed.     

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.     

Properties of thyroglobulin. XII. Comparison of the configurational states of reduced and unreduced thyroglobulin

The relaxation time of thyroglobulin has been determined in water at. neutral pH, in concentrated urea and guanidine solutions, at alkaline pH, both before and after reduction with β-mercaptoethanol. The structure of thyroglobulin in concentrated urea solutions is markedly affected by the pH, Time-dependent changes occur in thyroglobulin in concentrated urea or guanidine solutions which arc observable by polarization of fluorescence but not by optical rotation or viscosity. The reduction of the disulfide crosslinks of thyroglobulin in urea at high pH or in guanidine produces linear polypeptide chains with few if any permanent contacts between segments.     

Hormonogenic donor Tyr2522 of bovine thyroglobulin. Insight into preferential T3 formation at thyroglobulin carboxyl terminus at low iodination level

A tryptic fragment (b5_TR,NR), encompassing residues 2515–2750, was isolated from a low-iodine (0.26% by mass) bovine thyroglobulin, by limited proteolysis with trypsin and preparative, continuous-elution SDS–PAGE. The fragment was digested with Asp-N endoproteinase and analyzed by reverse-phase HPLC electrospray ionization quadrupole time-of-flight mass spectrometry, revealing the formation of: 3-monoiodotyrosine and dehydroalanine from Tyr2522; 3-monoiodotyrosine from Tyr2555 and Tyr2569; 3-monoiodotyrosine and 3,5-diiodotyrosine from Tyr2748. The data presented document, by direct mass spectrometric identifications, efficient iodophenoxyl ring transfer from monoiodinated hormonogenic donor Tyr2522 and efficient mono- and diiodination of hormonogenic acceptor Tyr2748, under conditions which permitted only limited iodination of Tyr2555 and Tyr2569, in low-iodine bovine thyroglobulin. The present study thereby provides: (1) a rationale for the preferential synthesis of T3 at the carboxy-terminal end of thyroglobulin, at low iodination level; (2) confirmation for the presence of an interspecifically conserved hormonogenic donor site in the carboxy-terminal domain of thyroglobulin; (3) solution for a previous uncertainty, concerning the precise location of such donor site in bovine thyroglobulin.     

Evidence that thyroglobulin contains nonidentical half molecule subunits

Bovine thyroglobulin was extracted from unfrozen glands, purified by sucrose gradient centrifugation, and fractionated into a narrow range in iodine content by RbCl isopycnic centrifugation. The subunit composition of these preparations was studied by sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis. The extent of dissociation of 19 S into 12 S half-molecules followed the known relationship with iodine, i.e. decreased dissociability of 19 S with increased iodine content. The undissociated 19 S band always consisted of three closely spaced, equidistant bands. Reduction of the disulfide bonds of thyroglobulin by mercaptoethanol in SDS solution resulted in the formation of two major and one minor components (S, F, and A). The concentration of A was always less than 10% of the total. The ratio of S to F was, however, about equal in thyroglobulin preparations which ranged in iodine content from 0.2 to 1%. The final ratios were obtained before all the disulfides were reduced. The relative mobilitis of S, F, and A, decreased with increasing extent of reduction. Fully reduced S and F, but not A, migrated slower than unreduced 12 S. The three reduced alkylated polypeptides were purified by preparative SDS-polyacrylamide gel electrophoresis and their molecular weights were determined by sedimentation equilibrium in 8 M urea. Their Mw and Mz values agreed closely with that of the unreduced 12 S half-molecule subunit, thus indicating that reduction of the disulfide bonds changes the shape but not the molecular weights of the subunits.     

Defective splicing of thyroglobulin gene transcripts in the congenital goitre of the Afrikander cattle

The structure of thyroglobulin mRNA was analyzed in an inbred herd of Afrikander cattle with hereditary goitre. Northern transfer of RNA from affected animals revealed both a shorter (approximately 7100 bases) and a normal-sized (approximately 8200 bases) thyroglobulin mRNA when hybridized to bovine thyroglobulin cDNA clones. S1 nuclease mapping experiments established that 1100 bases are deleted in the 5' region of the smaller mRNA. Electron microscopy of RNA from animals with goitre hybridized to a bovine genomic DNA clone showed that the region deleted corresponds to exon 9 of the thyroglobulin gene. Southern blot analysis of the exon 9 region revealed differences between affected and control animals with the enzymes PstI and TaqI. Although they could reflect a linkage disequilibrium between the mutation and restriction fragment length polymorphism, it is noteworthy that these differences map in the region of the exon 9/intron 9 junction. Our results show that a genetic lesion in the thyroglobulin gene causes aberrant splicing of the pre-mRNA, and suggest that the responsible mutation is at the exon 9/intron 9 junction.     

The effect of monensin on thyroglobulin secretion

The effect of monensin on the secretion of thyroglobulin was studied in open follicles isolated from pig thyroid tissue; in this system, thyroglobulin is secreted into the incubation medium. When monensin was present during a 4-h chase incubation after pulse-labelling with 3H-leucine, the secretion of labelled thyroglobulin was reduced by about 85%; in electron-microscopic autoradiographs of rat thyroid lobes labelled and chase-incubated under similar conditions the relative number of grains over follicle lumina was strongly reduced when monensin was present during the chase. These observations are in agreement with the consensus that monensin arrests transport of secretory proteins in the Golgi complex. In other experiments, pulse-labelled follicles were chase-incubated for 1.5 h whereby labelled thyroglobulin was transported from the RER to exocytic vesicles. Monensin present during a subsequent chase of 0.5 h caused only a moderate decrease of labelled thyroglobulin secretion. TSH present during the second chase-stimulated secretion in both control and monensin-exposed follicles. TSH also caused a drastic reduction of exocytic vesicles in rat thyroid lobes, and the number of vesicles remaining in the cells was the same in controls and lobes exposed to the ionophore. The observations are interpreted to show that monensin does not inhibit the basal or TSH-stimulated transport of thyroglobulin from the site of monensin-induced arrest in the Golgi complex to the apical cell surface or the exocytosis of thyroglobulin.