The effect of iodide administration on hog thyroid gland and the composition of thyroglobulin and 27-S iodoprotein.

The effect of excess iodide on hog thyroid gland has been examined with regard to the change in the chemical composition of thyroglobulin and in the accumulation of 27-S iodoprotein by the in vivo treatment of hogs with iodide for various lengths of time. The iodine content of thyroglobulin was either unchanged by short term administration of excess iodide, or somewhat lowered. However, the iodine content as well as the total amount of thyroglobulin increased in the glands enlarged by prolonged treatment with iodide. The iodine highest reached 1.17% of the protein on an average. On the other hand, 27-S iodoprotein decreased and finally disappeared after the chronic treatment. Monoiodotyrosine and diiodotyrosine increased in parallel with the increase in the iodine content (0.15 to 1.17%) caused by the iodide treatment, while thyroxine increased but reached a plateau at the level of three residues per mole of thyroglobulin, and no change was observed even in the proteins with the higher iodine content than 0.75%. Proteolytic activity measured by amino acid release from the thyroid protein was depressed by the chronic treatment. On the other hand, the amount of iodocompound released by the autoproteolysis, which may reflect hormone secretion, increased, possibly because of the marked increase in the iodine content of thyroglobulin.     

9 S thyroid particulate iodoprotein.

Particulate iodoproteins have been studied in the rat thyroid gland using the isotopic 125I equilibration method. Pulse experiments were also performed with a second isotope, 131I. Labelled iodoproteins, both soluble and solubilized by digitonin from the thyroid particulate material, were analyzed by sucrose-gradient ultracentrifugation. 1. At isotopic equilibrium and irrespective of the iodide content of the diet two particulate iodoproteins, with sedimentation coefficients of 27 and 19 S, were solubilized by digitonin. In addition a 9 S iodoprotein was also present but its proportion varied markedly with the iodine content of the diet: it accounted for 50-60% of the label found at the particulate level when the dialy diet of iodine was high (75-500 mug/day) but was almost absent when the diet was only 2 mug/day. 2. Most of this 9 S protein was found in the 600-15 000 times g particulate pellet, i.e. a fraction enriched in lysosomes and phagolysosomes. 3. The iodoamino acid composition of the 9 S fraction was very similar to that of the 19 S particulate thyroglobulin: its hormone content was 19%. 4. The double precipitation technique showed that the 9 S fraction is immunochemically related to thyroglobulin. 5. Pulse experiments showed that the 9 S particulate iodoprotein was slowly labelled by 131I. 6. The amount of 9 S iodoprotein was increased by thyrotropin (30-40% increase versus control experiments 5 min after thyrotropin injection). These properties of the 9 S particulate iodoprotein are discussed in relation to the assumption that it might be a product of partial proteolysis of thyroglobulin after endocytosis and partial digestion by the phagolysosomes.     

An improved assay method for thyroid peroxidase applicable for a few milligrams of abnormal human thyroid tissues

A peroxidase assay method (Mini assay method) which is applicable for a minute amount (as small as a few mg) of thyroid tissue was developed, employing guaiacol or iodide as the second substrate. This method is a modification of the previous one (Ordinary assay method): the volume of the reaction mixture was reduced to about one-tenth with prior solubilization of the enzyme. The correlation between the Mini assay and Ordinary assay methods, and between the guaiacol and iodide assays by both methods were satisfactorily good, but the iodine content of thyroglobulin was found to be not directly correlated to the peroxidase activities. Protein-based specific activities of peroxidase from normal human thyroid tissue were about 0.030 guaiacol units/mg protein and 0.0066 iodide units/mg protein, which were slightly higher than those of porcine thyroid tissue. The Mini assay method developed in the present study was used for the determination of peroxidase activity in a small amount (1-8 mg) of thyroid tissue obtained by means of a needle biopsy from patients with thyroid disorders. One specimen (goitrous cretinism) showed no peroxidase activity in both the guaiacol and iodide assays, and three specimens (two chronic thyroiditis, one familial nontoxic goiter) possessed no ability to catalyze the oxidation of iodide in spite of the high reactivity towards guaiacol, suggesting the presence of an abnormal peroxidase in these tissues.     

Process of iodination of thyroglobulin and its maturation. I. Properties and distribution of thyroglobulin labeled with radioiodine in pig thyroid slices.

Pig thyroid slices were incubated with Na131I and the 17--19S 131I-labeled thyroglobulin isolated was subjected to dissociation with 0.3 mM sodium dodecyl sulphate SDS) on sucrose density gradient centrifugation and to iodoamino acid analysis. During the incubation, initially dissociable thyroglobulin was gradually altered to 0.3 mM SDS-resistant species with increasing incorporation of iodine. Microsome-bound, poorly iodinated thyroglobulin and preformed thyroglobulin were chemically iodinated and then subjected to analysis of dissociability and iodoamino acid contents with newly incorporated iodine. The results indicated that the behavior of the former thyroglobulin resembled that of 131I-thyroglobulin obtained from the slices. Then, thyroid slices were incubated for 3 min with Na131I and 3H-leucine with or without 10-min chase incubation. The sucrose density gradient centrifugation patterns of 131I and 3H-radioactivity of cytoplasmic extracts indicated that 131I-thyroglobulin is contained in particulates, especially in vesicles with low density(d=1.12) and that some of them are released into the soluble fraction within 10 min. The vesicles contained peroxidase and NADH-cytochrome c reductase, and are probably exocytotic vesicles in the apical area of cytoplasm of follicular cells. No positive evidence was obtained that plasma membranes participate in the iodination of thyroglobulin under the present experimental conditions. These results suggest that, in the incubation of thyroid slices, iodine atoms are preferentially incorporated into newly synthesized, less iodinated thyroglobulin, rather than preformed thyroglobulin, and that the iodination occurs, at least to a certain degree, in apical vesicles before the thyroglobulin is secreted into the colloid lumen.     

Thyrotropin increases the iodine content of rat circulating thyroglobulin as measured by equilibrium density gradient centrifugation

In previous work we demonstrated that circulating thyroglobulin contains very little or no iodine. We have now characterized circulating thyroglobulin following administration of thyrotropin (TSH) to determine whether its iodine content remains low or increases after stimulation. The iodine content of circulating thyroglobulin was estimated from its density determined by equilibrium density gradient (isopycnic) centrifugation. TSH stimulated thyroglobulin from 182 +/- 28 ng/ml to 571 +/- 83 ng/ml at 8-14 h. Circulating thyroglobulin in the basal state had a density consistent with very little or no iodine. Its density increased following TSH to a maximum at 8-14 h which was nearly the same as the density of thyroglobulin extracted directly from the thyroid. To determine whether selective peripheral metabolism, based on the degree of iodination, could account for the density shift, purified rat thyroid thyroglobulin was injected into thyroidectomized rats. The density of thyroglobulin remained unchanged for 25 h during which time it was metabolized by more than 97%. Therefore, selective metabolism of thyroglobulin based on iodine content did not occur. We conclude that TSH causes a marked increase in the iodine content of circulating thyroglobulin. It is most likely that in the basal state circulating thyroglobulin comes from selective release of poorly iodinated molecules, while after TSH, it comes from release of previously synthesized, iodinated and stored molecules.     

Thyroid morphological and functional heterogeneity: impact on iodine secretion

Thyroid iodine turnover heterogeneity includes morphological (cellular and colloidal distribution space for iodide) and functional heterogeneity (hormone synthesis in the colloid). In 'normal' rats, both iodide actively trapped by the epithelial cell and that coming from deiodination of iodotyrosines present the same probability for thyroglobulin (Tg) iodination (Tg iodination flux: 4.0 +/- 0.3 micrograms I/day). A portion of the thyroid iodide is sequestered in the colloid lumen and is inoperative in the Tg iodination mechanisms. The masses of cell and colloid compartments are equivalent (0.018 +/- 0.002 micrograms I) while colloid iodide concentration is twice that of the cell (0.11 and 0.06, respectively). The turnover of about 3 micrograms I of colloid iodine (Tg) is follicle diameter-dependent (inter-follicular heterogeneity) and it is mainly characterized by 2 different half lives of 8 and 16 hours, respectively. Ninety percent of the thyroid iodine (hormone) secretion (1.10 +/- 0.11 micrograms I/day) is provided by this compartment rich in iodotyrosine residues (70%). The remaining 10% of iodine secretion is provided by a Tg pool (7 micrograms I) characterized by 2 compartments (intra-follicular heterogeneity) with slow and very slow turnovers. The longer the transit time of Tg molecules in the colloid, the higher their iodothyronine content.     

Thyroglobulin-mediated one- and two-electron oxidations of glutathione and ascorbate in thyroid peroxidase systems

The one- or two-electron oxidation of thyroglobulin by the thyroid peroxidase system was found to be regulated by the iodine content of thyroglobulin. The catalytic intermediate of thyroid peroxidase observed at steady state of the reaction was Compound I and II when the iodine content in thyroglobulin was 0.2 and 0.7%, respectively, apparent rate constants for the rate-limiting steps being estimated at 4.7 x 10(7) and 4.8 x 10(4) M-1 S-1. The thyroglobulin-mediated oxidation of GSH occurred by way of two-electron transfer at 0.2% iodine content and by way of one-electron transfer at 0.7% iodine content. The spin-trapping experiment with 5,5-dimethyl-1-pyrroline-N-oxide showed that glutathione radicals were formed in the latter reaction but not in the former. In the reactions of thyroid peroxidase, the one- and two-electron oxidations of ascorbate were also mediated by 0.2 and 0.7% iodine thyroglobulins, respectively. The reactions were analyzed and mimicked with the use of p-cresol and p-acetaminophenol as a mediator in the reactions of lactoperoxidase and thyroid peroxidase.     

Purification and Characterization of Camel Thyroglobulin

Thyroglobulin (669 kDa), the major protein of the camel thyroid, has been isolated and purified from saline extract of the gland by ammonium sulfate fractionation and DEAE-cellulose chromatography. Ultracentrifugal analysis of the purified material, with an iodine content of 0.39%, showed a major and minor component with S_20,w values of 17 and 24, respectively. Separation of the protein from thyroid of individual animals by linear salt gradient on DEAE-cellulose showed a major and minor peak, indicating heterogeneity. Native gel electrophoresis of camel thyroglobulin showed a doublet, revealing microheterogeneity. A similar pattern was observed for the slower migrating components (24 S iodoprotein). N-terminal analysis of the purified protein revealed asparagine as the major N-terminal amino acid. Glycine and alanine were observed as the minor N-terminals. No differences in N-terminals between the major and minor peak were observed. Camel thyroglobulin, as thyroglobulin of other animal species, is a glycoprotein with a total carbohydrate content of 10.7%, comprising 6.0% neutral sugar, 3.67% glucosamine and 1.04% sialic acid. The iodoamino acid and amino acid composition of camel thyroglobulin is similar to that of other mammalian species.     

Application of improved coupling assay method for peroxidase of diseased thyroids: report of three cases

Recently we have developed an assay method for peroxidase-catalyzed coupling of iodotyronine residues of thyroglobulin, which is applicable to human diseased thyroid tissues. In the present study, the assay method as well as usual peroxidase assay methods were applied to thyroids of three patients (No. 1: familial goiter with impaired thyroglobulin synthesis, No. 2: mild chronic thyroiditis, No. 3: dyshormonogenetic goiter) who showed organification of iodine with high TSH levels and low thyroid hormone levels in sera. In general, these patients showed relatively high activities measured by guaiacol oxidation assay, iodide oxidation and coupling assay compared with those of control thyroids. Iodothyronine content in thyroglobulin was very low except thyroxine in No. 2. These results indicate that factors other than peroxidase may be responsible for the cause of the hypothyroid state. The coupling assay method used here is therefore useful for the detection of the 'coupling defect' in patients in a hypothyroid state.     

Free diiodotyrosine effects on protein iodination and thyroid hormone synthesis catalyzed by thyroid peroxidase.

Free diiosotyrosine exerts two opposite effects on the reactions catalyzed by thyroid peroxidase, thyroglobulin iodination and thyroid hormone formation. 1. Inhibition of thyroglobulin iodination catalyzed by thyroid peroxidase was observed when free diiodotyrosine concentration was higher than 5 muM. This inhibition was competitive, suggesting that free diiodotyrosine interacts with the substrate site(s) of thyroid peroxidase. Free diiodotyrosine also competively inhibited iodide peroxidation to I2. 2. Free diiodotyrosine, when incubated with thyroid peroxidase in the absence of iodide was recovered unmodified; in the presence of iodide an exchange reaction was observed between the iodine atoms present in the diiodotyrosine molecule and iodide present in the medium. Using 14C-labelled diiodotyrosine, 14C-labelled non-iodinated products were also observed, showing that deiodination occurred as a minor degradation pathway. However, no monoiodo[14C]tyrosine or E114C]tyrosine were observed. Exchange reaction between free diiototyrosine and iodide is therefore direct and does not imply deiodination-iodination intermediary steps. Thyroglobulin inhibits diiodotyrosine-iodide exchange and vice versa, again suggesting competition for both reactions. These results support, by a different experimental approach, the two-site model for peroxidase previously described by us in this journal. 3. Free diiodotyrosine when present at a very low concentration, 0.05 muM, exerts a stimulatory effect on throid hormones synthesis. The relationship between diiodotyrosine concentration and thyroid hormone synthesis give an S-shaped curve, suggesting that free diiodotyrosine acts as a regulatory ligand for thyroid peroxidase. Evidence is also presented that free diiodotyrosine is not incorporated into thyroid hormones. Therefore, thyroid peroxidase catalyzes only intra-molecular coupling between iodotyrosine hormonogenic residues. 4. Finally, although no direct proof exists that these free diiodotyrosine effects upon thyroglobulin iodination and thyroid hormone synthesis are physiologically significant, such a possibility deserves further investigation.     

Low Iodine in the Follicular Lumen Caused by Cytoplasm Mis-localization of Sodium Iodide Symporter may Induce Nodular Goiter

Iodine is a key ingredient in the synthesis of thyroid hormones and also a major factor in the regulation of thyroid function. A local reduction of iodine content in follicular lumen leads to overexpression of local thyroid-stimulating hormone receptor (TSHr), which in turn excessively stimulates the regional thyroid tissue, and result in the formation of nodular goiter. In this study, we investigated the relationship between iodine content and sodium iodide symporter (NIS) expression by using the clinical specimens from patients with nodular goiter and explored the pathogenesis triggered by iodine deficiency in nodular goiter. In total, 28 patients were clinically histopathologically confirmed to have nodular goiter and the corresponding adjacent normal thyroid specimens were harvested simultaneously. Western blot and immunohistochemistry were performed to assay NIS expression and localization in thyrocytes of both nodular goiter and adjacent normal thyroid tissues. NIS expression mediated by iodine in follicular lumen was confirmed by follicular model in vitro. Meanwhile, radioscan with iodine-131were conducted on both nodular goiter and adjacent normal thyroid. Our data showed that NIS expression in nodular goiter was significantly higher than that in adjacent normal tissues, which was associated with low iodine in the follicular lumen. Abnormal localization of NIS and lower amount of radioactive iodine-131 were also found in nodular goiter. Our data implied that low iodine in the follicular lumen caused by cytoplasm mis-localization of NIS may induce nodular goiter.     

Iodinated phospholipids and the iodination of proteins of dog thyroid gland in vitro

Slices of dog thyroid gland were incubated with liposomes consisting of (125)I-labelled phosphatidylcholine (the iodine was covalently linked to unsaturated fatty acyl chains). The (125)I label of (125)I-labelled liposomes was incorporated into thyroid protein and/or thyroglobulin at a higher rate than was the (131)I label of either Na(131)I or (131)I(2). The iodine was shown to be protein-bound by the co-migration of the labelled iodine with protein under conditions where free iodine, iodide and lipid-bound iodine were removed from protein. The uptake of iodine from the iodinated phospholipid was probably due to phospholipid exchange between the iodinated liposomes and the thyroid cell membrane, since (a) (14)C-labelled phospholipid was metabolized to (14)CO(2) and (b) many lipids in the tissue slice became (14)C-labelled. A very strong inhibition of iodide ;uptake' from Na(131)I, caused by thiosulphate, produced only a minor inhibition of the incorporation of (125)I from (125)I-labelled liposomes into thyroid protein and/or thyroglobulin. This implies that free iodide may not necessarily be formed from the iodinated phospholipids before their entrance or utilization in the cell. Synthetic polytyrosine polypeptide suspensions showed some iodination by (131)I-labelled liposomes. In tissues with low tyrosine contents, such as liver and kidney, only a trace uptake was observed. Salivary gland showed some uptake. Endoplasmic reticulum of thyroid gland showed a higher iodine uptake than that of the corresponding plasma membranes. These experiments, together with the demonstration of the diet-dependent presence of iodinated phospholipids in dog thyroid, leads us to suggest that iodination of the membrane phospholipids of thyroid cells may be directly or indirectly involved at some stage in the synthesis of thyroglobulin, or exists as a scavenger mechanism, to re-utilize and/or recover released iodine from unstable compounds inside the thyroid cell.     

Iodination and oxidation of thyroglobulin catalyzed by thyroid peroxidase

The kinetics of iodination and oxidation of hog thyroglobulin were studied with purified hog thyroid peroxidase and the results were compared with the reactions of free tyrosine. From Lineweaver-Burk plots and on the basis of a value of 0.83 for delta epsilon mM at 289 nm/iodine atom incorporated, the rate constant for transfer of an assumed enzyme-bound iodinium cation to thyroglobulin was estimated to be 6.7 X 10(7) and 2.3 X 10(7) M-1 s-1 in native (iodine content = 1.0%) and more iodinated (iodine content = 1.2%) thyroglobulins, respectively. This iodine-transferring reaction was stimulated by iodothyronines, similarly as observed in the reaction with free tyrosine. The iodination of thyroglobulin was inhibited by GSH, the inhibition being competitive with thyroglobulin. Thyroglobulin was oxidized in the presence of a thyroid peroxidase system without giving any appreciable change in absorbance around 300 nm. From stopped flow data, the oxidation was concluded to occur by way of two-electron transfer and the rate constant for the reaction of thyroid peroxidase Compound I with thyroglobulin was estimated to be 1.0 X 10(7) M-1 s-1. The stopped flow kinetic pattern was similar to that observed on the reaction with free tyrosine and monoiodotyrosine. About 6 mol of hydrogen peroxide were consumed per mol of thyroglobulin. Thyroid peroxidase catalyzed thyroglobulin-mediated oxidation of GSH, but lactoperoxidase did not.     

Thytropin increases the iodine content of rat circulating thyroglobulin as measured by equilibrium density gradient centrifugation

In previous work we demonstrated that circulating thyroglobulin contains very little or no iodine. We have now characterized circulating thyroglobulin following administration of thyrotropin (TSH) to determine whether its iodine content remains low or increases after stimulation. The iodine content of circulating thyroglobulin was estimated from its density determined by equilibrium density gradient (isopycnic) centrifugation. TSH stimulated thyroglobulin from 182 ± 28 ng/ml to 571 ± 83 ng/ml at 8–14 h. Circulating thyroglobulin in the basal state had a density consistent with very little or no iodine. Its density increased following TSH to a maximum at 8–14 h which was nearly the same as the density of thyroglobulin extracted directly from the thyroid. To determine whether selective peripheral metabolism, based on the degree of iodination, could account for the density shift, purified rat thyroid thyroglobulin was injected into thyroidectomized rats. The density of thyroglobulin remained unchanged for 25 h during which time it was metabolized by more than 97%. Therefore, selective metabolism of thyroglobulin based on iodine content did not occur. We conclude that TSH causes a marked increase in the iodine content of circulating thyroglobulin. It is most likely that in the basal state circulating thyroglobulin comes from selective release of poorly iodinated molecules, while after TSH, it comes from release of previously synthesized, iodinated and stored molecules.     

Ion-exchange chromatographic analysis of iodothyronines.

An ion-exchange chromatographic procedure for the analysis of iodothyronine mixtures containing iodotyrosines is described. Eight different iodothyronines are separated into five peaks and one shoulder, the order of their elution being related to the number and position of iodine substitution in the compounds. The resolution of monoiodotyrosine and diiodotyrosine from each other and from iodothyronines is excellent. Quantitation of iodoamino acids is carried out by the automatic analysis of the effluent based on the ceric-arsenite reaction. This procedure has been applied to the determination of the iodoamino acid distribution in hog thyroglobulin and to the analysis of photodegradation products of thyroxine and triiodothyronine.     

Thyroglobulin interactions with thyroid membranes. Relationship between receptor recognition of N-acetylglucosamine residues and the iodine content of thyroglobulin preparations

Bovine thyroglobulin has been subjected to sequential glycohydrolase treatment in order to define further the components of the carbohydrate chain which are important in binding of the glycoprotein to bovine thyroid membranes. Preparations of asialoagalactothyroglobulin exhibit the best binding, suggesting that exposed N-acetylglucosamine residues on the B carbohydrate chain of thyroglobulin play an important role in the interaction of thyroglobulin with the thyroid membranes. Enhanced binding of asialoagalactothyroglobulin to microsomal, lysosomal, and Golgi membranes, as well as to thyroid cells in culture, was also observed. Isopycnic rubidium chloride gradient centrifugation, a procedure used in the isolation of thyroglobulin molecules with a low iodine content, also isolates thyroglobulin molecules with a low sialic acid content and with an increased ability to interact with wheat germ agglutinin, a lectin which recognizes exposed N-acetylglucosamine residues. The studies further indicate that there is a correlation between iodine content, exposed N-acetylglucosamine residues, and the binding of thyroglobulin to thyroid membranes.     

Thyroidal iodine and thyroglobulin in hibernating and active Richardson's ground squirrels Spermophilus richardsoni

Thyroidal iodine, protein and thyroglobulin (TG) were investigated in a hibernator, Spermophilus richardsoni, sampled in the field and from laboratory-held winter colonies. In field animals, thyroidal iodine and protein contents were similar at onset of hibernation and at terminal arousal. Iodine content was increased in laboratory-held animals, a function of alimentary supply, but no differences were observed between hibernators and non-hibernators. Density sucrose gradients showed that approx. 20% of the TG was present as the 12S precursor sub-unit. No variations in the iodine content, nor the iodoamino acid composition of the TG occurred as a function of hibernation.     

Differences in iodinated peptides and thyroid hormone formation after chemical and thyroid peroxidase-catalyzed iodination of human thyroglobulin

The distribution of iodine among the polypeptides of human goiter thyroglobulin (Tg) was examined. Tg was iodinated in vitro with ¹³¹I to levels of 2 to 84 gram atoms (g.a.)/mol using thyroid peroxidase (TPO) or a chemical iodination system. The samples were reduced, alkylated, and subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Two low-molecular-weight peptides appeared preferentially in radioautograms of the sodium dodecyl sulfate (SDS) gels of TPO-iodinated samples. Iodination of these peptides increased sharply in the TPO-treated Tg as the level of total iodine/ molecule rose. Radioiodine was incorporated into these same gel regions in the chemically treated Tg, but only after much higher levels of total iodination were reached. Differences in iodoamino acid distribution were also noted between the chemically and enzymatically iodinated thyroglobulins. In the chemically iodinated samples, little thyroxine (T₄) was synthesized, even at high iodine levels. In the TPO-treated samples only small amounts of T₄ were seen below 14 g.a. total I/mol, while at or above that level of iodination T₄ formation increased sharply. To examine the coupling process, Tg was chemically iodinated, excess I^? removed, and the samples treated with TPO and a H₂O₂-generating system in the absence of iodide. Radioautograms obtained from SDS-polyacrylamide gels of reduced and alkylated protein from such coupling assays showed an increase in the level of iodine in the low-molecular-weight peptides after TPO treatment. Thyroxine production also increased with TPO treatment. The addition of free DIT (a known coupling enhancer) to the [¹³¹I]Tg/TPO incubation increased both the production of T₄ and the amount of iodine in the smaller polypeptides. Two-dimensional maps prepared from CNBr-digested TG showed differences between the coupled and uncoupled samples. Our observations confirm the importance of the lowmolecular-weight peptides derived from Tg in thyroid hormone synthesis. At total iodine levels above 14 g.a./mol Tg in enzymatically treated samples there is selective incorporation of iodine into both the low-molecular-weight polypeptides and into thyroid hormone.     

Hormone synthesis and storage in the thyroid of human preterm and term newborns: effect of thyroxine treatment.

Iodine and thyroglobulin concentrations, as well as iodine, T3, T4 and sialic acid contents of thyroglobulin, were measured in thyroid glands collected postmortem from 42 human premature or term newborns and infants. Three groups were considered: very preterm newborns (24-32 postmenstrual weeks, < 5 days postnatal life), preterm and term newborns (34-41 postmenstrual weeks, < 5 days postnatal life) and infants (born at term, postnatal age 1-8 months). Five very preterm and seven preterm newborns received a daily dose of 10 microg/kg L-T4 for at least 3 days. Thyroid weight and sialic acid content of thyroglobulin progressed with maturation. Intrathyroidal concentrations of iodine and thyroglobulin did not increase significantly before the 42nd week of postmenstrual age. The level of thyroglobulin iodination increased during the postnatal life, except in the very preterm neonates. T4 and T3 content of thyroglobulin was directly proportional to its degree of iodination and positively related to its sialic acid content. L-T4 treatment of preterm newborns increased thyroglobulin iodination and T4-T3 content, without increasing thyroglobulin concentration in the thyroid. It was concluded that the storage of thyroglobulin and iodine in the thyroid develops around term birth. This, associated with the resulting rapid theoretical turnover of the intrathyroidal pool of T4 in Tg, could be an important factor of increased risk of neonatal hypothyroxinemia in the premature infants. The L-T4 treatment of preterm newborns does not accelerate the maturational process of the thyroid gland.     

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.