Biosynthesis of thyroglobulin. Incorporation of [1-14C] galactose, [1-14C] manose and [4,5-3H2] leucine into soluble proteins by rat thyroids in vitro

A comparative review of the structure and biosynthesis of thyroglobulin

Thyroglobulin, the major iodoglycoprotein of the thyroid (Mr 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.

Transporters of nucleotide sugars, ATP, and nucleotide sulfate in the endoplasmic reticulum and Golgi apparatus

The lumens of the endoplasmic reticulum and Golgi apparatus are the subcellular sites where glycosylation, sulfation, and phosphorylation of secretory and membrane-bound proteins, proteoglycans, and lipids occur. Nucleotide sugars, nucleotide sulfate, and ATP are substrates for these reactions. ATP is also used as an energy source in the lumen of the endoplasmic reticulum during protein folding and degradation. The above nucleotide derivatives and ATP must first be translocated across the membrane of the endoplasmic reticulum and/or Golgi apparatus before they can serve as substrates in the above lumenal reactions. Translocation of the above solutes is mediated for highly specific transporters, which are antiporters with the corresponding nucleoside monophosphates as shown by biochemical and genetic approaches. Mutants in mammals, yeast, and protozoa showed that a defect in a specific translocator activity results in selective impairments of the above posttranslational modifications, including loss of virulence of pathogenic protozoa. Several of these transporters have been purified and cloned. Experiments with yeast and mammalian cells demonstrate that these transporters play a regulatory role in the above reactions. Future studies will address the structure of the above proteins, how they are targeted to different organelles, their potential as drug targets, their role during development, and the possible occurrence of specific diseases.

Effect of cooling on intracellular transport and secretion of thyroglobulin

The effect of cooling to 20 degrees C on the intracellular transport and secretion of thyroglobulin was studied by incubating open thyroid follicles isolated from porcine thyroid tissue. Follicles were labeled with 3H-leucine or 3H-galactose and the secretion of labeled thyroglobulin into the incubation medium was followed by chase incubations under various experimental conditions. The observations indicate that the transport of thyroglobulin is inhibited at three sites of the intracellular pathway by cooling to 20 degrees C, i.e., between the RER cisternae and the Golgi cisternae, between the latter and the exocytic vesicles, and between these vesicles and the extracellular space (corresponding to the follicle lumen). The secretion of 3H-leucine-labeled thyroglobulin decreased linearly between 37 degrees and 20 degrees C; within this temperature range the activation energy for secretion, calculated from Arrhenius plots, was found to be 37 kcal/mol. Below 20 degrees C the secretion was scarcely measurable. It is suggested that the three transport blocks at 20 degrees C result mainly from inhibition of membrane fission and fusion due to phase transition in membrane lipids.

The biosynthetic pathway of the asparagine-linked oligosaccharides of glycoproteins

This review deals with the structure and addition of the different types of oligosaccharides to asparagine residues in proteins. This process occurs in several steps, first an oligosaccharide which contains N-acetylglucosamine mannose and glucose is built up joined to dolichyl diphosphate. The oligosaccharide is then transferred to a polypeptide chain, loses its glucose, and is modified by removal of some monosaccharides and addition of others giving rise to a variety of saccharides.

Immunochemical and immunohistochemical studies on the 27 S iodoprotein of dog thyroid with reference to thyroglobulin-like reaction of the parafollicular cells

Our earlier finding that the thyroglobulin-like material responsible for the immunoreaction of parafollicular cells obtained in peak I fraction of Bio-Gel A-5m was followed up in the present study by an investigation of the immunochemical and immunohistochemical reactions of 27 S iodoprotein which was the most prominent material in the peak I fraction. The antibody was raised against completely purified 27 S iodoprotein which was obtained as follows: Thyroglobulin was extracted from dog thyroids and chromatographed initially on Bio-Gel A-5m and then on Bio-Gel A-50m. The area of 27 S migrated as a single bank on polyacrylamide gel slab electrophoresis. This was cut and eluted. Anti-27 S antiserum showed the same immunochemical patterns to 27 S and 19 S as anti-19 S antiserum with three different immunochemical methods: double diffusion test, one dimensional and two dimensional immunoelectrophoresis. The immunoperoxidase reactions of the anti-27 S antiserum and anti-19 S antiserum were restricted to follicular cells and luminal colloids. No reaction of the parafollicular cells was obtained by these antisera. Thus, 27 S iodoprotein shared common immunochemical and immunohistochemical properties with 19 S thyroglobulin. It was concluded that 27 S iodoprotein was not responsible for the thyroglobulin-like reaction of the parafollicular cells.

C cell (parafollicular cell) -- immunoreactive thyroglobulin: purification, identification and immunological characterization

In relation to our earlier finding that the thyroglobulin-like material responsible for the cytochemical immunoreaction of C cells was obtained in the peak I fraction of Bio-Gel A-5 m, which included faster sedimenting components of thyroglobulin, the present study has identified the positive reacting component and clarified its immunochemical and immunohistochemical properties. 1. The peak I fraction of dog and hog thyroglobulin was chromatographed on a Bio-Gel A-50 m column. Antiserum to the faster eluted peak I'1 only immunoreacted with C cells. The peak I'1 was then refiltered on Bio-Gel A-150 m column. Antiserum to peak I''1 fraction of both species which was eluted in the first part had high immune specificity for C cells. 2. When 4-30% and 2-16% continuous gradient gels of polyacrylamide were employed, peak I''1 represented a single electrophoretic band corresponding to the component with the largest molecular weight in thyroglobulin. The protein was named C-thyroglobulin. The molecular weight was approximately 2,600,000, four times as large as 19 S, as calculated by relative mobility on the 2-16% gradient gel. 3. In double diffusion tests, anti-peak I''1 antiserum produced two immunoprecipitin lines with its own antigen. The reaction was different from that of anti-19 S antiserum which formed a single line. 4. On immunoperoxidase staining, anti-peak I''1 antiserum reacted to C cells in exactly the same way as anti-calcitonin antiserum. 5. When anti-peak I''1 antiserum was absorbed with calcitonin, the subsequent reaction of the C cells was greatly decreased. The absorption of anti-calcitonin antiserum with increased amounts of peak I''1 abolished the C cell reaction. On the basis of these observations, the possibility that C-thyroglobulin is a biosynthetic precursor of calcitonin exists.

Cytochemical localization of complex carbohydrates in the thyroid gland of normal and TSH-treated mice

The silver methenamine method for the ultrastructural localization of carbohydrates and glycoproteins was applied to the thyroid glands of normal and TSH-treated mice. The majority of the cisternae of the rough endoplasmic reticulum showed a weak, but apparently positive reaction. These findings support the opinion that glycosylation of thyroglobulin occurs initially in the rough endoplasmic reticulum. By this method the Golgi apparatus was observed to display a staining gradient. The intermediate to inner saccules were intensely stained, whereas the outer saccules were not so heavily stained. This phenomenon indicates that the Golgi apparatus has a functional polarity for the addition of carbohydrates to thyroglobulin and other proteins. In the inner and/or the peripheral regions of the Golgi apparatus and in the apical cytoplasm, a large number of globules of various sizes, considered to be colloid droplets, lysosomes and apical secreting vesicles, showed a positive reaction. The luminal colloid was also positive with silver methenamine staining, with almost the same intensity as the globules and vesicles.

Retarded incorporation of [14C]mannose into thyroglobulin of human thyrotoxic thyroid glands

In vitro studies using thyroid slices from human non-toxic goitres and from thyrotoxic glands show retarded incorporation of [14C]mannose into the 19S protein of thyrotoxic glands. This was not found using [14C]galactose with thyrotoxic glands or using either labelled sugar with slices from non-toxic goitres. Experiments with thyroid tissue from rats on a variety of treatment regimes such as iodine supplements, carbimazole alone or with iodine supplements did not show this differential delay of [14C]mannose incorporation. This suggests that there may be some abnormality of carbohydrate incorporation into thyroglobulin in thyrotoxicosis.

Purification and some properties of microsome-bound thyroglobulins

The sonicate of microsomal fraction of hog thyroid was found to contain two species of proteins which reacted with anti-thyroglobulin antiserum and corresponded to 2 to 3% of total protein of the fraction. The two species were purified by ammonium sulfate precipitation, repeated sucrose density gradient centrifugations and separated from each other by polyacrylamide gel electrophoresis into S-mb thyroglobulin (the slower-migrating microsomal-bound fraction), F-mb thyroglobulin (the faster-migrating microsomal-bound fraction), and thyroglobulin itself. Amino acid compositions of the proteins were essentially the same as that of thyroglobulin. Mannose contents also were close to that of thyroglobulin while galactose and fucose contents decreased in the order: thyroglobulin, F-mb thyroglobulin and S-mb thyroglobulin. S-mb thyroglobulin had no sialic acid and no iodine at all. F-mb thyroglobulin was sialylated to an extent of less than 80% of, and iodinated to an extent of less than 50% of that of thyroglobulin, respectively. Antigenic activities of F-mb thyroglobulin and of S-mb thyroglobulin were qualitatively the same as, but quantitatively less than, that of thyroglobulin. Sedimentation coefficients of S-mb thyroglobulin and F-mb thyroglobulin were approximately 1 S lower than that of thyroglobulin. All the properties of the thyroglobulin-related proteins suggested that S-mb thyroglobulin and F-mb thyroglobulin were the products by the sequential modification of thyroglobulin polypeptide in the pathway of thyroid hormone production.

The Golgi complex. III. The effects of puromycin on ultrastructure and glycoprotein synthesis

The effect of puromycin has been investigated on protein and glycoprotein synthesis and on ultrastructure of the Golgi complex from rat liver. Incorporation of [14C]leucine into protein in Golgi fractions and into serum proteins was depressed rapidly after puromycin treatment. In the serum proteins, incorporation returned to normal levels at 2 h whereas in Golgi fractions it continued to rise to 200% of the control levels at 3 h and was still elevated at 24 h after puromycin treatment. Incorporation of [14C]glucosamine into glycoprotein was depressed in Golgi and serum fractions in a similar manner but slightly later than that of leucine. Leucine labelled material found at 3 h was a poor acceptor for carbohydrate, since [14C]glucosamine incorporation was not elevated above control values. Galactosyl transferase activity was not depressed in the Golgi membranes and, at 3 h, was elevated implying that an adequate supply of enzyme was available at all times. The activity of the galactosyl transferase in serum appeared to be depressed suggesting that transport of enzyme from Golgi complex to serum was defective. Ultrastructural changes in the Golgi complex were observed to occur rapidly after puromycin treatment. The cisternae became irregular, compressed, and degenerated progressively from central region towards the periphery. Irregular tubular structures formed at the expense of cisternal membrane and showed accumulation of low density lipoprotein. Vesiculation and degenerative changes of the Golgi membranes continued from 2-12 h while more typical arrangements of the Golgi complex were observed between 24-48 h. The morphological changes correlated with changes in glycoprotein synthesis.

A proposed pathway of plasma glycoprotein synthesis

Plasma glycoprotein synthesis in the liver occurs in a stepwise fashion. The first sugar, N-acetyl-glucosamine, is attached to the protein during the growth of the polypeptide chain on the membrane-bound ribosomes. Subsequent carbohydrates are incorporated after the completion of the protein in the lumen of the endoplasmic reticulum and Golgi apparatus. The reactions are carried out by enzymes strongly bound to the membranes. Because the glycosylation reaction occurs in the interior of the cytoplasmic tubules a permeability problem for the nucleotide sugar exists. Recent studies indicate that sugar-lipids are formed on the cytoplasmic site of the membrane and these complexes transfer the sugars across the membrane. Experimental evidence for this pathway is presented in this article.

Autoradiographic studies of synthesis and intracellular migration of glycoproteins in the rat anterior pituitary gland

The incorporation of [(3)H]fucose in the somatotrophic and gonadotrophic cells of the rat adenohypophysis has been studied by electron microscope autoradiography to determine the site of synthesis of glycoproteins and to follow the migration of newly synthesized glycoproteins. The pituitaries were fixed 5 min, 20 min, 1 h, and 4 h after the in vivo injection of [(3)H]fucose and autoradiographs analyzed quantitatively. At 5 min after [(3)H]fucose administration, 80-90% of the silver grains were localized over the Golgi apparatus in both somatotrophs and gonadotrophs. By 20 min, the Golgi apparatus was still labeled and some radioactivity appeared over granules. At 1 h and 4 h, silver grains were found predominantly over secretory granules. The kinetic analysis showed that in both protein-secreting cells (somatotrophs) and glycoprotein-secreting cells (gonadotrophs), the glycoproteins have their synthesis completed in the Golgi apparatus and migrate subsequently to the secretory granules. It is concluded from these in vivo studies that glycoproteins which are not hormones are utilized for the formation of the matrix and/or of the membrane of the secretory granules. The incorporation of [(3)H]fucose in gonadectomy cells (hyperstimulated gonadotrophs) was also studied in vitro after pulse labeling of pituitary fragments in medium containing [(3)H]fucose. The incorporation of [(3)H]fucose was localized in both the rough endoplasmic reticulum (ER) and the Golgi apparatus. Later, the radioactivity over granules increased while that over the Golgi apparatus decreased. The concentration of silver grains over the dilated cisternae of the rough ER was not found to be modified at the longest time intervals studied.

A biochemical and radioautographic analysis of protein secretion by thyroid lobes incubated in vitro

In this study we analyzed several aspects of protein secretion by thyroid follicular cells. The study was carried out on intact thyroid lobes obtained from newborn rats and incubated in vitro. The fate of leucine-(3)H incorporated into protein within follicular cells of untreated and thyrotropic hormone (TSH)-treated lobes was traced by quantitative electron microscope radioautography. Our findings indicate that protein synthesized by the rough-surfaced endoplasmic reticulum during a pulse exposure to leucine-(3)H is released relatively slowly by this organelle. Approximately 1 hr after onset of the pulse, a peak of radioactive protein appears in the Golgi region. The significance of this peak is not clear. Newly synthesized secretory protein passes through the apex of follicular cells without being concentrated or temporarily stored there in the form of large secretory droplets. Passage probably takes place via small vesicles which are intermingled among diverse small vesicles at the apex of the cells as well as in the Golgi region. Exposure of the lobes to TSH in the incubation medium for 45 or 90 min does not stimulate incorporation of leucine-(3)H into protein. Acute stimulation with TSH does, however, modify the movement of secretory protein within the exocrine secretory apparatus of the follicular cell. It accelerates the arrival of the protein at the apex of follicular cells, and it accelerates the release of the protein into the follicular lumen.

Radioautographic study of in vivo and in vitro incorporation of fucose-3H into thyroglobulin by rat thyroid follicular cells

The incorporation of fucose-(3)H in rat thyroid follicles was studied by radioautography in the light and electron microscopes to determine the site of fucose incorporation into the carbohydrate side chains of thyroglobulin, and to follow the migration of thyroglobulin once it had been labeled with fucose-(3)H. Radioautographs were examined quantitatively in vivo at several times after injection of fucose-(3)H into rats, and in vitro following pulse-labeling of thyroid lobes in medium containing fucose-(3)H. At 3-5 min following fucose-(3)H administration in vivo, 85% of the silver grains were localized over the Golgi apparatus of thyroid follicular cells. By 20 min, silver grains appeared over apical vesicles, and by 1 hr over the colloid. At 4 hr, nearly all of the silver grains had migrated out of the cells into the colloid. Analysis of the changes in concentration of label with time showed that radioactivity over the Golgi apparatus increased for about 20 min and then decreased, while that over apical vesicles increased to reach a maximum at 35 min. Later, the concentration of label over the apical vesicles decreased, while that over the colloid increased. Similar results were obtained in vitro. It is concluded that fucose, which is located at the end of some of the carbohydrate side chains, is incorporated into thyroglobulin within the Golgi apparatus of thyroid follicular cells, thereby indicating that some of these side chains are completed there. Furthermore, the kinetic analysis demonstrates that apical vesicles are the secretion granules which transport thyroglobulin from the Golgi apparatus to the apex of the cell and release it into the colloid.

Biosynthesis of the carbohydrate portion of immunoglobulins. Kinetics of synthesis and secretion of [3H] leucine-, [3H] galactose- and [3H] mannose-labelled myeloma protein by two plasma-cell tumours

The kinetics of incorporation of leucine, galactose and mannose into intracellular and secreted myeloma protein, MOPC 21 IgG(1) and MOPC 46 kappa-type light chain, by cell suspensions of two myeloma plasma-cell tumours, MOPC 21 and MOPC 46, were similar. Radioactive galactose was incorporated to over 90% into galactose residues of intracellular and secreted protein, mannose to over 90% into glucosamine and mannose residues of intracellular protein and to over 90% into glucosamine, mannose and fucose residues of secreted protein, but not into galactose residues. The results show that specific residues in the carbohydrate portion of myeloma proteins can be labelled by specific radioactive monosaccharides, and suggest that fucose residues are added, while myeloma protein is in its final stage of secretion from the plasma cell. The kinetics of incorporation indicate at least three sequential precursor-product relationships between different intracellular forms and the secreted form of myeloma protein.

Radioautographic visualization of the incorporation of galactose-3H and mannose-3H by rat thyroids in vitro in relation to the stages of thyroglobulin synthesis

Rat thyroid lobes incubated with mannose-(3)H, galactose-(3)H, or leucine-(3)H, were studied by radioautography. With leucine-(3)H and mannose-(3)H, the grain reaction observed in the light microscope is distributed diffusely over the cells at 5 min, with no reaction over the colloid. Later, the grains are concentrated towards the apex, and colloid reactions begin to appear by 2 hr. With galactose-(3)H, the reaction at 5 min is again restricted to the cells but it consists of clumped grains next to the nucleus. Soon after, grains are concentrated at the cell apex and colloid reactions appear in some follicles as early as 30 min. Puromycin almost totally inhibits incorporation of leucine-(3)H and mannose-(3)H, but has no detectable effect on galactose-(3)H incorporation during the 1st hr. Quantitation of electron microscope radioautographs shows that mannose-(3)H label localizes initially in the rough endoplasmic reticulum, and by 1-2 hr much of this reaction is transferred to the Golgi apparatus. At 3 hr and subsequently, significant reactions are present over apical vesicles and colloid, while the Golgi reaction declines. Label associated with galactose-(3)H localizes initially in the Golgi apparatus and rapidly transfers to the apical vesicles, and then to the colloid. These findings indicate that mannose incorporation into thyroglobulin precursors occurs within the rough endoplasmic reticulum; these precursors then migrate to the Golgi apparatus, where galactose incorporation takes place. The glycoprotein thus formed migrates via the apical vesicles to the colloid.