Assessment of thyroid function in adult medaka (Oryzias latipes) and juvenile rainbow trout (Oncorhynchus mykiss) using immunostaining methods

The effect of injected bovine TSH on the pattern of anti-T(4) and anti-T(3) immunostaining of the thyroid tissue was examined in rainbow trout (Oncorhynchus mykiss) and medaka (Oryzias latipes) to determine if the previously reported immunostaining of the cytoplasm of thyrocytes is due to the presence of colloid pinocytotic vesicles and is thus indicative of thyroid hormone release. We hypothesized that the number of immunostained thyrocytes should increase following a TSH challenge, and this should parallel other indicators of increased thyroid activity. In medaka, immunostained thyrocytes were only found following the TSH challenge, and were most marked after 24 to 72 hours; the immunostaining was associated with large colloid-filled cytoplasmic vesicles. In trout, the number and staining intensity of immunostained thyrocytes were increased after the TSH challenge; the immunostaining was present throughout the cytoplasm of the thyrocytes. These findings support the working hypothesis that the immunostaining of the thyrocytes is associated with the pinocytosis of thyroglobulin by the thyrocytes in parallel with an increase in release of thyroid hormone, and that this investigational approach provides a reliable indicator of thyroid hormone release activity.     

An Ex vivo Culture System to Study Thyroid Development

The thyroid is a bilobated endocrine gland localized at the base of the neck, producing the thyroid hormones T3, T4, and calcitonin. T3 and T4 are produced by differentiated thyrocytes, organized in closed spheres called follicles, while calcitonin is synthesized by C-cells, interspersed in between the follicles and a dense network of blood capillaries. Although adult thyroid architecture and functions have been extensively described and studied, the formation of the “angio-follicular” units, the distribution of C-cells in the parenchyma and the paracrine communications between epithelial and endothelial cells is far from being understood.This method describes the sequential steps of mouse embryonic thyroid anlagen dissection and its culture on semiporous filters or on microscopy plastic slides. Within a period of four days, this culture system faithfully recapitulates in vivo thyroid development. Indeed, (i) bilobation of the organ occurs (for e12.5 explants), (ii) thyrocytes precursors organize into follicles and polarize, (iii) thyrocytes and C-cells differentiate, and (iv) endothelial cells present in the microdissected tissue proliferate, migrate into the thyroid lobes, and closely associate with the epithelial cells, as they do in vivo.Thyroid tissues can be obtained from wild type, knockout or fluorescent transgenic embryos. Moreover, explants culture can be manipulated by addition of inhibitors, blocking antibodies, growth factors, or even cells or conditioned medium. Ex vivo development can be analyzed in real-time, or at any time of the culture by immunostaining and RT-qPCR.In conclusion, thyroid explant culture combined with downstream whole-mount or on sections imaging and gene expression profiling provides a powerful system for manipulating and studying morphogenetic and differentiation events of thyroid organogenesis.     

Thyroid stimulating hormone upregulates secretion of cathepsin B from thyroid epithelial cells

Constant levels of thyroid hormones in the blood are principal requirements for normal vertebrate development. Their release depends on the regulated proteolysis of thyroglobulin which is extracellularly stored in the follicle lumen under resting conditions. Thyroglobulin is proteolytically degraded to a major part in lysosomes, but in part also extracellularly leading to the release of thyroxine. Extracellularly occurring lysosomal enzymes are most probably involved in the proteolytic release of thyroxine. In this study we have analyzed the secretion of cathepsin B by thyroid follicle cells (primary cells as well as FRTL-5 cells) and its regulation by thyroid stimulating hormone, which stimulated the secretory release of the proenzyme as well as of mature cathepsin B. Within one to two hours of stimulation with thyroid stimulating hormone, the cathepsin B activity associated with the plasma membrane increased significantly. This increase correlated closely with the localization of lysosomes in close proximity to the plasma membrane of cultured thyrocytes as well as with the thyroxine liberating activity of thyrocyte secretion media. These observations indicate that thyroid stimulating hormone induces the secretion of cathepsin B, which contributes to the extracellular release of thyroxine by thyrocytes.     

Structural and ultrastructural differentiation of the thyroid gland during embryogenesis in the grass snake Natrix natrix L. (Lepidosauria, Serpentes)

The differentiation of the thyroid primordium of reptilian species is poorly understood. The present study reports on structural and ultrastructural studies of the developing thyroid gland in embryos of the grass snake Natrix natrix L. At the time of oviposition, the thyroid primordium occupied its final position in the embryos. Throughout developmental stages I-IV, the undifferentiated thyroid primordium contained cellular cords, and the plasma membranes of adjacent cells formed junctional complexes. Subsequently, the first follicular lumens started to form. The follicular lumens were of intracellular origin, as in other vertebrate species, but the mechanism of their formation is as yet unclear. At developmental stages V-VI, the thyroid anlage was composed of small follicles with lumens and cellular cords. Cells of the thyroid primordium divided, and follicles were filled with a granular substance. At developmental stage VI, the cells surrounding the follicular lumen were polarized, the apical cytoplasm contained dark granules and the Golgi complex and the rough endoplasmic reticulum (RER) developed gradually. Resorption of the colloid began at developmental stage VIII. At the end of this stage, the embryonic thyroid gland was surrounded by a definitive capsule. During developmental stages IX-X, the follicular cells contained granules and vesicles of different sizes and electron densities and a well-developed Golgi apparatus and RER. At developmental stage XI, most follicles were outlined by squamous epithelial cells and presented wide lumens filled with a light colloid. The Golgi complex and RER showed changes in their morphology indicating a decrease in the activity of the thyroid gland. At developmental stage XII, the activity of the embryonic thyroid gradually increased, and at the time of hatching, it exhibited the features of a fully active gland.     

Expressions of Raldh3 and Raldh4 during zebrafish early development

Retinoic acid (RA) plays crucial roles in vertebrate embryogenesis. Four retinal dehydrogenases (Raldhs) that are responsible for RA synthesis have been characterized in mammals. However, only Raldh2 ortholog is identified in zebrafish. Here, we report the identification of raldh3 and raldh4 genes in zebrafish. The predicted proteins encoded by zebrafish raldh3 and raldh4 exhibit 70.0% and 73.5% amino acid identities with mouse Raldh3 and Raldh4, respectively. RT-PCR analyses reveal that both raldh3 and raldh4 mRNAs are present in early development. However, whole mount in situ hybridization shows that raldh3 mRNA is first expressed in the developing eye region of zebrafish embryos at 10-somite stage. At 24 hpf (hours post fertilization), raldh3 mRNA is expressed in the ventral retina of eye. At 36 hpf, the mRNA is also expressed in otic vesicle in addition to ventral retina, and it maintains its expression pattern till 2 dpf (days post fertilization). At 3 dpf, raldh3 mRNA becomes very weak in ventral retina but is present in otic vesicle at a high level. At 5 dpf and 7 dpf, raldh3 is no longer expressed in eyes but is expressed in otic vesicles at a very low level. raldh4 mRNA is initially detected in developing liver and intestine regions at 2 dpf embryos. Its expression level becomes very high in these two regions of embryos from 3 dpf to 5 dpf. Analysis on the sections of 5 dpf embryos reveals that raldh4 is expressed in the epithelium of intestine. At 7 dpf, raldh4 mRNA is only weakly expressed in the epithelium of intestinal bulb.     

Covalent cross-linking of secreted bovine thyroglobulin by transglutaminase.

Extracellular storage of thyroglobulin (TG) is a prerequisite for maintaining constant levels of thyroid hormones in vertebrates. Storage of TG within the follicle lumen is achieved by compactation and by the formation of covalent cross-links between TG molecules. In bovine thyroids, approximately 75% of the cross-links are other than disulfide bonds (J. Cell Biol. 180, 1071-1081). We have now shown that polymeric TG contains a large number of N(epsilon)(gamma-glutamyl)lysine cross-links and that only traces of these can be found in the soluble form of TG. Because such isopeptide bridges are generated usually by the action of a transglutaminase, it is reasonable to propose that the covalent polymerization of TG in the globules is under the control of this enzyme. Soluble TG was shown to be a substrate for transglutaminase in vitro; moreover, the presence of transglutaminase was demonstrated by immunofluorescence and by immunoblotting in freshly isolated bovine thyroid globules. With immunoelectron microscopy, transglutaminase was detected in the cytoplasm of thyrocytes, but not in compartments of the secretory pathway. Only one messenger RNA for transglutaminase was found by Northern blotting. Sequencing of the cloned gene failed to reveal a secretory signal, which supports the notion that the thyroid transglutaminase is the cytosolic type. Apparently, the enzyme reaches the lumen of the follicle by an as yet unknown pathway to catalyze the covalent cross-linking of thyroid globules in this extracellular compartment.     

Hollowing or cavitation during follicular lumen formation in the differentiating thyroid of grass snake Natrix natrix L. (Lepidosauria,Serpentes) embryos? An ultrastructural study

The mechanism of follicular lumen differentiation during thyroid gland morphogenesis in vertebrate classes is still unclear and the current knowledge regarding the origin and the mechanism of follicular lumen formation during thyroid differentiation in reptiles is especially poor. The present study reports on an ultrastructural investigation of thyroid follicle formation and follicular lumen differentiation in grass snake (Natrix natrix L.) embryos. The results of this study show that the earliest morphogenesis of the presumptive thyroid follicles in grass snake embryos appears to be similar to that described in embryos of other vertebrate classes; however, differences appeared during the later stages of its differentiation when the follicular lumen was formed. The follicular lumen in grass snake embryos was differentiated by cavitation; during thyroid follicle formation, a population of centrally located cells was cleared through apoptosis to form the lumen. This manner of follicular lumen differentiation indicates that it has an extracellular origin. It cannot be excluded that other types of programmed cell death also occur during follicular lumen formation in this snake species.     

Development of cell-to-cell relationships in the thyroid gland of the chick embryo

Summary Thyroid glands of 7 to 21 day-old chick embryos were examined by electron microscopy using freeze-fracture and thin-section preparations. The primitive follicle lumen first appears between two adjacent epithelial cells in 8 day-old embryos, and is formed in the region of a focal tight junction (macula occludens). The focal tight junction develops into the zonula occludens when the primitive follicle lumen first forms.The zonula occludens is, at first, composed of 4.6 ± 2.45 strands, but with increasing embryonic age the number of strands increases to 5.9 ± 1.41 in 13 day-old, and 8.0 ± 1.75 in 19 day-old embryos.Thyroglobulin stored within the embryonic gland lumina is isolated from the mesenchymal tissue even at the first appearance of these follicle cavities.Well developed gap junctions already occur in the thyroid gland of the 7 day-old embryo, so that an intimate relationship and communication between these cells already exists at the time of their functional differentiation.This study was supported by a grant from the Japan Ministry of Education     

Changes in thyroid hormone levels during zebrafish development

The zebrafish (Danio rerio) has been used as a model for the study of endocrine disrupting chemicals. This study set out to determine the profiles of whole-body thyroxine (T4) and 3,5,3'-triiodothyronine (T3) levels during the development of zebrafish from embryo to adult. Enzyme-linked immunoassay was used to analyze whole-body T4 and T3 contents. The results showed that whole-body T4 and T3 levels remained stable during the pre-hatching period (0-3 d) and increased significantly during early development after hatching. The T3 level peaked at 0.28 ± 0.01 ng g(-1) body weight at 10 days post-fertilization (dpf), and T4 peaked at 0.58 ± 0.09 ng g(-1) body weight at 21 dpf. Both thyroid hormones subsequently declined during later development. This study establishes a baseline for thyroid hormones in zebrafish, which will be vital for the understanding of thyroid hormone functions and in future studies of thyroid toxicants in this species.     

Histological and ultrastructural alterations of rat thyroid gland after short-term treatment with high doses of thyroid hormones

The aim of the present study was to investigate histological alterations of rat thyroid gland after short-term treatment with supraphysiological doses of thyroid hormones. Rats from experimental groups were treated with triiodothyronine (T3) or thyroxine (T4) during five days. In both treated groups, thyrocyte height was reduced and follicular lumens were distended. Progressive involutive changes of the thyroid parenchyma were apparent, including follicular remodeling (fusion) and death of thyrocytes. Morphological changes confirmed by quantitative analysis were more pronounced in the T4-treated group. Our results demonstrate that thyrotoxicosis, whether induced by T3 or T4, leads to different grades of thyroid tissue injury, including some irreversible damages. These changes might be explained at least in part by lack of trophic and cytoprotective effects of the thyroid stimulating hormone. Since the period required for morphophysiological recovery may be unpredictable, findings presented here should be taken into consideration in cases where the thyroid hormones are used as a treatment for thyroid and non-thyroid related conditions.     

Thyroid hormones in grey seal pups (Halichoerus grypus).

The aim of the present study was to describe the changes in thyroid hormone status in grey seal (Halichoerus grypus) pups from birth to weaning and moulting. Plasma concentrations of total thyroxine (tT4) were highest the first two days after birth, thereafter dropping to a lower, but stable level. This pattern may reflect a high transfer rate of maternal thyroxine prepartum, prior to parturition, or postpartum via colostrum, or it may be caused by active secretory thyrocytes in late foetal stage. Total triiodothyronine (tT3) concentrations were lowest in neonatal pups, and increased as a function of age, indicating that deiodination of T4 to T3 increases as a function of age. Plasma concentrations of free thyroxine (fT4) did not vary as a function of age. All hormone concentrations were higher than previously reported in adults, probably reflecting the important role of these hormones in regulating their high rates of metabolism and tissue synthesis and the growth of their juvenile pelage. Since polychlorinated biphenyls (PCBs) have been reported to affect plasma concentrations of thyroid hormones in seals, the information on thyroid hormone concentrations and dynamics reported in grey seal pups from a pristine Norwegian coastal environment provide valuable reference material for future studies on pups from more polluted areas.     

The age at onset of diabetes influences functional and structural changes in the pituitary-thyroid axis of streptozocin-diabetic male rats

Severe structural changes leading to marked alterations in secretory activity are known to occur in the pituitary-thyroid axis 1 month after induction of postpuberal streptozocin (SZ)-diabetes. However, SZ-diabetic rats of different age groups have not been compared, nor has the maturity of the pituitary and thyroid glands at the onset of diabetes been correlated with the type and evolution of functional and structural changes. We thus induced diabetes in 1-month (prepuberal of 3-month (postpuberal) old male rats and compared diabetic with control groups 4 and 8 months after SZ or saline injection. We determined: 1) pituitary and thyroid weights, 2) the basal plasma TSH, T3, and T4 concentrations, and 3) several morphometrical measurements in the pituitary and thyroid glands. After 4 months, 1) the pituitary and thyroid weights were decreased, 2) plasma TSH and T3 were unchanged, plasma T4 was reduced. and 3) the number of thyrotropes, degenerative changes of follicle cells, and colloid area were increased, the follicle cell height as well as the number of fused cold follicles decreased, and the follicle area was unchanged in diabetic compared with control rats. The lesions were more conspicuous in pre- than in postpuberal diabetic animals. After 8 months, plasma TSH, T3, and T4 were decreased in diabetic compared with control rats. Except for the increased colloid area, all other lesions were similar, though more severe in prepuberal diabetic rats after 8 than 4 months. Few changes were found in postpuberal diabetic rats.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mannose 6-phosphate receptor in porcine thyroid follicle cells. Localization and possible implications for the intracellular transport of thyroglobulin

Thyroglobulin has been shown to be phosphorylated and to carry the mannose 6-phosphate (M6P) signal in terminal position. In order to investigate whether the cation-independent mannose 6-phosphate receptor (CI-MPR) can possibly play a role in the transport of thyroglobulin the localization of the receptor was analyzed in thyroid follicle cells. The immunocytochemical observations showed that the CI-MPR is primarily located in elements of the endocytic pathway such as coated pits and endosomes. This localization of the CI-MPR in thyrocytes differs from the receptor sites in other cell types by the rare occurrence of the CI-MPR in cisternae of the Golgi complex. The observations are interpreted as an indication that the relatively small amount of receptor in the Golgi complex might be occupied primarily by lysosomal hydrolases. The CI-MPR in thyrocytes might, therefore, be unable to bind and to convey thyroglobulin efficiently. The receptor is, however, a binding site for thyroglobulin at the apical plasma membrane and may, therefore, be involved in the binding of thyroglobulin and its transfer from the follicle lumen to lysosomes.     

Appearance of LH-immunoreactive cells in the Rathke's pouch of the chicken embryo

The differentiation of the pituitary of the chicken embryo was studied by means of an immunohistochemical technique using antisera to turkey and chicken pituitary hormones. Immunoreactive LH-cells are detected in 4-day embryos (stage 23 of Hamburger and Hamilton) when the primordium of the anterior pituitary, the Rathke's pouch is only composed of a single-layer epithelium lined with an undifferentiated mesenchyme. A few immunoreactive cells are observed grouped on the posterior aspect of the pouch. As development proceeds, a strip of positive cells is detected encircling the Rathke's pouch. Prolactin-, growth hormone-, and ACTH-immunoreactive cells are detected in 6- and 7-day embryos, only after the pituitary has acquired its characteristic structure with cords in which different cell types become progressively recognizable. The early appearance of immunoreactive LH-cells following a precise distribution shows that secretory properties and differentiation capacities are acquired simultaneously in the epithelium of the Rathke's pouch and may be induced by the same stimulus.     

Activation of MHC-restricted rat T cells by cloned syngeneic thyrocytes

We have previously demonstrated that rat thyrocytes express MHC class II Ag (RT1.B&D) in response to IFN-gamma. To determine whether MHC class II-positive thyrocytes can be recognized by MHC-restricted T cells, we used our clone of rat thyroid cells (1B-6) derived from the Fisher rat thyroid cell line (FRTL-5) and known to express MHC class II Ag in response to recombinant rat IFN-gamma. CD4+ and CD8+ normal syngeneic Fisher rat spleen T cells were selected by flow cytometry and averaged greater than 96% purity. We demonstrated that irradiated MHC class II-positive but not class II-negative 1B-6 thyrocytes stimulated CD4+ T cells in a primary sensitization reaction over 4 days. In contrast, CD8+ T cells had no response in similar experiments. This stimulation of CD4+ T cells was dose dependent for 1B-6 thyrocytes and was abrogated by anti-rat MHC class II mAb (MRC OX-6). Autoreactive (Fisher) and alloreactive (Buffalo) T cell lines and isolated CD4+ T cells derived from these lines, which were developed against Fisher rat spleen cells, similarly recognized MHC class II Ag expressed on 1B-6 cells but had no detectable response to 1B-6 MHC class II-negative thyrocytes or MHC class II-positive human thyroid cells. The CD4+ T cell recognition of 1B-6 cells via MHC class II Ag supports our previous data with autologous human thyroid T cell co-cultures and is indicative of an autospecific role for thyrocytes in the development of autoimmune thyroiditis.     

Appearence of LH-Immunoreactive Cells in the Rathke's Pouch of the Chicken Embryo

The differentiation of the pituitary of the chicken embryo was studied by means of an immunohistochemical technique using antisera to turkey and chicken pituitary hormones. Immunoreactive LH-cells are detected in 4-day embryos (stage 23 of Hamburger and Hamilton) when the primordium of the anterior pituitary, the Rathke's pouch is only composed of a single-layer epithelium lined with an undifferentiated mesenchyme. A few immunoreactive cells are observed grouped on the posterior aspect of the pouch. As development proceeds, a strip of positive cells is detected encircling the Rathke's pouch. Prolactin-, growth hormone-, and ACTH-immunoreactive cells are detected in 6- and 7-day embryos, only after the pituitary has acquired its characteristic structure with cords in which different cell types become progressively recognizable. The early appearance of immunoreactive LH-cells following a precise distribution shows that secretory properties and differentiation capacities are acquired simultaneously in the epithelium of the Rathke's pouch and may be induced by the same stimulus.     

Testosterone and estradiol modulate TSH-binding in the thyrocytes of Wistar rats: influence of age and sex.

Age and sex are important factors that influence thyroid pathophysiology. Though sex steroids are known to enhance thyrotropin (TSH) mRNA expression and incidence of thyroid tumours, there is no report on their effects on TSH action under normal physiological conditions. In the present study, the effects of testosterone (T) and estradiol (E2) on thyroidal TSH-receptor (TSH-R) concentration, and TSH-binding to thyrocytes (in vitro) were elucidated in immature and mature Wistar rats. Immature (10 days old) and adult (120 days old) rats of either sex were gonadectomized (GDX) and one group of GDX rats was treated with physiological doses of T and another with E2. Immature GDX rats were supplemented with the steroids for 10 days and adults were supplemented with the steroids for 30 days. While supplementation of steroids to immature rats was begun immediately after surgery, for adult rats it was started 10 days after gonadectomy. The rats were killed at the end of the experimental period. Gonadectomy significantly decreased serum TSH, and TSH-R concentration under in vivo condition and [125I]-TSH binding to thyrocytes under in vitro conditions. Supplementation of T to male and E2 to female GDX rats restored normality of the parameters. Thyrocytes of immature male rats challenged with linearly increasing doses of TSH or T (6.25-800 ng/ml) showed a dose-dependent increase in TSH-binding. However, thyrocytes of immature female rats challenged with T showed a gender-specific response. While there was a linear increase in TSH-binding in thyrocytes of males, a biphasic response was evident in thyrocytes of females. In the case of thyrocytes from adult rats, T induced a dose-dependent change in TSH-binding in males, which reached the peak in response to 12.5 ng T, and diminished thereafter. In contrast, E2 was inhibitory to TSH-binding to thyrocytes of adult male rats. On the other hand, E2 showed a clear gender-specific stimulation of TSH-binding in thyrocytes of females and an inhibition of the same in males. TSH and sex steroids upregulated TSH receptors in immature rats, whereas the effect was biphasic in adult rat thyrocytes. It is concluded from the present study that sex steroids modulate TSH-binding in rat thyrocytes, which may vary according to the age and sex of the animals.     

Thyrocytes,but not C cells,actively undergo growth and folliculogenesis at the periphery of thyroid tissue fragments in three-dimensional collagen gel culture

In the thyroid, new follicle formation from preexisting follicles (mother follicle-derived folliculogenesis) has been poorly understood. To address this issue, we analyzed mother follicle-derived folliculogenesis, using a thyroid tissue-organotypic culture that retains three-dimensional follicles with both thyrocytes and C cells over a long period. Three types of mother follicle-derived folliculogenesis occurred only at the periphery of the tissue fragments embedded in collagen gel: (1) solid nest, (2) budding and (3) lumen-dividing types. Immunohistochemistry showed that neogenic follicles rarely had calcitonin-positive C cells. Electron microscopy showed that their component thyrocytes expressed normal polarity. In growth, bromodeoxyuridine uptake of thyrocytes at the tissue periphery was about 5 times the uptake that occurred at the center. C cells had no uptake. Thyrotropin (TSH, 10 mU/ml) and free calcium (0.17~1.95 mM), which are associated with the biological behavior of thyrocytes and C cells, respectively, did not affect the events described above. The data indicate that thyrocytes, but not C cells, actively undergo growth and three types of mother follicle-derived folliculogenesis at the tissue periphery in a TSH- or free calcium-independent manner. This suggests that the tissue periphery, which may escape from contact inhibition of cell growth, is the regenerative site.