Response of thyroid hormones in peripheral and thyroid venous blood to TRH administration in man

Thyroid vein and cubital vein samples were collected simultaneously in 6 moderately hypercalcemic patients and 1 eucalcemic hypothyroid patient, and thyroid hormones were measured in the serum in the basal state, as well as 30 and 60 min after intravenous administration of TRH. No gradient was detectable between peripheral and thyroid blood in the case of T4, and no significant changes were observed following TRH. The levels of T3 were higher in the thyroid venous effluent than in the periphery and a marked increase occurred following TRH. Serum thyroglobulin also increased following TRH, but there was no peripheral vs. thyroid gradient. Calcitonin demonstrated a marked positive gradient in the thyroid vein compared to the periphery, but no change was observed following TRH. It is concluded that the patterns of response of individual thyroid hormones reflect differences in their secretion and, specifically, that intrathyroid conversion of T4 to T3 occurs during the thyroid hormone secretion.     

Generation of oxygen free radicals in thyroid cells and inhibition of thyroid peroxidase

We examined whether superoxide (O(2)(-)) is produced as a precursor of hydrogen peroxide (H(2)O(2)) in cultured thyroid cells using the cytochrome c method and the electron paramagnetic resonance (EPR) method. No O(2)(-) or its related radicals was detected in thyroid cells under the physiological condition. The presence of quinone, 2,3-dimethoxy-l-naphthoquinone (DMNQ), or 2-methyl-1, 4-naphthoquinone (menadione), in the medium produced O(2)(-) and hydroxyl radicals (OH*); the amount of H(2)O(2) generation was also increased. Incubation of follicles with DMNQ or menadione inhibited iodine organification (a step of thyroid hormone formation) and its catalytic enzyme, thyroid peroxidase (TPO). This inhibition should be caused by reactive oxygen species because the two quinones, particularly DMNQ, exert their effect through the generation of reactive oxygen species. It is speculated that the site-specific inactivation of TPO might have occurred at the heme-linked histidine residue of the TPO molecule, a critical amino acid for enzyme activity because OH* (vicious free radicals) can be formed at the iron-linked amino acid. TPO mRNA level and electrophoretic mobility of TPO were not inhibited by quinones. Our study suggests that thyroid H(2)O(2) is produced by divalent reduction of oxygen without O(2)(-) generation. If thyroid cells happen to be exposed to significant amount of reactive oxygen species, TPO and subsequent thyroid hormone formation are inhibited.     

Effects of thyrotropin and thyroid hormones in vivo on thyroid responsiveness to thyrotropin in vitro.

The thyroid gland of rats fed propylthiouracil is known to be unresponsive in vitro to thyrotropin; to investigate further the underlying mechanism groups of rats were variously treated with propylthiouracil and thyroid hormone or subjected to hypophysectomy. In vitro responsiveness of the thyroids was tested by measuring an increase in the concentration of c AMP when thyrotropin or prostaglandin E1 was added to the medium. Results showed that responsiveness to thyrotropin partially returned with rats fed prophylthiouracil and hypophysectomized 5, but not 2, days before death; hypophysectomy of normal rats led to increased in vitro responsiveness to thyrotropin and this was partially reversed by injections of thyrotropin for a week before death. Administration of thyroid hormone had little effect in these investigations and in vitro responsiveness to prostaglanding E1 was not consistently influenced by any of the in vivo regimens. From this experience we conclude that, at least as studied in vitro, circulating thyrotropin has a significant role in modulating responsiveness of the thyroid to thyrotropin.     

Dietary selenium status and plasma thyroid hormones in chicks

Experiments were conducted to study the effect of marginal levels of selenium and vitamin E on plasma thyroid hormones of meattype chicks. Plasma thyroxine (T₄) was significantly increased when a semipurified diet was supplemented with either selenium or vitamin E. Triiodothyronine (T₃) was also significantly increased by vitamin E and in one experiment with selenium supplementation. No significant increase in these hormones was observed in birds fed a corn-soybean-meal diet supplemented with these nutrients. Plasma corticosterone level was reduced and weight of the bursa of Fabricius increased by selenium or vitamin E supplementation. These nutrients may be necessary for providing the optimum thyroid conditions for activity of thyroid peroxidase.     

Frequent epigenetic inactivation of RASSF10 in thyroid cancer

The Ras association domain family (RASSF) encodes for distinct tumor suppressors and several members are frequently silenced in human cancer. In our study, we analyzed the role of a novel RASSF member termed RASSF10 in thyroid carcinogenesis. The RASSF10 CpG island promoter was intensively methylated in nine thyroid cancer cell lines and in 66% of primary thyroid carcinomas. RASSF10 methylation was significantly increased in primary thyroid carcinoma compared to normal thyroid and follicular adenoma (0% and 10%, respectively; p     

Mechanisms and pathogenesis of thyroid cancer in animals and man

The transformation of the normal fully differentiated thyroid follicular cell to the rapidly growing undifferentiated anaplastic thyroid carcinoma cell involves a number of stages which have been defined morphologically and are now being related to various growth pathways and to molecular biological defects. The two main factors involved in this transformation are growth stimulation and mutagenesis. Growth stimulation alone, through elevated TSH, can lead to the development of thyroid tumours, usually benign, and retaining TSH dependency in some cases. Mutagens alone, if growth is suppressed, do not produce tumours, the combination of mutagens and increased growth is a potent carcinogenic regime. Non-genotoxic carcinogenesis in the thyroid involves growth, without mutagenesis the agent often causes this through affecting one component of thyroid hormone synthesis or metabolism, leading to a fall in thyroid hormone levels and a rise in TSH. Growth stimulation increases the rate of cell division, and therefore increases the chance of a mutation. Continued growth increases the change of subsequent events, in particular loss of heterozygosity in a tumour suppressor gene. The main oncogenes involved in human thyroid carcinogens are ras in the follicular tumour pathway, and ret in the papillary carcinoma pathway. p53 is involved in the progression of either papillary or follicular adenoma to an undifferentiated carcinoma. In experimental thyroid carcinogenesis, ras is again involved, with a link between the mutagenic agent used and the type of ras gene showing mutation. Analysis of the involvement of different growth factors and oncogenes in thyroid carcinogenesis suggests that genes related to the two receptors concerned with normal TSH stimulated growth, TSH receptor and the IGF1 recpptor may be involved in the progression of thyroid tumours of follicular pathology. Several tyrosine kinase receptors with unknown ligands or of uncertain physiological function are linked to papillary carcinoma. The recent large increase in papillary carcinoma of the thyroid in children exposed to fallout from the Chernobyl nuclear accident underlines the importance of understanding the pathobiology of thyroid neoplasia.     

Messenger RNA properties of primary cultures of thyroid cells isolated from normal thyroid tissue and from patients with various thyroid diseases.

When compared to cells isolated from normal thyroid tissue, cells isolated from colloid adenoma have the same total polyadenylic acid content and total template activity. However, in both the cells isolated from diffuse non toxic goiter and from toxic adenoma, these two values are increased, the most striking effect being observed in the latter case. Moreover, as compared to normal thyroid tissue, in the three thyroid diseases and particularly in toxic adenoma, we observed an increase in the polyadenylic acid and messenger activity associated to RNA sedimenting at greater than 30 S, which correspond probably to thyroglobulin messenger RNA.     

Increased thyrotropin binding in hyperfunctioning thyroid nodules

The object of this study was to investigate TSH receptors in hyperfunctioning thyroid nodules (HFN). In HFN, obtained from seven patients, 125-I-TSH binding as determined by equilibrium binding analysis on particulate membrane preparations, was found to be significantly increased as compared with normal thyroid tissues (five patients; P less than 0.001). Scatchard analysis of TSH-binding revealed two kinds of binding sites for both normal thyroid tissue and HFN, and displayed significantly increased association constants of high- and low-affinity binding sites in HFN (Ka = 11.75 +/- 6.8 10(9) M-1, P less than 0.001 and Ka = 2.1 +/- 1.0 10(7) M-1, P less than 0.025; x +/- SEM) as compared with normal thyroid tissue (Ka = 0.25 +/- 0.06 10(9) M-1, Ka = 0.14 +/- 0.03 10(7) M-1; x +/- SEM). The capacity of the high-affinity binding sites in HFN was found to be decreased (1.8 +/- 1.1 pmol/mg protein, x +/- SEM) in comparison with normal thyroid tissue (4.26 +/- 1.27 pmol/mg protein; x +/- SEM). TSH-receptor autoradiography applied to cryostatic tissue sections confirmed increased TSH binding of the follicular epithelium in HFN. These data suggest that an increased affinity of TSH-receptor sites in HFN in iodine deficient areas may be an important event in thyroid autonomy.     

TSH-stimulated increases in calcium uptake and calmodulin levels in thyroid cells

This is the first report to show that polypeptide hormone increases cellular calmodulin contents. In cultured porcine thyroid cells, 6 days' exposure to TSH (above 0.02 mU/ml) increased cellular calmodulin contents. Six days' exposure to TSH also increased calcium uptake in thyroid cells. This TSH-stimulated increase in calcium uptake was partly due to the increase in cellular calmodulin contents.     

Proteome analysis in thyroid pathology

The incidence of thyroid cancer has continuously increased due to its detection in the preclinical stage. Clinical research in thyroid pathology is focusing on the development of new diagnostic tools to improve the stratification of nodules that have biological, practical and economic consequences on the management of patients. Several clinical questions related to thyroid carcinoma remain open and the use of proteomic research in the hunt for new targets with potential diagnostic applications has an important role in the solutions. Many different proteomic approaches are used to investigate thyroid lesions, including mass spectrometry profiling and imaging technologies. These approaches have been applied to different human tissues (cytological specimens, frozen sections, formalin-fixed paraffin embedded tissue or Tissue Micro Arrays). Moreover, other specimens are used for biomarker discovery, such as cell lines and the secretome. Alternative approaches, such as metabolomics and lipidomics, are also used and integrated within proteomics.     

Characterization of a monoclonal antibody to hog thyroid peroxidase and its use for immunohistochemical localization of the peroxidase in the thyroid gland

A monoclonal antibody (30.1.2) to hog thyroid peroxidase was produced, purified, and characterized. The IgG of 30.1.2 formed an immune complex with the peroxidase in a 1:2 or 1:1 molar ratio depending on the IgG to antigen ratio in the incubation mixture. Immune complex formation did not inhibit the peroxidase activity, which was actually activated 2-fold in the 1:1 complex. Studies of the binding of the conjugate of the IgG or its Fab' with horseradish peroxidase to untreated and acetone-treated thyroid microsomes showed that the IgG conjugate could bind to only a very small portion of the total binding sites (thyroid peroxidase) present in untreated microsomes even after prolonged incubation. The binding of the Fab' conjugate to untreated microsomes, on the other hand, increased as the incubation time was increased, reaching 40% of the total sites after 20 h of incubation. These findings indicated that thyroid peroxidase is localized on the inner surface of the microsomal membranes and that the Fab' conjugate, but not the IgG conjugate, can slowly penetrate through the membrane barrier to reach the peroxidase. Immunohistochemical experiments using the Fab' conjugate as a probe revealed that most thyroid peroxidase in the thyroid gland is located in the endoplasmic reticulum and perinuclear cisternae of the follicular cell, although a small amount could occasionally be detected in the apical membrane including microvilli. In contrast to previous reports, no thyroid peroxidase could be found in other cellular structures such as Golgi apparatus and apical vesicles by the immunohistochemical technique employed.     

Effects of substance P on thyroidal cyclic AMP levels and thyroid hormone release from canine thyroid slices

A neuropeptide, substance P (1-50 microM) caused a prompt but transient rise in tissue cyclic AMP levels and also increased the release of thyroid hormones from canine thyroid slices. While norepinephrine markedly inhibited the stimulation by TSH of such parameters as reported previously, substance P had no effect. These results suggest that substance P may play a regulatory role in thyroid gland functions in a manner different from norepinephrine.     

Influence of thyroid hormones and catecholamines on myosin of swim-exercised rats

To define the physiological signals involved in the redirection of myosin expression in the swim-exercised rat, the relative influence of thyroid hormones and beta-adrenergic blockade was determined. Swimming exercise resulted in an increased proportion of myosin V1 (60.9 +/- 9.7 vs. 38.0 +/- 4.1% of sedentary rats fed ad libitum) but did not increase serum concentrations of total and free thyroxine or triiodothyronine determined either 17-21 h or immediately after swimming. The proportion of V1 increased, although intermittently food-deprived rats with the body weight of swimming rats exhibited a reduced proportion of V1 (23.5 +/- 2.7). When swimming rats had only intermittent access to food, they had reduced concentrations of all thyroid hormones, but the proportion of V1 (51.5 +/- 7.6) was nonetheless increased. Thus the redirection of myosin expression cannot be attributed to an increased secretion of thyroid hormones. The influence of the adrenergic system was assessed by treating swimming rats with the beta-blocking drug atenolol. Because the proportion of V1 was reduced, but thyroid hormones were not affected, beta-adrenergic blockade seems to influence myosin expression independently of thyroid hormones.     

Bone turnover in overt and subclinical hyperthyroidism due to autonomous thyroid adenoma.

Parameters of bone turnover were measured in 20 premenopausal women affected by autonomous thyroid adenoma: 7 patients were suffering from overt hyperthyroidism with raised values of free thyroid hormones; 13 were clinically euthyroid and had normal values of free thyroid hormones. In all cases serum TSH concentrations were below the lower normal limit of our laboratory (< 0.4 mU/l). Eleven healthy premenopausal women were studied as a control group. Patients with overt hyperthyroidism disclosed a significant enhancement of both bone resorption (increased serum calcium and urinary excretion of hydroxyproline) and bone formation (increased serum levels of osteocalcin and alkaline phosphatase) when compared both to controls and to patients with subclinical hyperthyroidism. No significant alterations of bone metabolism parameters were found in patients with subclinical hyperthyroidism in comparison with controls. Therefore, in premenopausal women affected by autonomous thyroid adenoma the bone turnover appeared to be significantly increased when the serum values of free thyroid hormones were raised in the group of patients with overt hyperthyroidism.     

Glucose tolerance and incidence of pancreatic islet cell antibodies in pregnancy in women with thyroid autoantibodies

The prevalence of pancreatic islet cell antibodies (ICA) and complement fixing ICA (CF-ICA) and the effect of pregnancy of glucose tolerance was studied in 3 groups of women. One group had thyroid autoantibodies in serum detected in early pregnancy and subsequent development of postpartum thyroiditis (PPT), another group had thyroid autoantibodies without signs of PPT and the third group did not have thyroid autoantibodies or PPT. In the women with thyroid autoantibodies and PPT, ICA were found in one of 12 women (8%, 95% confidence limits 0-38%). In the group with thyroid autoantibodies without PPT, ICA were found in three of 27 women (11%, 2-29%), whereas two of 20 women without thyroid autoantibodies had ICA (10%, 1-32%), N.S. Where present, serum ICA levels were very low and similar in early pregnancy and 6 months postpartum. CF-ICA were only found in two women with thyroid autoantibodies without signs of PPT. In all groups glucose tolerance was impaired in pregnancy when compared to postpartum despite an increased insulin response to glucose ingestion. In pregnancy, however, glucose tolerance was more impaired in the women with thyroid autoantibodies and subsequent PPT, than in the women without thyroid autoantibodies. Postpartum glucose tolerance was similar in all groups. It is concluded, that the presence of thyroid autoantibodies in early pregnancy or development of PPT is not accompanied by an increased prevalence of islet cell antibodies, but women with thyroid autoantibodies and subsequent PPT have a significantly more reduced glucose tolerance in late pregnancy than women without thyroid autoantibodies.     

Transmembrane controls in cultured human thyroid carcinoma

It is well known that many of thyroid carcinoma are capable of responding to TSH, but our studies shown that there are some alteration in this responsiveness. The adenylate cyclase responsiveness to TSH was usually greater in thyroid carcinoma than in adjacent histologically normal thyroid tissue. The level of increased response of adenylate cyclase were correlated with the level of enhanced expression of ras oncogene product p21 assessed by Western blotting analysis. The TSH induced desensitization of adenylate cyclase was not observed in some differentiated carcinoma. This loss of desensitization may be reflect the change in ADP-ribosylable Gi protein. In the differentiated carcinoma, the capacity of EGF receptor was higher than that in normal thyroid. The EGF binding to cultured carcinoma cells did not increase in response to TSH. These altered properties of transmembrane control in human thyroid carcinoma may be related to the neoplastic growth.     

Mechanisms of action of thyroid hormones in the skeleton

Background

Thyroid hormones regulate skeletal development, acquisition of peak bone mass and adult bone maintenance. Abnormal thyroid status during childhood disrupts bone maturation and linear growth, while in adulthood it results in altered bone remodeling and an increased risk of fracture

Scope of Review

This review considers the cellular effects and molecular mechanisms of thyroid hormone action in the skeleton. Human clinical and population data are discussed in relation to the skeletal phenotypes of a series of genetically modified mouse models of disrupted thyroid hormone signaling.

Major Conclusions

Euthyroid status is essential for normal bone development and maintenance. Major thyroid hormone actions in skeletal cells are mediated by thyroid hormone receptor α (TRα) and result in anabolic responses during growth and development but catabolic effects in adulthood. These homeostatic responses to thyroid hormone are locally regulated in individual skeletal cell types by the relative activities of the type 2 and 3 iodothyronine deiodinases, which control the supply of the active thyroid hormone 3,5,3’-L-triiodothyronine (T3) to its receptor.

General Significance

Population studies indicate that both thyroid hormone deficiency and excess are associated with an increased risk of fracture. Understanding the cellular and molecular basis of T3 action in skeletal cells will lead to the identification of new targets to regulate bone turnover and mineralization in the prevention and treatment of osteoporosis. This article is part of a Special Issue entitled Thyroid hormone signaling.