Changes in thyrotropin (TSH) carbohydrate structure and response to TSH-releasing hormone during postnatal ontogeny: analysis by concanavalin-A chromatography

Beneficial effects of thyroid hormone on adipose inflammation and insulin sensitivity of obese Wistar rats

Thyroid hormones play an important role in glucose metabolism and there is evidence of increased prevalence of thyroid dysfunction in obese and diabetic patients. This study aimed at evaluating the thyroid function and the effects of the triiodothyronine (T3) treatment on glycemia control, insulin sensitivity and subclinical inflammation in cafeteria‐diet‐induced obesity in rats. Obesity was induced in male Wistar rats by offering a cafeteria diet and a subset of the obese rats was treated with T3 (1.5 μg per 100 g of body weight) for a 28‐day period. The pituitary‐thyroid axis was evaluated by molecular and biochemical parameters. Cytokine content was measured in the serum as well as in the mesenteric and epididymal white adipose tissue. Obese rats exhibited impairment of glycemia control, increased content of inflammatory cytokines in mesenteric white adipose tissue, decreased serum thyrotropin (TSH) concentration and increased sodium/iodide symporter (NIS) and TSH receptor (TSHR) protein content in thyroid gland. T3 treatment improved insulin sensitivity, glucose tolerance, and reduced inflammatory cytokine content in mesenteric white adipose tissue. In the thyroid gland NIS, TSHR, and thyroperoxidase (TPO) content were reduced while thyroglobulin (TG) content was increased by T3. The thyrotrophic response to negative feedback exerted by T3 was preserved in obese rats. The present data reinforce the beneficial effects of T3 treatment of obese rats on the improvement of insulin sensitivity and on the negative modulation of inflammatory cytokine expression in adipose tissue. Moreover, we have evidenced that the pituitary‐thyroid axis is affected in obese rats, as illustrated by the impaired TSH secretion.

Glycosylation in the Thyroid Gland: Vital Aspects of Glycoprotein Function in Thyrocyte Physiology and Thyroid Disorders

The key proteins responsible for hormone synthesis in the thyroid are glycosylated. Oligosaccharides strongly affect the function of glycosylated proteins. Both thyroid-stimulating hormone (TSH) secreted by the pituitary gland and TSH receptors on the surface of thyrocytes contain N-glycans, which are crucial to their proper activity. Thyroglobulin (Tg), the protein backbone for synthesis of thyroid hormones, is a heavily N-glycosylated protein, containing 20 putative N-glycosylated sites. N-oligosaccharides play a role in Tg transport into the follicular lumen, where thyroid hormones are produced, and into thyrocytes, where hyposialylated Tg is degraded. N-glycans of the cell membrane transporters sodium/iodide symporter and pendrin are necessary for iodide transport. Some changes in glycosylation result in abnormal activity of the thyroid and alteration of the metabolic clearance rate of hormones. Alteration of glycan structures is a pathological process related to the progression of chronic diseases such as thyroid cancers and autoimmunity. Thyroid carcinogenesis is accompanied by changes in sialylation and fucosylation, β1,6-branching of glycans, the content and structure of poly-LacNAc chains, as well as O-GlcNAcylation, while in thyroid autoimmunity the main processes affected are sialylation and fucosylation. The glycobiology of the thyroid gland is an intensively studied field of research, providing new data helpful in understanding the role of the sugar component in thyroid protein biology and disorders.

Thyroid morphology and subclinical hypothyroidism in children and adolescents with Williams syndrome

OBJECTIVE

To verify the prevalence of morpho-volumetric and functional thyroid abnormalities in young patients with Williams syndrome (WS).

STUDY DESIGN

Ninety-two patients with WS (49 boys and 43 girls, 0.2-17.2 years of age) underwent evaluation of thyroid function by means of thyroid-stimulating hormone (TSH), fT3, and fT4 measurement. Thyroid ultrasonography was performed in 37 patients. Thyroid antibodies (thyroid peroxidase and thyroglobulin) were measured in all patients with abnormal thyroid function tests.

RESULTS

None of our patients had overt hypothyroidism; 29 patients (31.5%) had subclinical hypothyroidism. Thyroid antibodies were absent in all patients. The prevalence of patients with subclinical hypothyroidism was significantly higher in the younger patients. Ultrasonography revealed morphological or volumetric abnormalities of the thyroid gland in 67.5% of patients; these abnormalities were more frequently observed in the older children.

CONCLUSIONS

Subclinical hypothyroidism is a frequent but stable finding in young children with WS. The great majority of patients with WS >10 years, either with normal or hypoplastic thyroid, have normal thyroid function. Therefore, we suggest yearly monitoring of thyroid function and sonographic studies at least once in patients with WS. Treatment should be reserved for the patients with overt hypothyroidism or for those whose thyroid function shows signs of progressive deterioration.

Thyroid hemiagenesis and elevated thyrotropin levels in a child with Williams syndrome

A girl with Williams syndrome (WS) presented with elevated thyrotropin (TSH) levels (7.0 microU/ml), normal free thyroid hormone concentrations, and absent antithyroid autoantibodies. Thyroid ultrasonography and scintigraphy showed hemiagenesis of the left lobe and no evidence of ectopic tissue. TSH response to thyrotropin-releasing hormone (TRH) injection (200 microg/mq, i.v.) was exaggerated and prolonged, suggesting subclinical hypothyroidism. The biological activity of circulating TSH was slightly below the normal range [TSH bioactivity (B) to immunoreactivity (I) ratio (TSH B/I) = 0.4, normal: 0.6-2.2]. These abnormalities are similar to those seen in patients with hypothalamic hypothyroidism. Thyroid function is not a recognized manifestation of WS and is not routinely investigated. However, abnormalities of the hypothalamic-pituitary-thyroid (HPT) axis and thyroid dysgenesis have been found in other WS cases. Genes mapping at 7q11.23, contiguous to the chromosomal region deleted in most WS patients, may be involved in the development of the thyroid gland, contributing to the complex phenotype of WS.

Hypothalamic thyrotropin-releasing hormone and thyrotropin biological activity

Hypothalamic thyrotropin-releasing hormone (TRH) is the main positive regulator of thyrotropin (TSH) secretion. TRH action and the negative feedback of thyroid hormone are integrated in order to guarantee appropriate thyroid stimulation. TRH action affects various steps of the biosynthetic process within thyrotrophs, with major effects on the posttranslational maturation of TSH oligosaccharide chains, and is necessary for the secretion of the glycoprotein hormone with full biological activity. Since the first description in 1979 of some patients with central hypothyroidism of hypothalamic origin associated with the secretion of TSH molecules with conserved immunoreactivity but decreased bioactivity, a large body of evidence has accumulated in more recent years showing that changes of the oligosaccharide chains have a great impact on the biological properties of circulating TSH and occur in various in vivo situations. These findings have lead to the new concept of a qualitative regulation of TSH secretion. This can be achieved mainly through the transcriptional and posttranscriptional regulation of the complex enzymatic machinery devoted to the processing of the three oligosaccharide chains linked to specific asparagine residues of TSH heterodimer. Data obtained in several physiological and pathological conditions, which are characterized by an increased or diminished TRH action, indicate that both qualitative and quantitative regulations cooperate within thyrotrophs in order to adjust thyroid-stimulating activity to the temporary needs.

Thyroid function in very preterm infants: influences of gestational age and disease

It is not known how immaturity and disease influence postnatal thyroid function in infants <30 wk of gestational age. We performed serial measurements of plasma thyroxine (T4), free T4 (FT4), triiodothyronine (T3), reverse T3 (rT3), TSH, and T4-binding globulin (TBG) in 100 infants of <30 wk of gestation, during the first 8 postnatal weeks, to investigate the influences of disease and gestational age on the time course of thyroid hormones. One hundred infants were divided twice into two groups: 1) in a group of 25-28 and of 28-30 wk of gestation; and 2) in a sick and a healthy group, with similar gestational ages. The time course of T4, FT4, T3, TSH, and TBG, but not rT3 differed significantly (p < 0.005) between the gestational age groups. T4 and FT4 decreased to levels below the cord blood value with a deeper FT4 nadir on d 7 in the youngest group. Disease decreased T4, FT4, T3, TSH, and TBG concentrations especially during the 1st wk after birth (p < 0.005). However, the FT4 nadir on d 7 was similar in sick and healthy infants. After 3 wk, T4, FT4, T3, and TBG were higher in the sick group compared with the healthy group. rT3 levels were not increased in sick infants. We conclude that the extent of the FT4 decrease after birth in infants of <30 wk gestation is mainly influenced by gestational age and probably reflects a transient depletion of thyroidal hormone reserves. rT3 cannot be used as a marker of nonthyroidal illness in very preterm infants.

Structures of high-mannose and complex oligosaccharides of mouse TSH and free alpha-subunits after in vitro incubation of thyrotropic tissue with TRH

To determine whether incubation of mouse thyrotropic tissue with TRH in vitro influenced the oligosaccharide structure of TSH, thyrotropic tumor tissue or pituitary tissue was incubated in vitro with [3H]mannose or with [35S]sulfate and [3H]methionine, in the absence or presence of TRH for times up to 24 h. [3H]mannose-labeled oligosaccharides from intracellular TSH and free alpha-subunits were analyzed by paper chromatography, and were predominantly Man9GlcNAc and Man8GlcNAc units both in the absence and presence of TRH. The [35S]sulfate/[3H]methionine ratio in secreted molecules was greater for TSH than for free alpha-subunits; within TSH heterodimers the ratio was greater for beta-subunits than alpha-subunits. The [35S]/[3H] ratio was not altered in TSH or free alpha-subunits by TRH. Analyses of [3H]mannose-labeled charged oligosaccharides by HPLC anion-exchange chromatography revealed similar types of oligosaccharides present on TSH subunits and free alpha-subunits (having one or two sulfate residues, one or two sialic acid residues, or both a sulfate and a sialic acid residue). These charged oligosaccharides occurred in different proportions on TSH subunits compared to free alpha-subunits, and also differed depending on whether the tissue source was tumorous or nontumorous. The proportions of oligosaccharide unit types were not altered by TRH. Thus, while this study provided information concerning the high-mannose and complex oligosaccharides of mouse TSH, there was no evidence that short incubations of tissues with TRH in vitro caused modulation of TSH oligosaccharide structures.

Changes in the sialylation and sulfation of secreted thyrotropin in congenital hypothyroidism

We have examined the oligosaccharide structure of secreted thyrotropin (TSH) in perinatal and mature rats with congenital primary hypothyroidism. Rat pituitaries from euthyroid control animals and those rendered hypothyroid by methimazole treatment were incubated with [3H]glucosamine in vitro. Secreted TSH was purified, and oligosaccharides were enzymatically released and characterized by anion-exchange HPLC. In perinatal hypothyroid animals compared with control animals, oligosaccharides from TSH alpha and beta subunits contained more species with three or more negative charges. Moreover, perinatal hypothyroid animals demonstrated a dramatic increase in the ratio of sialylated to sulfated species within oligosaccharides of the same negative charge (2.9- to 7.4-fold increase for TSH-alpha; 15.1- to 25.5-fold increase for TSH-beta). In mature hypothyroid 9-week-old animals compared with control animals, changes were less pronounced, suggesting that endocrine regulation of oligosaccharide structure is dependent upon the maturational state of the animal. These changes were specific for TSH because glycosylation of free alpha subunit (synthesized by the thyrotroph and gonadotroph) and of total glycoproteins was minimally altered by hypothyroidism. Together, these data provide direct evidence and characterization of specific changes in the structure of a secreted pituitary glycoprotein hormone occurring as a result of in vivo endocrine alterations during early development. Moreover, they provide a potential structural basis to explain the delayed clearance of both TSH and the gonadotropins with end-organ deficiency, which may have important implications for the in vivo biological activities of these hormones. Specifically, such posttranslational changes may be an important adaptive response to prevent the consequences of endocrine deficiency during early development.

Development of the thyroid

The fetal hypothalamic-pituitary-thyroid axis develops autonomously of maternal influence. System ontogenesis begins with the appearance and histological development of the thyroid and pituitary glands followed by development of the hypothalamus and the pituitary portal vascular system. Hypothalamic-pituitary control of thyroid function matures during the last half of human fetal development. Thyroid hormones undergo several types of biochemical transformations in tissues, including deiodination, side-chain metabolism, and conjugation with sulphate or glucuronide. Enzyme-mediated monodeiodination is the most important pathway. The first step in T4 metabolism is either outer-ring monodeiodination to active T3 or innerring monodeiodination to inactive rT3. Most T4 is metabolized to rT3 in fetal tissues and/or placenta and rT3 is the major circulating T4 metabolite in the fetus. Selective tissues, such as brain, can monodeiodinate T4 to T3, and this T3 is available for local action. Nuclear thyroid hormone receptors mature at different times in different tissues. Receptors appear earlier in brain than in liver and local T3 production and action may be important in fetal brain development. Most thyroid hormone actions, however, appear in the perinatal period, and infants with thyroid agenesis appear normal at birth and develop normally with prompt neonatal diagnosis and treatment. Premature infants, particularly those less than 30-32 weeks' gestational age, have an immature thyroid system and manifest a state of transient hypothalamic-pituitary TSH deficiency. This does not require treatment. Infants with primary hypothyroidism, either due to thyroid dysgenesis or to thyroid dyshormonogenesis, by contrast, require prompt diagnosis and treatment. Rarely an infant is born with permanent TSH deficiency with or without other pituitary hormone deficiencies. These infants also require prompt treatment. Mothers with thyroid disease or a history of thyroid disease and with IgG autoantibodies to thyroid gland TSH receptors may deliver infants with hypothyroidism or hyperthyroidism due to transplacental passage of the receptor-blocking or receptor-stimulating autoantibodies. These infants also require careful evaluation and management.

Thyroid function in embryonic and early posthatch chickens and quail

Technological advances, especially radioimmunoassays, have led to good descriptive information about the timing and pattern of development of the thyroid gland (TG) and circulating thyroid hormone (TH). Immunocytochemical studies in combination with more traditional techniques such as gland ablation and hormone replacement have revealed the time of appearance of each hormone in the axis, the relative amounts of hormone present in each gland at different developmental stages, and a general picture of the pattern of maturation of the hypothalamic-pituitary-thyroid axis. Studies of the pituitary control of the TG remain limited by the lack of adequately specific techniques for measuring avian thyroid-stimulating hormone. Our understanding of peripheral TH dynamics is progressing as a result of iodothyronine deiodinase assays but full understanding will require more elaborate studies that adequately characterize the enzyme system(s) in each case. Molecular techniques have made powerful strides in identifying the gene responsible for producing a protein that appears to be the triiodothyronine receptor. Receptor assays have revealed the pattern of changes in receptor-binding capacities during development but have not yet revealed how binding of hormone to the receptor triggers cellular activity. Molecular genetic techniques are being used to reveal the mechanisms whereby some examples of developmental events (e.g., malic enzyme synthesis) are induced by TH. Although it is not yet possible to assess the value of molecular studies in this area for developing practical applications, these techniques are revealing the fundamental biological roles of TH in growth and development.