Dedifferentiation of cultured thyroid cells by epidermal growth factor: some insights into the mechanism

Switching from MAPK-dependent to MAPK-independent repression of the sodium-iodide symporter in 2D and 3D cultured normal thyroid cells

Loss of sodium-iodide symporter (NIS) expression in thyroid tumour cells primarily caused by constitutive MAPK pathway activation is often refractory to small molecule MAPK inhibitors. Suggested mechanisms are rebound MAPK signalling and activation of alternative signalling pathways. Here we provide evidence that failure to recover down-regulated NIS by MEK inhibition is not specific to tumour cells. NIS mRNA levels remained repressed in TSH-stimulated primary thyroid cells co-treated with epidermal growth factor (EGF) and pan-MEK inhibitor U0126 in the presence of 5% fetal bovine serum or, independently of serum, in 3D cultured thyroid follicles. This led to inhibited iodide transport and iodination. In contrast, U0126 restituted thyroglobulin synthesis in EGF-treated follicular cells. Serum potentiated TSH-stimulated NIS expression in 2D culture. U0126 blocked down-regulation of NIS only in serum-starved cells with a diminished TSH response. Together, this suggests that morphogenetic signals modify the expression of NIS and recovery response to MEK inhibition.

Initiation of cell locomotility is a morphogenetic checkpoint in thyroid epithelial cells regulated by ERK and PI3-kinase signals

Epithelial locomotility is a fundamental determinant of tissue patterning that is subject to strict physiological regulation. The current study sought to identify cellular signals that initiate cell migration in cultured thyroid epithelial cells. Porcine thyroid cells cultured as 3-dimensional follicles convert to 2-dimensional monolayers when deprived of agents that stimulate cAMP/PKA signaling. This morphogenetic event is driven by the activation of cell-on-substrate locomotility, providing a convenient assay for events that regulate the initiation of locomotion. In this system, the extracellular signal regulated kinase (ERK) pathway became activated as follicles converted to monolayer, as demonstrated by immunoblotting for activation-specific phosphorylation and nuclear accumulation of ERK. Inhibition of ERK activation using the drug PD98059 effectively prevented cells from beginning to migrate. PD98059 inhibited cell spreading, actin filament reorganization and the assembly of focal adhesions, cellular events that mediate the initiation of thyroid cell locomotility. Akt (PKB) signaling was also activated during follicle-to-monolayer conversion and the phosphoinositide 3-kinase (PI3-kinase) inhibitor, wortmannin, also blocked the initiation of cell movement. Wortmannin did not, however, block activation of ERK signaling. These findings, therefore, identify the ERK and PI3-kinase signaling pathways as important stimulators of thyroid cell locomotility. These findings are incorporated into a model where the initiation of thyroid cell motility constitutes a morphogenetic checkpoint regulated by coordinated changes in stimulatory (ERK, PI3-kinase) and tonic inhibitory (cAMP/PKA) signaling pathways.

Nitric oxide donors inhibit iodide transport and organification and induce morphological changes in cultured bovine thyroid cells

Nitric oxide (NO) has been proposed as an intracellular signal in the thyroid. The NO effect on function and morphology of bovine thyroid follicles in culture was analyzed by using the NO donors sodium nitroprusside (SNP) and S-nitrosoglutathione (GSNO). Both NO donors induced a concentration-dependent NO release measured by the nitrite accumulation in the culture medium. The SNP (10 to 500 micromol/L) treatment for 24 hours significantly inhibited the uptake, organification and transport of iodide in a concentration-dependent manner. When SNP (50 micromol/L) was withdrawn from the culture medium after 24 hours' incubation, iodide uptake and organification were partially recovered at 24 hours and reached the control value at 48 hours, indicating a reversible effect of SNP. A possible involvement of cyanide in the SNP inhibitory effect was excluded because incubation of follicles with potassium cyanide (KCN) at concentrations estimated to be present in the medium (40 and 80 micromol/L) for 24 hours did not modify iodide uptake and organification. The GSNO (10 to 500 micromol/L) treatment for 24 hours also reduced the iodide uptake, organification and transport in a concentration-dependent manner. A significant inhibition of iodide organification was induced after incubation with 1000 micromol/L of N2, 2'-O-dibutyrylguanosine 3':5'-cyclic monophosphate ([Bu]2cGMP). Morphological evaluation by light microscopy revealed that the incubation with NPS or GSNO (500 micromol/L) produced cellular dispersion with loss of follicular cell aggregates that was evident at 96 hours exposure. Cell viability was not altered by 10-500 micromol/L SNP or GSNO (80% to 85%). We concluded that long-term NO exposure induces functional and morphological modifications compatible with a loss of differentiation in thyroid follicles. These observations further support a role of NO in the regulation of the thyroid function.

Protein tyrosine phosphorylation influences adhesive junction assembly and follicular organization of cultured thyroid epithelial cells

The follicular histoarchitecture of the thyroid forms the anatomical basis for thyroid physiology and is commonly disturbed in diseases of the thyroid. We have used cultured porcine thyroid cells to study thyroid epithelial morphogenesis and its regulation. When cultured in the presence of TSH, freshly isolated thyroid cells reorganize to form follicles within three-dimensional cell aggregates. However, when established follicles are washed into TSH-free medium, thyroid cells spread and migrate to convert follicles into confluent epithelioid monolayers, activating morphogenetic mechanisms, such as cell locomotility, that may be relevant to thyroid inflammation and tumor invasiveness. The phenomenon of follicle to monolayer conversion, therefore, provides an opportunity to identify morphogenetic mechanisms that 1) must be tonically inhibited to maintain follicular organization and 2) may contribute to pathogenetic disturbances of follicular architecture when functioning aberrantly. In this study we found that follicle to monolayer conversion is associated with an increase in cellular phosphotyrosine. This was particularly evident at nascent focal adhesions (cell-substrate adhesive junctions) and later at cell-cell junctions. Focal adhesion assembly was accompanied by reorganization of the actin cytoskeleton, with the appearance of prominent stress fibers. Genistein, a potent inhibitor of protein tyrosine kinases, inhibited the accumulation of phosphotyrosine, focal adhesion assembly, and follicle to monolayer conversion. We conclude that tyrosine phosphorylation exerts an important influence on thyroid epithelial organization in culture, at least partly mediated through regulation of focal adhesion assembly.

Actions of epidermal growth factor and its receptor in the thyroid

Since its discovery by Stanley Cohen (1962), epidermal growth factor (EGF) has been found to influence the growth and function of most mammalian cells. EGF is secreted, after cleavage of a large precursor molecule, as a 53-amino acid polypeptide that exerts its effects through the epidermal growth factor receptor (EGF-R), a single 170-kD transmembrane molecule exhibiting intrinsic tyrosine kinase activity of crucial importance to signal transduction (Hsuan et al 1989). Although generally mitogenic, EGF has a wide range of other effects, which vary considerably among organs, cell types, and species. [For a comprehensive update, see the review by Fisher and Lakshmanan (1990).] This article summarizes the present knowledge of EGF actions on thyroid follicular cells (thyrocytes), discusses the possible role of EGF in physiological and pathological conditions of the thyroid gland, and points out some issues that warrant further studies.

Stimulation of proliferation and inhibition of function of xenotransplanted human thyroid tissue by epidermal growth factor

A stimulation of thyroid epithelial cell proliferation by epidermal growth factor (EGF) has been repeatedly reported in different in vitro systems. Furthermore, a suppression of thyroid epithelial cell function by EGF has been described in vitro. In order to investigate the effects of EGF on the thyroid in vivo, human Graves' disease tissue was transplanted to 59 nu/nu mice. EGF was given once, and over a period of 7 days 7 times intermittently or continuously by osmotic mini pumps to mice. 3-H-thymidine histoautoradiography of transplants showed an increased 3-H-thymidine incorporation of thyroid epithelial cells and mesenchymal cells, following each form of EGF application. Thyroid epithelial cell nuclear volume, which has previously been shown to be a parameter for thyroid epithelial cell function showed a decrease following EGF application. There was a tendency to a more intensive proliferation and differentiation following intermittent EGF application compared to continuous stimulation. These results demonstrate that EGF does stimulate proliferation of thyroid epithelial as well as mesenchymal cells in vivo. The growth stimulating effect of EGF is linked with a concomitant decrease of thyroid function in vivo. The latter is most likely due to the dedifferentiating action of EGF previously shown in in vitro systems.

Dietary iodine affects epidermal growth factor levels in mouse thyroid and submaxillary glands

To determine whether dietary iodine intake affects the levels of immunoreactive epidermal growth factor (EGF) in vivo in two mouse tissues known to be thyroid hormone responsive, 24 adult BALB/c mice were randomized into groups of six animals and fed a) an iodine-deficient diet, b) normal laboratory chow (controls), c) an iodine-deficient diet with high physiological iodine supplementation (approximately 300 micrograms/day), and d) an iodine-deficient diet with pharmacological doses of iodine (approximately 3 mg/day). After 21 days on the various regimens, the mice were killed and the concentration of mouse (m) EGF in the thyroid and submaxillary glands (SMG) measured by radioimmunoassay. The mean (+/- SEM) SMG mEGF level (micrograms/mg wet weight) in the different groups were: a) 7.58 +/- 1.87, b) 12.46 +/- 4.7, c) 19.79 +/- 4.47, and d) 24.36 +/- 5.96. The thyroid mEGF concentrations (ng/mg wet weight) were: a) 3.65 +/- 0.75, b) 5.23 +/- 1.84, c) 8.07 +/- 1.18, and d) 6.43 +/- 0.95, respectively. Analysis of variance revealed that dietary iodine status had a significant effect on mEGF levels in both the SMG (p < 0.001) and the thyroid gland (p < 0.001). Compared to controls, tissue mEGF levels decreased by 30-40% in the mice fed an iodine-deficient diet, and increased by 60-150% following physiologic iodine replacement.

Co-expression of the genes encoding transforming growth factor-alpha and its receptor in papillary carcinomas of the thyroid

Transforming growth factor-alpha (TGF-alpha) is frequently coexpressed with its receptor, epidermal growth factor receptor (EGF-R), in several types of carcinoma and sarcoma. It is believed that this results in an autocrine stimulation of tumor growth in these tumors. We have found that TGF-alpha and EGF-R/c-erbB RNAs were co-expressed at significantly higher levels in papillary thyroid carcinomas and their lymph-node metastases than in non-neoplastic thyroid tissues. We also observed a low level of expression of RNA specific for insulin-like growth factor I in these tumors, which was highest in a lymph-node metastasis. Autocrine stimulation by TGF-alpha may thus be a common feature of papillary carcinomas of the thyroid. Since EGF is known to induce proliferation and dedifferentiation of normal thyroid cells in culture, TGF-alpha and its receptor may play an important role in thyroid carcinogenesis.

Thyroglobulin gene expression as a differentiation marker in primary cultures of calf thyroid cells

A system of calf thyroid follicular cells in primary cultures has been developed to investigate the control of thyroglobulin gene expression in normal cells in vitro. In low (0.1%) serum conditions, the cells remained quiescent and formed dense aggregates surrounded by slowly spreading cells. High expression of thyroid-specific differentiation markers such as thyroglobulin (Tg) mRNA accumulation and iodide transport required the continuous exposure of cells to thyrotropin (TSH) or other adenylate cyclase activators (cholera toxin and forskolin). In the absence of TSH, Tg mRNA decreased to low but still detectable levels. Addition of TSH, forskolin or cholera toxin restored high Tg gene expression. Hydrocortisone moderately stimulated basal Tg mRNA accumulation and strongly potentiated the effect of TSH. Growth promoters including serum (1-10%), epidermal growth factor (EGF), fibroblast growth factor (FGF) and 12-O-tetradecanoylphorbol 13-acetate (TPA) induced calf thyroid cells to develop as a monolayer and inhibited both basal and TSH-stimulated expression of specialized functions. Moreover, only a partial restoration of this expression was achieved after addition of TSH or forskolin to well spread-out cells that had proliferated in response to EGF or serum. The results show that in calf thyroid cells, iodide transport and Tg gene expression are regulated by TSH through cyclic AMP; hydrocortisone potentiates this effect on Tg gene expression, while all growth promoting factors inhibit the expression of these differentiated functions.

Expression of oncogenes in thyroid tumours: coexpression of c-erbB2/neu and c-erbB

The receptor-type oncogenes c-erbB2/neu and c-erbB have been found amplified and/or overexpressed in a number of tumours of epithelial origin. We have studied the expression of oncogenes in biopsies from human thyroid tumours. The c-erbB2/neu and c-erbB oncogenes showed two- to three-fold higher levels of RNA in papillary carcinomas and lymph node metastases as well as in one adenoma when compared to non-tumour tissue. The nuclear oncogenes c-myc and c-fos were found to be expressed at varying levels in both non-tumour and tumour tissue. RNA transcripts specific for the platelet-derived growth factor A and B chains and the N-ras oncogene were detected in one anaplastic carcinoma. Neither rearrangements nor amplifications of oncogenes were observed in the thyroid tumours. These data are particularly interesting in light of the recent findings that epidermal growth factor induces proliferation and dedifferentiation of normal thyroid epithelial cells in vitro. We suggest that the epidermal growth factor or other ligands for the c-erbB and c-erbB2/neu receptors may contribute to the development and/or maintenance of the malignant phenotype of papillary carcinomas of the thyroid.

Insulin stimulates cell growth of a new strain of differentiated rat thyroid cells

A new strain, named WRT cells, has been generated from primary cultures of rat thyroids. The primary culture was grown in Coon's modified Ham's F12 medium with 5% calf serum, insulin, hydrocortisone, transferrin, somatostatin, glycyl-L-histidyl-L-lysine and thyrotropin (TSH). On the basis of the following facts, the WRT cell strain, cloned from the primary culture, was considered 'normal': the cells are euploid, not carcinogenic, not able to grow in soft agar, and show contact inhibition. Their differentiated functions consist of the ability to synthesize thyroglobulin and to take up iodide, and they have a TSH-dependent adenylate cyclase system. TSH increases cellular adenosine 3',5'-cyclic monophosphate (cAMP) levels and [3H]thymidine incorporation in WRT cells from a concentration similar to that active on another clonal rat cell line (FRTL-5), even though the cell replication appears to be differently regulated in the two cell strains. In fact, the WRT cell doubling time is 42 h and they are also able to grow in the absence of TSH, though more slowly. In the same conditions, FRTL-5 cells have a population doubling time of 38 h, but they are not able to grow in the absence of TSH. When the effect of the other growth factors of the medium was studied, insulin appears to be a growth stimulus by itself, while it is only a facilitative step for TSH action in FRTL-5 cells. WRT cells, unlike FRTL-5 cells, can grow with a population doubling time of 80 h, when cultured for prolonged periods in a medium with a low serum concentration (0.5%), but containing insulin plus TSH. In conclusion, the WRT cell strain is a new and interesting experimental model for studying growth factors at the level of the thyroid, especially for their mechanism of action on the TSH receptor.