Effect of thyrotropin on iodide efflux in FRTL-5 cells mediated by Ca2+

A functioning rat thyroid cell line (FRTL-5) responds acutely to the addition of TSH, norepinephrine, and the Ca2+ ionophore A23187 by a depression in iodide (I-) uptake levels. The decrease in I- content measured at the steady state depends on the presence of external Ca2+ and can be accounted for by an effect on stimulated I- efflux. As contrasted to the prolonged time (hours and days) involved in the stimulatory effect of TSH on I- uptake, the acute response to TSH is 1) seen within 5 min and maintained for about 20 min, 2) maximum, at a 1 X 10(-7)M concentration of TSH compared with the concentration of 1 X 10(-9)M necessary for the stimulatory effect, 3) independent of whether the cells are growing in the presence or absence of TSH, and 4) not mimicked by the addition of (Bu)2cAMP. The results suggest that TSH and adrenergic stimulation lead to increased membrane permeability to I- which is mediated by an elevation in the intracellular Ca2+ concentration.     

Hydrogen peroxide inhibits iodide influx and enhances iodide efflux in cultured FRTL-5 rat thyroid cells

This study describes the effects of hydrogen peroxide on the two iodide transport systems, I influx and I efflux, in the cultured FRTL-5 rat thyroid cells. I influx was measured by the amount of I taken up by the cells during incubation with Na125I and NaI for 7 min, and I efflux was measured by calculating the rate of 125I release from the 125I-loaded cells in the presence and absence of 5 mmol/l H2O2. Exposure to greater than 100 mumol/l H2O2 for 40 min caused a significant inhibition of I influx; the inhibition was reversible and non-competitive with iodide. Thyroid Na+K+ ATPase activity, a major mechanism to drive I influx, decreased by 40% after the cells were exposed to 5 mmol/l H2O2 for 10 min. H2O2 enhanced I efflux only when Ca2+ was present in the medium. The mechanism of an enhanced I efflux by H2O2 appears to be mediated through the elevation of free cytosolic Ca2+ concentration. Our data indicate that H2O2 can affect I transport by inhibiting I influx and enhancing I efflux.     

Iodination of newly synthesized thyroglobulin by FRTL-5 cells is selective and thyrotropin dependent

This study shows that the Fisher rat thyroidal cell line (FRTL-5) can iodinate newly synthesized thyroglobulin. Iodinated thyroglobulin was found intra- and extracellularly. Both the synthesis of thyroglobulin and its subsequent iodination were found to be thyrotropin (TSH) dependent, with optimal activity at 10-100 microU TSH/ml. Thyroglobulin was the only protein in the culture medium, that was iodinated with high specificity and in a TSH-dependent fashion. Albumin, which was abundantly present in the culture medium, was only weakly iodinated. Various proteins, including thyroglobulin, were found to be iodinated intracellularly. Of these iodoproteins only thyroglobulin appeared in the medium suggesting selective secretion of iodinated thyroglobulin. It was shown that the other intracellular iodoproteins were no thyroglobulin breakdown products. Their function is as yet unknown.     

Iodine suppression of iodide uptake in FRTL-5 thyroid cells

Exposure of FRTL-5 cells to iodide (I-) in excess of 3 microM suppresses the concentrative uptake of I-. The depression of I- uptake measured at the steady state is due to decrease in the rate of I- influx and not to an effect on I- efflux. Exposure to NaI is associated with decreased T4 secretion and also depressed Na+-dependent amino acid accumulation. The depression in I- and amino acid transports increases proportionately with the duration of exposure and concentration of I- used but is not associated with alterations in FRTL-5 cell cAMP levels. The I- suppression effect is blocked, however, when methimazole is present during the incubation with NaI. In agreement with studies in vivo, I- suppression in FRTL-5 cells appears to depend on an intermediate in the organification process and to be independent of a TSH-induced cAMP-mediated action.     

Nitric oxide/cGMP signaling inhibits TSH-stimulated iodide uptake and expression of thyroid peroxidase and thyroglobulin mRNA in FRTL-5 thyroid cells.

OBJECTIVE: Nitric oxide (NO) induces morphological and functional alterations in primary cultured thyroid cells. The aim of this paper was to analyze the direct influence of a long-term exposition to NO on parameters of thyroid hormone biosynthesis in FRTL-5 cells. DESIGN: Cells were treated with the NO donor sodium nitroprusside (SNP) for 24-72 h. MAIN OUTCOME: SNP (50-500 micromol/L) reduced iodide uptake in a concentration-dependent manner. The inhibition of iodide uptake increased progressively with time and matched nitrite accumulation. SNP inhibited thyroperoxidase (TPO) and thyroglobulin (TG) mRNA expression in a concentration-dependent manner. SNP enhanced 3',5'-cyclic guanosine monophosphate (cGMP) production. 3',5'-cyclic adenosine phosphate (cAMP) generation was reduced by a high SNP concentration after 48 h. 8-Bromoguanosine 3',5'-cyclic monophosphate (8-Br-cGMP), a cGMP analog, inhibited iodide uptake as well as TPO and TG mRNA expression. The cGMP-dependent protein kinase (cGK) inhibitor KT-5823 reversed SNP or 8-Br-cGMP-inhibited iodide uptake. Thyroid-stimulating hormone pretreatment for 24-48 h prevented SNP-reduced iodide uptake although nitrite levels remained unaffected. CONCLUSION: These findings favor a long-term inhibitory role of the NO/cGMP pathway on parameters of thyroid hormone biosynthesis. A novel property of NO to inhibit TPO and TG mRNA expression is supported. The NO action on iodide uptake could involve cGK mediation. The long-term inhibition of steps of thyroid hormonogenesis by NO could be of interest in thyroid pathophysiology.     

Effects of thyrotropin on thyroglobulin exocytosis and iodination in the rat thyroid gland.

Rats, pretreated with thyroxine for 2 days, were given one or two iv injections of 500 mU of TSH; in some groups the second TSH dose was replaced by 0.75 micronmol isoproternol. The effects of the thyroid stimulators on the following parameters were studied: the number of exocytotic vesicles in the follicle cells; the incorporation of 125I into thyroid proteins, measured over periods of 5 min; and the thyroidal cAMP contents. At 2 h after TSH administration, a second dose of TSH failed to stimulate iodination while at 8 h the iodination response was "normal". Two hours after TSH the follicle cells contained practically no exocytotic vesicles but at 8 h they had a full supply of vesicles, and this was emptied by the second TSH injection. THE CAMP content was less increased by the second TSH injection than by the first one, but the stimulatory effect of the second TSH dose on cAMP was the same at 2 h and at 8 h; this indicates that the lack of iodination response at 2 h was not simply due to blocking of TSH receptors. Isoproternol, which acts on other receptors than does TSH, cause a similar cAMP increase incontrols and at 2 h and 8 h after TSH, but stimulated iodination only in controls and at 8 h after TSH; this supported the conclusion that the lack of iodination response to a second TSH dose at 2 h was not due to impairment of the adenylate cyclase-cAMP system. These observations taken together strongly indicate that a rapid iodination response to TSH depends on stimulated exocytosis which, in turn, requires a pool of exocytotic vesicles in the follicle cells. Such a coupling between exocytosis and iodination seems appropriate since by exocytosis uniodinated thyroglobulin and membrane, showing peroxidase activity histochemically, are delivered to the site of iodination, the apical cell surface.     

Synergistic effect of thyroid hormone and thyrotropin on iodothyronine 5'-deiodinase in FRTL-5 rat thyroid cells

The effects of T3 and T4 on the iodothyronine 5'-deiodinase (5'-D) activity in FRTL-5 rat thyroid cells were investigated. T3 and T4 stimulated the 5'-D activity in a dose-dependent manner. Kinetic studies showed that the stimulation of the 5'-D by T3 was associated with an increase in maximum velocity (Vmax) in [11.9 +/- 0.2 (mean +/- SE) and 25.4 +/- 0.9 pmol I-released/mg protein.min, respectively, in control and cultured with 10(-9) M T3 for four days] but without a change in apparent Michaelis-Menten constant (Km) (94.8 +/- 5.3 nM and 105.4 +/- 12.1 nM, respectively). Furthermore, cycloheximide (5 microM) completely abolished the stimulatory effect of T3 on the 5'-D activity. T3 and T4 also enhanced the 5'-D activity stimulated by TSH in a dose-dependent manner. Kinetic studies showed that the stimulatory effect of T3 on the 5'-D stimulated by TSH was again associated with an increase in Vmax (86.0 +/- 4.0 and 166.5 +/- 1.9 pmol I- released/mg protein.min, respectively, cultured with 0.3 U/liter TSH and cultured with TSH plus 10(-9) M T3 for four days) without a change in apparent Km (114.0 +/- 7.4 nM and 111.6 +/- 12.5 nM, respectively). Cycloheximide (5 microM) completely abolished the stimulatory effect of TSH plus T3 on the 5'-D activity. There were no significant differences observed between cells cultured with TSH and with TSH plus T3 in either the intra- or extracellular cAMP contents. Furthermore, T3 enhanced the 5'-D activity stimulated by (Bu)2 cAMP. These results strongly suggest that T3 or T4 was synergistic with TSH in stimulating the 5'-D activity in FRTL-5 cells, and that cAMP production would be an important component of the synergism.     

Insulin-like growth factor-I potentiates thyrotropin stimulation of adenylyl cyclase in FRTL-5 cells

We reported that TSH and insulin-like growth factor-I (IGF-I), which were known to synergistically stimulate DNA synthesis, synergize to elevate the 1,2-diacylglycerol content of FRTL-5 thyroid cells. We presented evidence that cAMP is the proximal mediator of these actions of TSH. To further define the mechanism of this interaction, we investigated the effects of IGF-I on TSH stimulation of adenylyl cyclase. Long and short term effects of IGF-I or high doses of insulin were studied in FRTL-5 cells that were maintained in serum-, hormone-, and growth factor-free medium for 4-7 days (basal cells). When cells were incubated with high doses of insulin for 7 days and acutely stimulated, a 10-fold increase in sensitivity and a 2-fold increase in maximal responsiveness of cAMP accumulation to TSH were observed. To study shorter term effects, cells were preincubated with insulin for 3 h and then exposed to TSH, cholera toxin, or forskolin. Incubation with high doses of insulin for 3 h caused 30-300% increases in cAMP accumulation at high doses of TSH (greater than or equal to 1 mU/ml), cholera toxin (greater than 0.1 microM), and forskolin, but did not affect the EC50 for TSH. Dose-response studies were consistent with insulin acting via receptors for IGF-I, and IGF-I caused a similar effect. There was a 45% increase in adenylyl cyclase activity stimulated by TSH in membranes isolated from cells incubated with high doses of insulin for 3 h. Pretreatment of FRTL-5 cells with pertussis toxin, which ADP-ribosylates the inhibitory G-protein Gi, or adenosine, which we show inhibits cAMP accumulation by interacting with Gi, did not affect insulin/IGF-I enhancement of cAMP accumulation. We suggest that synergism of actions of TSH and IGF-I may in part be due to IGF-I enhancement of TSH stimulation of adenylyl cyclase.     

Norepinephrine and thyrotropin effects on the thyroid in vitro: simultaneous stimulation of iodide organification and antagonism of thyroxine release

Norepinephrine (NE), which has previously been shown to inhibit TSH-induced T4 release by mouse thyroids in vitro, was found to stimulate iodide organification. The concentration of NE (6 X 10(-7) M) necessary to stimulate organification of iodide was 10 times less than the concentration (6 X 10(-6) M) required for inhibition of TSH-induced T4 release. Both actions of NE were exerted through an alpha-adrenergic receptor, since they were inhibited by phentolamine but not by l-propranolol. One milliunit of TSH maximally stimulated T4 release only, but larger amounts (100 mU) also stimulated organification. TSH stimulation of T4 release and organification was not affected by adrenergic antagonists and therefore was not mediated by adrenergic receptors. N6, O2-Dibutyryl cAMP and isobutylmethylxanthine, like TSH, stimulated T4 release. Their actions were inhibited by NE. However, both compounds, unlike TSH, failed to enhance organification in mouse thyroids. The effects of TSH and NE on the cAMP content of incubated mouse thyroids were also studied. TSH induced a prolonged increase in thyroidal cAMP during the 90-min incubation; this increase was unaffected by alpha- or beta-adrenergic antagonists. In contrast, NE (6 X 10(-5) M) produced a transient but significant increase in cAMP only within the first 5 min. Unlike the action of NE on organification, this short term stimulatory effect on cAMP production was mediated by a beta-adrenergic receptor, since it was blocked by l-propranolol but not by phentolamine. The following conclusions were reached: 1) stimulation of iodide organification and thyroid hormone release involves different sensitivity thresholds for TSH and NE; 2) TSH stimulation of iodide organification, hormone release, and cAMP formation is not exerted through adrenergic receptors; 3) NE stimulates organification and inhibits TSH-stimulated T4 release through alpha-adrenergic receptors, but stimulates cAMP production through beta-receptors; and 4) cAMP may not be the mediator of all TSH actions on the thyroid.     

Graves' IgG stimulation of iodide uptake in FRTL-5 rat thyroid cells: a clinical assay complementing FRTL-5 assays measuring adenylate cyclase and growth-stimulating antibodies in autoimmune thyroid disease

With optimal conditions and cells maintained in the absence of thyrotropin (TSH) for 7-10 days, IgG preparations from approximately 90% of patients with active Graves' disease can exhibit statistically significant stimulation of cAMP levels in rat FRTL-5 thyroid cells as compared to normal controls. FRTL-5 cells maintained in the absence of TSH for 7-10 days lose their ability to take up iodide. Iodide uptake returns upon readdition of TSH over a 60-hour period via a cAMP-mediated process; thus TSH can be replaced by dibutyryl cAMP or other agents which increase cAMP levels, for example, thyroid-stimulating autoantibodies (TSAbs) from Graves' sera. TSAb stimulation of iodide uptake requires the continued presence of TSAb over at least the first 24 hours of a 48-hour reversal period; TSH, in contrast, can be withdrawn after 5 hours and will still achieve maximal effects at 36-48 hours. Iodide uptake, measured as a 30-minute pulse at 48 hours, appears, however, to be faster with TSAb than TSH. With optimized conditions (cells depleted of TSH greater than 7-10 days; 3-isobytyl-1-methyl xanthine, 0.005 mM; TSAb addition for the entire 48-hour assay period; and a 30-minute pulse of 10 microM 125I-sodium iodide at 37 C), TSAb stimulation is concentration-dependent with a half-maximal activity at approximately 10-fold lower concentrations than in the cAMP stimulation assay. In a series of 24 patients with Graves' disease, IgGs with positive values in the cAMP assay were positive in the iodide uptake assay.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pendrin, the protein encoded by the Pendred syndrome gene (PDS), is an apical porter of iodide in the thyroid and is regulated by thyroglobulin in FRTL-5 cells

Pendred syndrome is an autosomal recessive disorder characterized by congenital deafness and thyroid goiter. The thyroid disease typically develops around puberty and is associated with a mild organification defect, characterized by an inappropriate discharge of iodide upon perchlorate stimulation (a positive perchlorate discharge test). The gene (PDS) mutated in Pendred syndrome is expressed in thyroid and encodes a 780-amino acid protein (pendrin) that has recently been shown to function as an iodide/chloride transporter. We sought to establish the location of pendrin in the thyroid and to examine the regulatory network controlling its synthesis. Using peptide-specific antibodies for immunolocalization studies, pendrin was detected in a limited subset of cells within the thyroid follicles, exclusively at the apical membrane of the follicular epithelium. Interestingly, significantly greater amounts of pendrin were encountered in thyroid tissue from patients with Graves' disease. Using a cultured rat thyroid cell line (FRTL-5), PDS expression was found to be significantly induced by low concentrations of thyroglobulin (TG), but not by TSH, sodium iodide, or insulin. This is different from the established effect of TG, more typically a potent suppressor of thyroid-specific gene expression. Together, these results suggest that pendrin is an apical porter of iodide in the thyroid and that the expression and function of both the apical and basal iodide porters are coordinately regulated by follicular TG.     

Muscarinic regulation of phospholipase A2 and iodide fluxes in FRTL-5 thyroid cells.

FRTL-5 thyroid cells express a muscarinic receptor which inhibits the phospholipase C activity in a pirenzepine-insensitive manner. We here report that the cholinergic agonist carbachol decreases in these cells the steady-state iodide content, an effect correlated with the iodination of thyroglobulin and with thyroid hormone formation. Several signal pathways may be involved in this phenomenon since carbachol in addition to inhibiting phospholipase C, increased the arachidonic acid release and modified the adenylyl cyclase activity. In FRTL-5 cells, arachidonic acid is released via the direct stimulation of phospholipase A2 by a pirenzepine-sensitive muscarinic receptor coupled to a GTP binding protein sensitive to pertussis toxin. Regarding adenylyl cyclase, carbachol potentiated the thyrotropin-induced stimulation of the enzyme, whereas it did not affect the basal levels of cAMP. In vitro binding studies revealed the presence of two muscarinic binding sites. To summarize, the analysis of signal pathways and of in vitro binding sites indicates a complex muscarinic regulation of thyroid function, which includes the modulation of iodide fluxes.     

Regulation of sodium iodide symporter gene expression in FRTL-5 rat thyroid cells.

The sodium iodide symporter (NIS), first identified in FRTL-5 cells, plays a critical role in iodide transport in the thyroid gland and in the production of the iodine-containing thyroid hormones. The aim of our study was to examine the regulation of NIS RNA steady-state levels and protein expression as well as functional activity in FRTL-5 cells. FRTL-5 cells cycling in media containing thyrotropin (TSH) were incubated for 48 hours with dexamethasone (10(-8)-10(-5) M), triiodothyronine (T3; 10(-9)-10(-6) M), methimazole (100 microM), propylthiouracil (PTU; 100 microM), perchlorate (10 microM) and potassium iodide (40 microM). In other experiments, cells were treated for 48 hours with various cytokines including interleukin-6 (IL-6) (100 U/mL), interferon-gamma (IFN-gamma) (100 U/mL), tumor necrosis factor-alpha (TNF-alpha) (10 ng/ml), IL-1alpha (100 U/mL), and IL-1beta (100 U/mL). Northern blot analysis using a 32P-labeled rat NIS-specific cDNA probe (nucleotides 1397-1937) revealed NIS mRNA as a single species of approximately 3 kb. When normalized for beta-actin mRNA signal intensities, NIS RNA steady-state levels in viable FRTL-5 cells were suppressed by approximately 80% after incubation with dexamethasone and T3 in a concentration-dependent manner. Iodide accumulation was decreased by up to 40% after incubation with dexamethasone and T3, respectively, in a concentration-dependent manner. Using a rabbit polyclonal rNIS-specific antibody, Western blot analysis of FRTL-5 cell membranes revealed a 60% and 70% suppression of NIS protein expression after treatment with T3 (0.1 microM) and dexamethasone (1 microM), respectively. In additon, NIS RNA steady-state levels were decreased by approximately 50% after treatment of monolayers with methimazole, PTU, and potassium iodide, respectively. Incubation with methimazole and PTU resulted in a 20% and 25% decrease of iodide accumulation, respectively, whereas potassium iodide suppressed iodide accumulation by approximately 50%. Treatment of FRTL-5 cells with IL-6 and IL-1beta resulted in a 30% decrease of NIS RNA steady-state levels. IL-6 did not alter NIS functional activity, but IL-1beta suppressed iodide accumulation by approximately 25%. IFN-gamma and perchlorate failed to alter NIS RNA steady-state levels. In contrast to IFN-gamma that had no effect on iodide accumulation, perchlorate almost completely suppressed iodide accumulation. TNF-alpha and IL-1alpha failed to alter NIS RNA steady-state levels in higher passage numbers of FRTL-5 cells, whereas treatment with TNF-alpha and IL-1alpha of early passages of FRTL-5 cells (<20 cell passages) resulted in a 70% and 40% decrease of NIS RNA steady-state levels, respectively, and in a 20% suppression of NIS functional activity. In conclusion, our data suggest that various agents known to affect iodide transport are capable of differentially altering NIS gene expression and function in cultured thyroid cells. Suppression of NIS gene expression and function by certain cytokines may be responsible, at least in part, for the impaired radioiodine uptake by thyroid tissue in certain forms of thyroiditis.     

The inhibitory effect of iodide on growth of rat thyroid (FRTL-5) cells

The effect of iodide on growth of rat thyroid cells (FRTL-5) was studied. TSH-stimulated cell growth was inhibited by iodide in a concentration-dependent manner, and an effect of iodide was detected at 10(-6) mol/l. KClO4 or 1-methylimidazole-2-thiol blocked the effect of iodide, suggesting that iodide uptake and its organification are required to produce the inhibitory effect of iodide on cell growth. Iodide not only decreased TSH-stimulated cAMP production in FRTL-5 cells but also cell growth induced by cAMP. These observations suggest that iodide inhibits TSH-stimulated growth of the cells by attenuating cAMP production and also by acting on the step(s) distal to cAMP generation. The inhibitory effect of iodide was also seen in growth stimulated by insulin, insulin-like growth factor-I or 12-O-tetradecanoyl phorbol 13-acetate, suggesting multiple sites of action of iodide in the process of growth of FRTL-5 cells.     

Organic iodine inhibits deoxyribonucleic acid synthesis and growth in FRTL-5 thyroid cells

FRTL-5 thyroid epithelial cells in culture were used to study the possible inhibitory effects of iodine on thyroid growth. NaI exerted a dose-dependent, thyroid epithelial cell-specific inhibitory effect on [methyl-3H]thymidine incorporation into DNA, reduced the DNA content in the cell layer, and limited the increase in cell number mediated by TSH. The inhibitory effects of sodium iodide applied to growth stimulated by TSH-, cAMP-, and non-cAMP-dependent mechanisms and were prevented by 1-methylimidazole-2-thiol (methimazole) and 2-ethylthioisonicotinamide (ethionamide). The latter findings indicate that the inhibitory effects of NaI are mediated by some iodine-containing organic compound. The inhibitory effects of organic iodine on growth subsided 24-48 h after removal of excess NaI from the culture medium. In contrast, NaI had no effect on normal rat kidney fibroblast or thyroid fibroblast [methyl-3H]thymidine incorporation stimulated by epidermal growth factor or serum. These data demonstrate a specific inhibitory effect of organic iodine on thyroid epithelial cell growth.