Thyroid hormone binding motifs and iodination pattern of thyroglobulin.

A phylogenetically conserved 5-residue thyroid hormone (TH)- binding motif was originally found in a few TH plasma carriers and, more recently, in all known plasma and cell-associated proteins interacting with TH as well as in proteins involved in iodide uptake. Minor variations of the motif were found, depending on the particular class of those proteins. Since thyroglobulin (Tg) is the protein matrix for TH synthesis starting from iodination of a selected number of tyrosines (to form first monoiodotyrosine (MIT) and diiodotyrosine (DIT) and then T3 and T4), we hypothesized that by searching the presence of perfect or imperfect versions of that motif in two Tg species (human and murine) in which the iodinated tyrosines and pattern of iodotyrosine/iodothyronine formation are known, we could have found relevant explanations. Explanations, which are not furnished by the simple possession of tyrosine-iodination motifs and sequence of the iodination motif, concern why only some (but not other) tyrosine residues in one species are iodinated and why they have a particular iodination pattern. In this bioinformatics study, we provide such explanations.

Reversibly Switchable, pH-Dependent Peptide Ligand Binding via 3,5-Diiodotyrosine Substitutions.

Cell type-specific targeting ligands utilized in drug delivery applications typically recognize receptors that are overexpressed on the cells of interest. Nonetheless, these receptors may also be expressed, to varying extents, on off-target cells, contributing to unintended side effects. For the selectivity profile of targeting ligands in cancer therapy to be improved, stimuli-responsive masking of these ligands with acid-, redox-, or enzyme-cleavable molecules has been reported, whereby the targeting ligands are exposed in specific environments, e.g., acidic tumor hypoxia. One possible drawback of these systems lies in their one-time, permanent trigger, which enables the "demasked" ligands to bind off-target cells if released back into the systemic circulation. A promising strategy to address the aforementioned problem is to design ligands that show selective binding based on ionization state, which may be microenvironment-dependent. In this study, we report a systematic strategy to engineer low pH-selective targeting peptides using an M2 macrophage-targeting peptide (M2pep) as an example. 3,5-Diiodotyrosine mutagenesis into native tyrosine residues of M2pep confers pH-dependent binding behavior specific to acidic environment (pH 6) when the amino acid is protonated into the native tyrosine-like state. At physiological pH of 7.4, the hydroxyl group of 3,5-diiodotyrosine on the peptide is deprotonated leading to interruption of the peptide native binding property. Our engineered pH-responsive M2pep (Ac-Y-Î-Î) binds target M2 macrophages more selectively at pH 6 than at pH 7.4. In addition, 3,5-diiodotyrosine substitutions also improve serum stability of the peptide. Finally, we demonstrate pH-dependent reversibility in target binding via a postbinding peptide elution study. The strategy presented here should be applicable for engineering pH-dependent functionality of other targeting peptides with potential applications in physiology-dependent in vivo targeting applications (e.g., targeting hypoxic tumor/inflammation) or in in vitro receptor identification.

[Thyroid hormones and their precursors. II. Species-specific properties]. / Pajzsmirigyhormonok és eloanyagaik. II. Részecske-specifikus tulajdonságok.

This paper surveys the species-specific physico-chemical parameters (basicity and lipophilicity) and related biological functions of thyroid hormones (thyroxine, liothyronine and reverse liothyronine) and their biological precursors (tyrosine, monoiodotyrosine and diiodotyrosine). The protonation macroconstants were determined by 1H NMR-pH titrations while the microconstants were determined by a multimodal spectroscopic-deductive methodology using auxiliary derivatives of reduced complexity. Our results show that the different number and/or position of iodine are the key factors to influence the phenolate basicity. The ionization state of the phenolate site is crucial in the biosynthesis and protein binding of thyroid hormones. The role of the protonation state in the receptor binding was investigated by an in silico docking method. Microspecies of thyroid hormones were docked to the thyroid hormone receptor isoforms. Our results quantitate at the molecular level how the ionization stage and the charge distribution influence the protein binding. The anionic form of the carboxyl group is essential for the protein binding, whereas the protonated form of the amino group loosens it. The protonation state of the phenolate plays a role of secondary importance in the receptor binding. The combined results of docking and microspeciation studies show that microspecies of the highest concentration at the pH of blood are not the strongest binding ones. The site-specific lipophilicity of our investigated molecules was determined with the measurement of distribution coefficients at different pH using carboxymethyl- and O-methyl-derivatives to mimic the partition of some of the individual microspecies. Correction factors were determined and introduced. Our data show that the iodinated aromatic ring system is the definitive structural element that fundamentally determines the lipophilicity of thyroid hormones, whereas the protonation state of the aliphatic part is essential in receptor binding. The membrane transport of thyroid hormones can be well interpreted in terms of the site-specific lipophilicity. At physiological pH these biomolecules are strongly amphipathic due to the lipophilic aromatic rings and hydrophilic amino acid side chains which can well be the reason why thyroid hormones cannot cross membranes by passive diffusion and they even become constituents of biological membranes. The site-specific physico-chemical characterization of the thyroid hormones is of fundamental importance to understand their (patho) physiological behavior and also, to influence the therapeutic properties of their drug candidate derivatives at the molecular level.

Towards the pre-clinical diagnosis of hypothyroidism caused by iodotyrosine deiodinase (DEHAL1) defects.

DEHAL1 (also named IYD) is the thyroidal enzyme that deiodinates mono- and diiodotyrosines (MIT, DIT) and recycles iodine, a scarce element in the environment, for the efficient synthesis of thyroid hormone. Failure of this enzyme leads to the iodotyrosine deiodinase deficiency (ITDD), characterized by hypothyroidism, compressive goiter and variable mental retardation, whose diagnostic hallmark is the elevation of iodotyrosines in serum and urine. However, the specific diagnosis of this type of hypothyroidism is not routinely performed, due to technical and practical difficulties in iodotyrosine determinations. A handful of mutations in the DEHAL1 gene have been identified as the molecular basis for the ITDD. Patients harboring DEHAL1 defects so far described all belong to consanguineous families, and psychomotor deficits were present in some affected individuals. This is probably due to the lack of biochemical expression of the disease at the beginning of life, which causes ITDD being undetected in screening programs for congenital hypothyroidism, as currently performed. This worrying feature calls for efforts to improve pre-clinical detection of iodotyrosine deiodinase deficiency during the neonatal time. Such a challenge poses questions of patho-physiological (natural history of the disease, environmental factors influencing its expression) epidemiological (prevalence of ITDD) and technical nature (development of optimal methodology for safe detection of pre-clinical ITDD), which will be addressed in this review.

Iodotyrosine deiodinase: a unique flavoprotein present in organisms of diverse phyla.

Iodide is required for thyroid hormone synthesis in mammals and other vertebrates. The role of both iodide and iodinated tyrosine derivatives is currently unknown in lower organisms, yet the presence of a key enzyme in iodide conservation, iodotyrosine deiodinase (IYD), is suggested by genomic data from a wide range of multicellular organisms as well as some bacteria. A representative set of these genes has now been expressed, and the resulting enzymes all catalyze reductive deiodination of diiodotyrosine with kcat/Km values within a single order of magnitude. This implies a physiological presence of iodotyrosines (or related halotyrosines) and a physiological role for their turnover. At least for Metazoa, IYD should provide a new marker for tracing the evolutionary development of iodinated amino acids as regulatory signals through the tree of life.

[Thyroid hormones and their precursors I. Biochemical properties]. / Pajzsmirigyhormonok és eloanyagaik I. Biokémiai tulajdonságok.

This paper and the following one (see the next issue of Acta Pharmaceutica Hungarica) survey the biological roles and the related site-specific physico-chemical parameters (basicity and lipophilicity) of the presently known thyroid hormones (thyroxine, liothyronine and reverse liothyronine) and their biological precursors (monoiodotyrosine and diiodotyrosine). Here the literature of the thyroid hormone biochemistry, biosynthesis, plasma- and membrane transport is summarized, focusing on the pH-dependent processes. Biosyntheses of the thyroid hormones take place by oxidative coupling of two iodotyrosine residues catalyzed by thyreoperoxidase in thyreoglobulin. The protonation state of the precursors, especially that of the phenolic OH is crucial for the biosynthesis, since anionic iodotyrosine residues can only be coupled in the thyroid hormone biosyntheses. In the blood more than 99% of the circulating thyroid hormone is bound to plasma proteins among which the thyroxine-binding globulin and transthyretin are crucial. The amphiphilic character of the hormones is assumed to be the reason why their membrane transport is an energy-dependent, transport-mediated process, in which the organic anion transporter family, mainly OATP1C1, and the amino acid transporters, such as MCT8 play important roles. Liothyronine is the biologically active hormone; it binds the thyroid hormone receptor, a type of nuclear receptor. There are two major thyroid hormone receptor (TR) isoforms, alfa (TRalpha) and beta (TRbeta). The activation of the TRalpha is associated with modifications in cardiac behavior, while activation of the TRbeta is associated with increasing metabolic rates, resulting in weight loss and reduction of blood plasma lipid levels. The affinity of the thyroid hormones for different proteins depends on the ionization state of the ligands. The site-specific physico-chemical characterization of the thyroid hormones is of fundamental importance to understand their (patho)physiological behavior and also, to influence their therapeutic properties at the molecular level.

Species-specific lipophilicity of thyroid hormones and their precursors in view of their membrane transport properties.

A total of 30 species-specific partition coefficients of three thyroid hormones (thyroxine, liothyronine, reverse liothyronine) and their two biological precursors (monoiodotyrosine, diiodotyrosine) are presented. The molecules were studied using combined methods of microspeciation and lipophilicity. Microspeciation was carried out by (1)H NMR-pH and UV-pH titration techniques on the title compounds and their auxiliary derivatives of reduced complexity. Partition of some of the individual microspecies was mimicked by model compounds of the closest possible similarity, then correction factors were determined and introduced. Our data show that the iodinated aromatic ring system is the definitive structural element that fundamentally determines the lipophilicity of thyroid hormones, whereas the protonation state of the aliphatic part plays a role of secondary importance. On the other hand, the lipophilicity of the precursors is highly influenced by the protonation state due to the relative lack of overwhelmingly lipophilic moieties. The different logp values of the positional isomers liothyronine and reverse liothyronine represent the importance of steric and electronic factors in lipophilicity. Our investigations provided clear indication that overall partition, the best membrane transport - predicting physico-chemical parameter depends collectively on the site-specific basicity and species-specific partition coefficient. At physiological pH these biomolecules are strongly amphipathic due to the lipophilic aromatic rings and hydrophilic amino acid side chains which can well be the reason why thyroid hormones cannot cross membranes by passive diffusion and they are constituents of biological membranes. The lipophilicity profile of thyroid hormones and their precursors are calculated and depicted in terms of species-specific lipophilicities over the entire pH range.

Expression pattern of iodotyrosine dehalogenase 1 (DEHAL1) during chick ontogeny.

The iodotyrosine dehalogenase1 (DEHAL1) enzyme is a transmembrane protein that belongs to the nitroreductase family and shows a highly conserved N-terminal domain. DEHAL1 is present in the liver, kidney and thyroid of mammals. DEHAL1 is known to act on diiodotyrosine (DIT) and monoiodotyrosine (MIT), and is involved in iodine recycling in relation to thyroglobulin. Here, we show the distribution of DEHAL1 during gastrulation to neurulation in developing chick. Immunocytochemistry using an anti-serum directed against the N-terminal domain (met(27)-trp(180) fragment) of human DEHAL1 revealed labelled cells in the embryonic ectoderm, embryonic endoderm, neural plate and in the yolk platelets of the chick embryo at gastrulation stage. Distinct DEHAL1 positive cells were located in the presumptive head ectoderm, presumptive neural crest, head mesenchymal cells and in the dorsal, lateral and ventral parts of neural tube during neurulation. Some cells located at the margin of the developing notochord and somites were also DEHAL1-positive. While the functional significance of this observation is not known, it is likely that DEHAL1 might serve as an agent that regulates cell specific deiodination of MIT and DIT before the onset of thyroidal secretion. The presence of DEHAL1 in different components of the chick embryo suggests its involvement in iodine turnover prior to the formation of functional thyroid.

Crystal structure of iodotyrosine deiodinase, a novel flavoprotein responsible for iodide salvage in thyroid glands.

The flavoprotein iodotyrosine deiodinase (IYD) salvages iodide from mono- and diiodotyrosine formed during the biosynthesis of the thyroid hormone thyroxine. Expression of a soluble domain of this membrane-bound enzyme provided sufficient material for crystallization and characterization by x-ray diffraction. The structures of IYD and two co-crystals containing substrates, mono- and diiodotyrosine, alternatively, were solved at resolutions of 2.0, 2.45, and 2.6 A, respectively. The structure of IYD is homologous to others in the NADH oxidase/flavin reductase superfamily, but the position of the active site lid in IYD defines a new subfamily within this group that includes BluB, an enzyme associated with vitamin B(12) biosynthesis. IYD and BluB also share key interactions involving their bound flavin mononucleotide that suggest a unique catalytic behavior within the superfamily. Substrate coordination to IYD induces formation of an additional helix and coil that act as an active site lid to shield the resulting substrate.flavin complex from solvent. This complex is stabilized by aromatic stacking and extensive hydrogen bonding between the substrate and flavin. The carbon-iodine bond of the substrate is positioned directly over the C-4a/N-5 region of the flavin to promote electron transfer. These structures now also provide a molecular basis for understanding thyroid disease based on mutations of IYD.

The impact of iodine excess on thyroid hormone biosynthesis and metabolism in rats.

Thyroid function ultimately depends on appropriate iodine supply to the gland. There is a complex series of checks and balances that the thyroid uses to control the orderly utilization of iodine for hormone synthesis. The aim of our study is to evaluate the mechanism underlying the effect of iodine excess on thyroid hormone metabolism. Based on the successful establishment of animal models of normal-iodine (NI) and different degrees of high-iodine (HI) intake in Wistar rats, the content of monoiodotyrosine (MIT), diiodotyrosine (DIT), T(4), and T(3) in thyroid tissues, the activity of thyroidal type 1 deiodinase (D1) and its (Dio1) mRNA expression level were measured. Results showed that, in the case of iodine excess, the biosynthesis of both MIT and DIT, especially DIT, was increased. There was an obvious tendency of decreasing in MIT/DIT ratio with increased doses of iodine intake. In addition, iodine excess greatly inhibited thyroidal D1 activity and mRNA expression. T(3) was greatly lower in the HI group, while there was no significant difference of T(4) compared with NI group. The T(3)/T(4) ratio was decreased in HI groups, antiparalleled with increased doses of iodine intakes. In conclusion, the increased biosyntheses of DIT relative to MIT and the inhibition of thyroidal Dio1 mRNA expression and D1 activity may be taken as an effective way to protect an organism from impairment caused by too much T(3). These observations provide new insights into the cellular regulation mechanism of thyroid hormones under physiological and pathological conditions.

Deciphering the peptide iodination code: influence on subsequent gas-phase radical generation with photodissociation ESI-MS.

Iodination of tyrosine was recently discovered as a useful method for generating radical peptides via photodissociation of carbon-iodine bonds by an ultraviolet photon in the gas phase. The subsequent fragmentation behavior of the resulting odd-electron peptides is largely controlled by the radical. Although previous experiments have focused on mono-iodination of tyrosine, peptides and proteins can also be multiply iodinated. Tyrosine and, to a lesser extent, histidine can both be iodinated or doubly iodinated. The behavior of doubly iodinated residues is explored under conditions where the sites of iodination are carefully controlled. It is found that radical peptides generated by the loss of a single iodine from doubly iodinated tyrosine behave effectively identically to singly iodinated peptides. This suggests that the remaining iodine does not interfere with radical directed dissociation pathways. In contrast, the concerted loss of two iodines from doubly iodinated peptides yields substantially different results that suggest that radical recombination can occur. However, sequential activation can be used to generate multiple usable radicals in different steps of an MS(n) experiment. Furthermore, it is demonstrated that in actual peptides, the rate of iodination for tyrosine versus mono-iodotyrosine cannot be predicted easily a priori. In other words, previous assumptions that mono-iodination of tyrosine is the rate-limiting step to the formation of doubly iodinated tyrosine are incorrect.

Molecular characterization of iodotyrosine dehalogenase deficiency in patients with hypothyroidism.

CONTEXT: The recent cloning of the human iodotyrosine deiodinase (IYD) gene enables the investigation of iodotyrosine dehalogenase deficiency, a form a primary hypothyroidism resulting from iodine wasting, at the molecular level. OBJECTIVE: In the current study, we identify the genetic basis of dehalogenase deficiency in a consanguineous family. RESULTS: Using HPLC tandem mass spectrometry, we developed a rapid, selective, and sensitive assay to detect 3-monoiodo-l-tyrosine and 3,5-diodo-l-tyrosine in urine and cell culture medium. Two subjects from a presumed dehalogenase-deficient family showed elevated urinary 3-monoiodo-l-tyrosine and 3,5-diodo-l-tyrosine levels compared with 57 normal subjects without thyroid disease. Subsequent analysis of IYD revealed a homozygous missense mutation in exon 4 (c.658G>A p.Ala220Thr) that co-segregates with the clinical phenotype in the family. Functional characterization of the mutant iodotyrosine dehalogenase protein showed that the mutation completely abolishes dehalogenase enzymatic activity. One of the heterozygous carriers for the inactivating mutation recently presented with overt hypothyroidism indicating dominant inheritance with incomplete penetration. Screening of 100 control alleles identified one allele positive for this mutation, suggesting that the c.658G>A nucleotide substitution might be a functional single nucleotide polymorphism. CONCLUSIONS: This study describes a functional mutation within IYD, demonstrating the molecular basis of the iodine wasting form of congenital hypothyroidism. This familial genetic defect shows a dominant pattern of inheritance with incomplete penetration.

Mechanism for the anti-thyroid action of minocycline.

Administration of minocycline (MN), a tetracycline antibiotic, produces a black pigment in the thyroids of humans and several species of experimental animals and antithyroid effects in rodents. We have previously shown that these effects appear to be related to interactions of MN with thyroid peroxidase (TPO), the key enzyme in thyroid hormone synthesis. In the present study, the mechanisms for inhibition of TPO-catalyzed iodination and coupling reactions by MN were investigated. MN was stable in the presence of TPO and H2O2, but adding iodide or a phenolic cosubstrate caused rapid conversion to several products. TPO-dependent product formation, characterized by on-line LC-APCI/MS and 1H-NMR, involved oxidative elimination to form the corresponding benzoquinone with subsequent dehydrogenation at the aliphatic 4-(dimethylamino) group. Addition of thiol-containing polymers (bovine serum albumin or thiol-agarose chromatographic beads) had a minimal effect on MN oxidation by TPO, but substantially reduced product formation and produced concomitant losses in free thiols. Covalent bonding through a thioether linkage of a reactive intermediate, the benzoquinone iminium ion, was inferred from these findings. Iodide- and phenolic cosubstrate-dependent oxidation of tetracycline to demethylated and dehydrogenated products was also observed, although at a slower rate than MN. The products and kinetics observed with MN were consistent with oxidation of MN by either the enzymatic iodinating species formed by reaction of TPO compound I with iodide or phenoxyl radicals/cations generated by TPO-mediated oxidation of a phenolic cosubstrate. The proposed reaction mechanism is consistent with alternate substrate inhibition of TPO-catalyzed iodination of tyrosyl residues in thyroglobulin (Tg) by MN, as previously reported. Furthermore, the observed phenoxyl radical-mediated oxidation of MN is consistent with its previously reported potent inhibition of the coupling of hormonogenic iodotyrosine residues in Tg in the reaction that forms thyroid hormones. The proposed reaction mechanism also implicates a reactive benzoquinone iminium ion intermediate that could be important in toxicity of MN.

Repair of semi-oxidized 3,5-diiodotyrosine: radiation chemical studies in the presence of oxygen, ascorbate and superoxide anion.

Reactions of semi-oxidized radicals derived from 3,5-diiodotyrosine (I2TyOH, a thyroid hormone precursor) have been studied using radiation chemical techniques. In buffered, aqueous medium at room temperature, molecular oxygen reactivity towards the phenoxyl radical (I2TyO.) is low, the average bimolecular rate constant, k being 1.7 +/- 0.22 x 10(6) dm3 mol-1s-1. On the other hand, superoxide anion (O2-) reactivity towards I2TyO. is close to the diffusion controlled limit, the k being 5 +/- 1 x 10(9) dm3 mol-1s-1. The major reaction channel in this case (approximately 60%) leads to the reformation of the parent compound by one-electron transfer. Under similar experimental conditions, ascorbate (As-) completely reduces I2TyO. to the parent compound with k = 3 +/- 0.5 x 10(9) and < or = 1 x 10(9) dm3 mol-1s-1 at pH 7.4 and 12 respectively. The propensity of these reactions are not dependent on the primary .OH/.O- or secondary N3. radicals used. These results suggest that the superoxide anion may actively interact at the cellular level, in the Thyroid during the course of I2TyOH oxidation, and the observed in vitro reaction mechanism implies its participation in a new role.

Photoaffinity labeling of lysosomal membrane proteins with [125I]diiodotyrosine, a system h ligand.

Percoll-purified rat thyroid FRTL-5 cell lysosomes were photoaffinity-labeled with [125I]diiodotyrosine to identify proteins which bind diiodotyrosine, a ligand for lysosomal transport system h. SDS-PAGE and autoradiography of these membranes showed specific labeling of a 70-kDa protein and weak labeling of three smaller proteins. [125I]Diiodotyrosine photolabeling of the 70-kDa protein was specifically competed against by ligands of lysosomal transport system h ligands. The 70-kDa protein was photolabeled more strongly in lysosomal membranes isolated from thyrotropin-stimulated cells when compared with those grown in the absence of thyrotropin, consistent with previous demonstrations that thyrotropin stimulates system h transport. The 70-kDa protein may represent some portion of the system h carrier protein.

Modulation of biological tyrosine reactions by tyrosine phosphorylation.

This review focuses on the influence of tyrosine phosphorylation on the biological reactions of tyrosine. Reactions that are modulated by this amino acid modification include dityrosine formation, thyroid hormone synthesis, and DOPA formation. In addition, we show that the reactivity of tyrosine in the common Lowry method of determination of protein concentrations is lost upon phosphorylation of the amino acid.

Evidence for a radical mechanism in peroxidase-catalyzed coupling. I. Steady-state experiments with various peroxidases.

Biosynthesis of thyroxine in the thyroid gland involves a reaction between two diiodotyrosyl residues within the same molecule of thyroglobulin, a large, thyroid-specific glycoprotein. This reaction, generally referred to as the coupling reaction, is catalyzed in the thyroid by the heme-containing glycoprotein enzyme, thyroid peroxidase, also a thyroid-specific protein. The coupling reaction is, however, not specific for thyroid peroxidase; it is also efficiently catalyzed by other heme-containing peroxidases. Peroxidase-catalyzed coupling may also occur between a monoiodotyrosyl and a diiodotyrosyl residue in thyroglobulin to form the more potent thyroid hormone, 3',3,5-triiodothyronine. Under most conditions, thyroxine formation in the thyroid is greatly favored over that of 3',3,5-triiodothyronine. Two mechanisms have been proposed for the coupling reaction, a radical mechanism and an ionic mechanism. In this, and in the following paper, we present evidence favoring a radical mechanism. This view is bsed primarily on the observation that peroxidase-catalyzed coupling is markedly stimulated by substoichiometric concentrations of free diiodotyrosine (DIT). Evidence obtained in this and in the following paper leads us to conclude that the stimulatory effect of DIT on coupling involves peroxidase-catalyzed oxidation of the added DIT to a radical form. We propose that this stimulation involves a radical chain propagation mechanism. This implies that peroxidase-catalyzed coupling in the absence of DIT must also be a radical-mediated reaction.

Evidence for a radical mechanism in peroxidase-catalyzed coupling. II. Single turnover experiments with horseradish peroxidase.

Single turnover experiments were performed with horseradish peroxidase (HRP) to study the mechanism of peroxidase-catalyzed coupling and its stimulation by low concentrations of free diiodotyrosine (DIT). HRP was used because, unlike thyroid peroxidase (TPO) and lactoperoxidase (LPO), the spectral properties of compounds I and II are readily distinguishable. This made it possible to correlate the kinetics and stoichiometry of T4 + T3 formation with spectral data. Incubation of 2 microM preformed HRP-I with 2 microM [125I]Tg (thyroglobulin of low hormone content, high iodotyrosine content) in the presence of 1 microM free DIT yielded about 0.8 residue T4 and 0.2 residue T3 per molecule of Tg. This represents the theoretical maximum for iodothyronine formation, indicating remarkably efficient use of the oxidizing equivalents in HRP-I for coupling. The time course for formation of T4 + T3 was biphasic. During a rapid initial phase (about 1 min), HRP-I was completely converted to HRP-II, coincident with the formation of about 0.65 residues of T4 + T3. During the second slower phase, lasting 10-15 min, HRP-II was completely reduced to the native enzyme, with formation of the remaining T4 + T3. In the absence of DIT, the coupling yield was reduced to 0.5-0.6 residue T4 + T3 per molecule Tg, and the reaction, although considerably slower, was still biphasic. The rapid phase again corresponded to the conversion of HRP-I to HRP-II, and the slower phase to the conversion of HRP-II to native enzyme. To gain insight into the mechanism of the stimulatory effect of free DIT on coupling, we studied the reaction of DIT with HRP-I and HRP-II. Free DIT reacted with both HRP-I and HRP-II in one-electron transfer reactions, and the time course for these reductions resembled those observed with DIT + Tg. These observations suggest that in DIT-stimulated coupling, free DIT radicals act as a shuttle for transferring oxidizing equivalents from the peroxidase intermediates to the DIT residues in Tg. The remarkable efficiency of the HRP-I-mediated coupling reaction implies that (i) only hormonogenic residues in Tg are oxidized and (ii) oxidation of two hormonogenic residues occurs within the same molecule of Tg. A scheme which attempts to explain both kinetic and stoichiometric features of the coupling reaction observed in this study is proposed. This scheme is based on a radical mechanism, consistent with the conclusions reached in the companion paper.

Expression of thyroglobulin gene in maternal and fetal thyroid in rats.

The relationship between the changes in thyroglobulin (Tg) mRNA and Tg proteins during thyroid development in the fetus and in maternal thyroid glands during gestation and lactation is studied. While the appearance of Tg mRNA (fetal day 15) showed good temporal correlation with that of 12S Tg, no 19S Tg could be detected until 3 days later. The 12S Tg was the predominant protein on days 18 and 19 of gestation in the fetus, while 19S Tg was the predominant protein on fetal days 21-22 and during the postnatal period in the offspring; by the 20th postnatal day, the 19S Tg content per gland was 4 times the amount of 12S (155 vs. 37 micrograms/gland; P less than 0.001). The 19S iodine content in the fetus was the same as that in 12S up to the 21st day of gestation, except for lower values on day 18. From fetal day 22 and through the postnatal period, the iodine content in 19S was 1.6-5.9 times greater than that in 12S. Therefore, the ratio of atoms of iodine per mol Tg during the experimental period changed from 0.75 to 19.5 for 19S and from 0.72 to 7.2 for 12S. The levels of all of the iodoamino acids were low on fetal days 17-19, after which they increased at different rates for each protein. The greatest increase in monoiodotyrosine and T3 corresponded to 12S, while diiodotyrosine and especially T4 showed a greater increase in 19S than in 12S Tg; 20 days after birth, the T4 content in 19S was about 3 times greater than that in 12S Tg. The soluble thyroid proteins from pregnant, lactating, and nonpregnant female controls contained a main protein, 19S, and a smaller amount of 27S. Both 19S Tg and 19S iodine contents were already lower than those in nonpregnant rats at 14 days of pregnancy, and the levels continued to decrease during the experimental period. In contrast, the 27S Tg and 27S iodine levels remained constant and similar to nonpregnant values. Surprisingly, a decrease in the level of Tg mRNA was observed during pregnancy and lactation. We have no explanation for the dramatic decrease in Tg mRNA during the last days of pregnancy. Further studies should help to elucidate the mechanism responsible for the changes in Tg gene expression in the thyroids of pregnant and lactating rats.

Inhibition by immunoglobulin G of synthesis of thyroid hormone in thyroid cultures from hypothyroid patients with goitrous Hashimoto's thyroiditis.

Recently, thyroid microsomal antigen was identified as thyroid peroxidase, and thyroid microsomal antibody was found to inhibit thyroid peroxidase activity in vitro. We investigated the possibility that anti-microsomal antibody inhibits the iodination of tyrosine, in vivo. Immunoglobulin G with or without anti-microsomal antibody from hypothyroid patients with goitrous Hashimoto's thyroiditis inhibited thyroid hormone synthesis in cultured slices of normal human thyroid tissue. IgGs with anti-microsomal antibody inhibited 125I thyroidal uptake and thyroid hormone synthesis stimulated by TSH more than normal IgG did. However, the same results were obtained with IgGs without anti-microsomal antibody. This effect did not involve anti-microsomal antibody, anti-thyroglobulin antibody, TSH-binding inhibitor immunoglobulin, thyroid stimulation-blocking immunoglobulin, or the cAMP level of the thyroid tissue. The ratio of organic I to inorganic I with stimulation by TSH in slices incubated with IgG from hypothyroid patients with goitrous Hashimoto's thyroiditis or normal IgG was not significantly different, but was significantly higher in slices incubated with methylmercaptoimidazole. Therefore, IgG from hypothyroid patients with goitrous Hashimoto's thyroiditis mainly suppressed 125I thyroidal uptake, rather than inhibiting thyroid peroxidase activity. In addition, this IgG was present in the serum of 11 of the 12 hypothyroid patients with Hashimoto's thyroiditis studied. This IgG may be involved in the mechanism that causes hypothyroidism in some patients with goitrous Hashimoto's disease.