Chronic effect of TSH on human thyroid tissue in organ culture

The chronic effect of TSH on thyroidal cAMP concentrations and release of thyroid hormones was investigated using human thyroid tissue in organ culture. Normal human thyroid slices were placed in HAM's F-10 synthetic culture medium in Falcon organ tissue culture dishes, and incubated at 37 degrees in a humidified atmosphere of 5% CO2 in air. Medium was changed everyday and daily T3 or T4 release was determined using concentration of T3 or T4 in the medium. After incubation, slices were transferred to the medium containing 10 mM theophylline and incubated without TSH for an additional 30 min to determine thyroidal cAMP concentrations. Thyroidal cAMP concentrations in slices incubated with 10 mU/ml of TSH increased significantly at 2, 6, and 24 hr and even on the 6th day of incubation. Daily T3 release was significantly increased above control from the 3rd day and daily T4 release from the 4th day to the 11th day of incubation with 10 mU/ml of TSH. Histologically, almost all follicles were structurally maintained even on the 11th day of incubation. These results suggest that both thyroidal cAMP concentrations and release of thyroid hormones are stimulated chronically by TSH. This organ culture system is useful for investigating chronic effects of various materials on human thyroid tissue.     

Evidence for differential synthesis of thyroxine and tri-iodothyronine by cultured human thyroid cells following exposure to thyrotrophin or dibutyryl cyclic AMP.

Cultured human thyroid cells treated with thyrotrophin (TSH) or dibutyryl cyclic AMP release more tri-iodothyronine (T3) and thyroxine (T4) than unsupplemented cells. Column chromatography was used to investigate the secretion of newly-synthesised 125-I labelled T3 and T4 from cells cultured with 125-I and TSH or dibutyryl cyclic AMP. Radioimmunoassays were used to determine total T3 and T4 release from cells cultured with unlabelled iodide.Iodothyronines released after TSH addition contained more 125-I than those released after dibutyryl cyclic AMP. This increase in 125-I was primarily in “new” T4. Release of “new” T3, however, was increased more by dibutyryl cyclic AMP than by TSH. Dibutyryl cyclic AMP and TSH were comparable in their stimulation of total T3 and total T4 release.Interpretation of these observations suggests that TSH and dibutyryl cyclic AMP may differ in some aspects of their in vitro effects on cellular iodination and iodothyronine coupling systems.     

Alpha-adrenergic interaction with stimulators of cyclic AMP concentrations in canine thyroid slices.

Thyroid stimulating hormone (TSH) increased cyclic AMP levels approximately 10–20 fold in canine thyroid slices after 30 min incubation. Thereafter the cyclic AMP level declined reaching about 50% of the maximal by 90 min even in the presence of 10 mM theophylline. When phentolamine, an α-adrenergic blocker, was added with TSH to the incubation medium, the decline of cyclic AMP levels that followed the peak was markedly diminished. The maximal effect of phentolamine was observed at a concentration of 10^?6M. A similar decline of the cyclic AMP levels after the peak was observed when the tissues was stimulated by prostaglandin E₁ or cholera toxin and the decline was again prevented by phentolamine. Phentolamine alone had no significant effect on the basal cyclic AMP levels. Phenylephrine, an α-adrenergic agonist, diminished the rise of cyclic AMP levels induced by TSH.Norephinephrine, a physiologic adrenergic stimulator, caused a marked inhibition of the elevation of cyclic AMP levels induced by prostaglandin E₁ or cholera toxin as was the case by TSH (Life Sciences 21, 607, 1977). The norepinephrine effect was abolished by phentolamine, but not by propranolol, a β-adrenergic blocker.These results indicate that α-adrenergic actions may be involved in the counter-regulation of cyclic AMP levels in canine thyroid glands.     

Thyrotropin (TSH) binding activities in bovine thyroid tissue: possible role of adenosine 3',5'-monophosphate dependent phosphorylation of thyroid plasma membranes in TSH receptor degradation

The relationship between thyroid plasma membrane phosphorylation and thyrotropin (TSH) receptor degradation was investigated by using bovine thyroid tissues. By fractionation of thyroid cytosol (105,000 X g supernatant of thyroid homogenate) in a continuous sucrose density gradient centrifugation, three different TSH binding activities were separated. During the incubation of thyroid plasma membranes, TSH binding activities were spontaneously released in vitro. By fractionation of the fraction containing released TSH binding activities in the same sucrose density gradient centrifugation, three different TSH binding activities were isolated. These peaks of TSH binding activity corresponded to the peaks of TSH binding activity obtained in cytosol fraction. Adenosine 3',5'-monophosphate (cyclic AMP) enhanced the release of TSH binding activities from the plasma membranes in vitro. After fractionation on a sucrose density gradient centrifugation of the supernatant of the plasma membranes which were preincubated with cyclic AMP, three different peaks of TSH binding activity were identified. These peaks corresponded to the peaks obtained in spontaneously released TSH binding activity. In this case, however, the amount of small molecule TSH binding activities was predominant compared to that of large molecule TSH binding activity. During the incubation of the plasma membranes with [r-32P]-ATP and with cyclic AMP, phosphorylated soluble proteins were released. The profile of the phosphorylated soluble proteins in the sucrose density gradient centrifugation showed three different peaks which corresponded to the peaks of binding activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cyclic AMP release from perfused dog thyroid lobes as a sensitive indicator of TSH activation of the secretion process. Evidence for two types of thyroid secretion latency

It has been demonstrated in various types of thyroid tissue preparations that cyclic AMP (cAMP) released into the medium reflects the amount of cAMP in the cells. In the present study employing perfused dog thyroid lobes the dynamics of cAMP release were compared to those of thyroxine (T4) and triiodothyronine (T3) release. The experiments gave evidence that even the lowest concentrations of TSH which stimulate hormone release (in this study 1 microU/ml) also activate the cAMP system; the very high levels of cAMP obtained by stimulation with high concentrations of TSH (in this study 10,000 microU/ml) are not accompanied by corresponding high increases in hormone release. On the contrary the T4 and T3 release is lower than during stimulation with more moderate concentrations of TSH (100 microU/ml). Hence studies employing high concentrations of TSH and measurements of cAMP as indicator of activity of secretory processes should be interpreted very cautiously; the prolonged lag in thyroid hormone secretion observed after stimulation with low concentrations of TSH is accompanied by a corresponding lag in activation of the cAMP system. This pattern suggest that the duration of late secretory processes such as thyroglobulin pinocytosis and hydrolysis is independent of the degree of stimulation and not involved in the variations in secretion latency.     

In vitro study on release of thyroid hormone in solitary autonomously functioning thyroid nodules using cell culture method

In vitro release of thyroid hormone was investigated under basal and TSH-stimulated conditions in the solitary autonomously functioning thyroid nodules (AFTN). A small portion (0.5 g of wet weight) of the nodules and adjacent thyroid tissues removed surgically from five patients with solitary AFTN were prepared for the dispersed cell culture. In the experiment on non TSH-stimulated (basal) conditions, those culture media which were totally replaced on the 5th day after primary culture were utilized for the determination of thyroxine (T4) and triiodothyronine (T3) by radioimmunoassay. T4 and T3 levels in culture media of the functioning nodules were 1.15 +/- 0.33 microgram/dl (mean +/- SEM) and 2.72 +/- 0.68 ng/ml, contrasted with levels of 0.67 +/- 0.09 microgram/dl and 1.24 +/- 0.22 ng/ml in the paranodular tissues. The mean ratios of T3/T4 of the nodules and paranodular tissues were 0.25 +/- 0.02 and 0.19 +/- 0.02, respectively (p less than 0.05). Meanwhile, in another experiment under TSH stimulatory conditions employing 40 and 80 microU/ml of human TSH, there were no significant differences in T4 and T3 releases when the two groups were compared.     

Effect of thyroid-stimulating hormone and norepinephrine on cyclic AMP levels in human normal thyroids and human thyroid tumors

The effect of TSH (100mU/ml) and norepinephrine (100 muM) on the cyclic AMP levels was studied in 10 human normal tissues, 10 thyroid adenomas and 4 thyroid carcinomas (3 papillary and 1 follicular). Normal tissues responded to TSH with a marked elevation of the cyclic AMP level. Response patterns of 10 thyroid adenomas to TSH were variable; the patterns of 6 cases resembled those of normal tissues, 3 responded mildly, and one had no response to TSH. Thyroid carcinomas had a higher basal level of cyclic AMP than those of normal tissues, although they responded only slightly to TSH. Two among 4 thyroid carcinomas had no response to TSH. Norepinephrine stimulated the accumulation of cyclic AMP in 4 thyroid adenomas and 3 thyroid carcinomas, while it had little effect on normal tissues. Responses to norepinephrine was observed only in thyroid tumors, although they had low response to TSH. It is suggested from these results that tumor cells originating from thyroid follicular cells have a modified response to hormones due to neoplastic alterations.     

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.     

Effects of concanavalin A and neuraminidase on cyclic AMP levels and 14C-1-glucose oxidation in dog thyroid slices.

Treatment with concanavalin A at 100 micron/ml or higher concentrations significantly increased 14C-1-glucose oxidation in dog thyroid slices as reported in other tissues. This treatment exerted no effect on tissue cyclic AMP levels. Neuraminidase at the same concentrations also had similar effects on these parameters. Neither concanavalin A nor neuraminidase at the concentrations up to 100 microng/ml had the TSH effect on both tissue cyclic AMP and 14C-1-glucose oxidation. These results indicate that modification of carbohydrate moieties of glycoproteins on the cell surface may cause an increase in glucose metabolism without any critical effect on cyclic AMP system and in the process of TSH response.     

Forskolin stimulates adenylate cyclase and iodine metabolism in thyroid

Forskolin is a potent activator of the cyclic AMP-generating system in many tissues. In dog thyroid slices, the enhancement of cyclic AMP level was rapid, sustained in the presence of forskolin, but easily reversible after its withdrawal. Contrary to TSH, forskolin induced little apparent desensitization. Forskolin potentiated the effects of TSH, PGE1 and cholera toxin. However, the forskolin-induced cyclic AMP accumulation was still sensitive to inhibitors of dog thyroid adenylate cyclase such as iodide, norepinephrine and adenosine. As fluoride, but contrary to TSH and PGE1, forskolin stimulated adenylate cyclase in a medium where Mg2+ was replaced by Mn2+. This suggests that in thyroid, as in other tissues, forskolin acts beyond the receptor level but, as it potentiates hormone action and does not impair modulation by inhibitors, it may interact with the nucleotide-binding regulatory proteins. Forskolin mimicked the effect of TSH on iodide organification and secretion.     

Iodide induced suppression of thyrotropin-stimulated adenosine 3',5'-monophosphate production in cat thyroid slices.

Cat thyroid slices were studied to investigate their responsiveness to thyrotropin stimulation of cyclic AMP accumulation. Ovine and bovine thyrotropin, in the presence of 2.5 mM aminophylline, induced a dose-dependent increase in the cyclic AMP content of cat thyroid tissue. Half-maximal stimulation of cyclic AMP accumulation was obtained at a thyrotropin concentration of 1-2 mU/ml. The maximal effect of thyrotropin was observed at 10 mU/ml, and was associated with a mean 77 +/- 19-fold increase in thyroidal cyclic AMP. Preincubation of cat thyroid tissue for 2 h with 50 micron NaI resulted in an impairment in the subsequent ability of thyrotropin to enhance cyclic AMP accumulation, without altering the level of cyclic AMP in tissues not exposed to the hormone. Preincubation alone was without effect on thyrotropin stimulation of cyclic AMP, and the inhibitory effect of iodide was prevented by addition of 3 mM methimazole to the preincubation medium. In addition, the time course of thytrotropin stimulation of cyclic AMP accumulation in cat thyroid slices was not significantly altered by the preincubation with excess iodide. These studies provide additional evidence that excess iodide inhibits the adenylate cyclase-cyclic AMP system in thyroid tissue.     

Negative control of TSH action by iodide and acetylcholine: mechanism of action in intact thyroid cells.

Iodide, a substrate of thyroid metabolism, and acetylcholine depress cyclic AMP intracellular content and secretion in dog thyroid slices under TSH stimulation. A direct or indirect pseudocompetitive effect at the level of TSH receptor interaction has been rejected. Iodide and carbachol, both inhibited cyclic AMP accumulation in TSH stimulated dog thyroid slices but only the effect of carbachol was suppressed in the presence of isobutylmethylanthine. Ro 20-1724 did not relieve either inhibitory effect. Carbachol greatly enhanced cyclic AMP disposal in TSH prestimulated slices after the cut off of hormone action by a trypsin treatment. This effect was also suppressed by isobutylmethylxanthine but not by Ro 20-1724. No action of iodide could be evidenced on cyclic AMP disposal in similar slices, although a clear effect after the same time of iodide action was observed on cyclic AMP accumulation. Neither carbachol, nor iodide depresses ATP levels in these slices. The data suggest that carbachol exerts its action through an activation of cyclic AMP disappearance probably by an activation of cyclic AMP phosphodiesterase and that iodide, through an oxidized intermediate, experts its inhibitory effect at the level of cyclic AMP synthesis.     

Effects of calcium ionophore (A-23187) on glucose oxidation and iodide transport in dog thyroid slices.

A calcium ionophore (A-23187, 20 mug/ml) stimulted 14C-1-glucose oxidation in dog thyroid slices to an extent equivalent to that obtained by the optimal concentration of dibutyryl cyclic AMP (1mM). Furthermore, the ionophore augmented the stimulation by dibutyryl cyclic AMP much more than the simple additive effect. The ionophore also enhanced the effect of TSH, but to a lesser extent. Under conditions where organic binding was blocked, T/M ratio of radioiodine concentration was lowered in slices by the ionophore; the findings similar to those obtained with TSH and dibutyryl cyclic AMP. The ionophore exhibited a slightly depressive effect on the basal cyclic AMP level. The elevation by TSH of cyclic AMP levels was also slightly depressed by the ionophore, but statistically insignificant in most cases. These results indicate that calcium ion may play an important role in the TSH regulation of iodide transport and glucose metabolism in the thyroid, in some cases by augmenting the effects of cyclic AMP.     

Alteration of thyroidal responsiveness to TSH under the influence of circulating thyroid hormone: short feed-back regulatory effect.

In order to examine the hypothesis that the thyroidal responsiveness to TSH is under the influence of thyroid hormone, following the T3 injection to the mice, serum T3 concentrations and the response of thyroid tissue to a fixed dose of TSH in terms of intracellular colloid droplet formation was studied. The colloid droplets induced by TSH was significantly reduced when serum T3 was decreasing, while it was significantly increased when serum T3 was increasing. This results demonstrate for the first time the existence of short feed-back loop regulating intra-thyroidal function by circulating T3. To delineate the possible mechanism of action of T3, the thyroid gland of mouse whose serum T3 concentration was elevated by injecting 50 mug T3, was incubated with TSH in vitro. TSH-induced cyclic AMP generation was not inhibited at all but colloid droplet formation was significantly inhibited in the thyroid tissue of the animal whose serum T3 concentration was enormously high. Thus, it was demonstrated that the site at which T3 affects is beyond cylcic AMP generation but prior to endocytosis, being consistent with our previous results.     

Effects of thyrotropin and N6,O2′-dibutyryl cyclic 3′,5′-adenosine monophosphate on prostaglandin levels in thyroid

We have shown that TSH increases PG levels in isolated bovine thyroid cells. We now report that TSH also increases PG levels in rat and mouse thyroid, and that these effects may be mediated via cyclic AMP. PG and cyclic AMP levels in intact rat and mouse thyroid lobes were measured by radioimmunoassay. During 60-min incubations at 37°C, 25 mU/ml TSH effected a 75–83% increase in PGE₁ and PGF_2α ”equivalents“ in rat thyroid; parallel measurements of endogenous cyclic AMP in these intact thyroid lobes revealed that maximal TSH-induced increase in cyclic AMP also required 60-min incubations. In mouse thyroid, 5 mU/ml TSH increased PGE₁ and PGF_2α levels 38–82% above basal; this TSH effect was evident within 15 min of incubation, thus mimicking the time-course of TSH-induced increase in mouse thyroid cyclic AMP. Exogenous DBcAMP, 0.5 to 3 mM, effected a dose-related increase in mouse thyroid PG levels. The stimulatory effects of both TSH and DBcAMP on mouse thyroid PG levels were abolished by aspirin and indomethacin. These studies suggest that TSH-induced increase in endogenous PG levels in thyroid may be mediated by cyclic AMP.     

Thyroid cell responses to thyrotropin and 12-O-tetradecanoyl-phorbol-13-acetate: translocation of protein kinase C and phosphorylation of thyroid cell polypeptide substrates

Not all of the effects of thyroid-stimulating hormone (TSH) on the thyroid are mediated by activation of the adenylate cyclase-cyclic AMP system, indicating that other control systems must also exist. Although a calcium-phospholipid-dependent protein kinase (protein kinase C) and specific substrates had been identified in thyroid tissue, their responsiveness to TSH and other stimulators has not been determined. In thyroid cells which had been preloaded with [32P]orthophosphate, TSH and 12-O-tetradecanoyl-phorbol-13-acetate (TPA) increased the phosphorylation of a 33K polypeptide substrate within 5 min in a dose-dependent fashion. The effect was observed with 1 mU/ml TSH and 3 nM TPA and was maximal with 100 mU/ml TSH and 100 nM TPA. The biologically inactive analog of TPA, 4 alpha-phorbol, had no effect. Isobutylmethylxanthine (IBMX) decreased the phosphorylation of the 33K polypeptide and inhibited the effect of TSH and TPA, indicating that the phosphorylation is not mediated by cyclic AMP. TSH and IBMX, but not TPA, augmented phosphorylation of a 38K polypeptide, suggesting involvement of cyclic AMP. In contrast TPA, but not TSH, increased the phosphorylation of 58K and 28K polypeptides. TSH, but not TPA or 4 alpha-phorbol, elevated the cyclic AMP level of thyroid slices. Incubation of thyroid slices with TSH or TPA significantly decreased protein kinase C activity in the 100,000g cytosol fraction and increased it in an extract of plasma membranes. The effect was present within 5 min and was maximal by 30 min. The effect was observed with 100 mU/ml TSH or 1 nM TPA. The stimulation by TSH or TPA of protein kinase C and its translocation from the cytosol to the plasma membranes of thyroid tissue may provide another mechanism for control of thyroid cell metabolism.     

Regulation of cyclic AMP levels in canine thyroid slices by alpha-adrenergic action.

In an attempt to clarify the role of adrenergic receptors in metabolic responses, interaction of norepinephrine with TSH was studied in canine thyroid slices with regard to cyclic AMP levels. Norepinephrine caused a very rapid (within 1 min), but quite transient increase in cyclic AMP levels. The elevation of cyclic AMP levels induced by TSH was markedly inhibited by norepinephrine. Phentolamine, an α-adrenergic blocker, not only prevented the decline of cyclic AMP levels that followed the rise by norepinephrine, but also abolished the norepinephrine effect on the TSH-induced elevation of cyclic AMP levels. Propranolol, a β-adrenergic blocker, exhibited no such effects. These results indicate that the α-adrenergic receptors control cyclic AMP levels in the thyroid gland.     

Studies of the in vitro sensitivity of iodothyronine synthesis to methimazole in normal human thyroid cells

The comparative effects of methimazole (MMI) on resting and thyrotropin (TSH) — stimulated human thyroid cell cultures were investigated in terms of the release of iodoprotein and newly — synthesised iodothyronine hormones into the culture medium during a 48h period of incubation.Iodoprotein recovery was increased after TSH, but both basal and TSH — enhanced iodoprotein release were depressed by MMI. TSH increased the release of tri-iodothyronine (T3) and thyroxine (T4), and although the TSH — enhanced T3 and T4 levels were depressed after MMI, (i) the basal levels found in control cultures were not attained, and (ii) T3 was more susceptible than T4 to MMI suppression, at high TSH levels.These findings indicate a retention of the $\text{in vivo}$ thyroidal sensitivity to MMI, under basal conditions and moderate TSH stimulation $\text{in vitro}$. The system may therefore facilitate further investigation into the mode of MMI suppression of peroxidase systems involved in iodothyronine hormone synthesis within the intact human thyroid cell.     

Effects of cholera toxin on thyroid cyclic AMP-dependent protein kinase and ornithine decarboxylase activities.

Cholera toxin activated beef thyroid cyclic AMP-dependent protein kinase in a dose (0.2 to 8 microgram/ml)-related fashion. Thus, when beef thyroid slices were incubated with toxin (8 microgram/ml) for 90 minutes and then assayed for protein kinase, the activity ratio (i.e. -cyclic AMP/+cyclic AMP) increased from 0.32 +/- 0.02 to 0.77 +/- 0.06. The toxin (5 microgram/ml)-induced increase was abolished by inclusion of ganglioside GM1 in the incubation medium (I50, 0.7 microgram/ml), whereas, gangliosides GD1a and GT1 were without effect. In contrast, TSH-activated protein kinase was unaffected by ganglioside addition. Cholera toxin increased rat thyroid ornithine decarboxylase (ODC) activity in-vitro in a dose (0.1 to 10 microgram/ml)-related fashion [basal, 100 cf cholera toxin (10 microgram/ml), 1500 pmol 14CO2/g tissue/30 min]. The toxin (1 microgram/ml)- (but not TSH-) induced increase in ODC was abolished by inclusion of ganglioside Ga and GT1 were without effect. Cholera toxin stimulation of ODC was inhibited by indomethacin or iodide as are the stimulatory effects of TSH or dibutyryl cyclic AMP. These results demonstrate that although there are differences in the TSH and cholera toxin responses with respect to receptor (ganglioside) interaction, they nevertheless elicit similar intracellular responses in thyroid.     

Characterization of regulation of thyrotropin (TSH) receptor function in thyroid plasma membrane: interaction between TSH receptor function and activation of adenosine 3',5'-monophosphate-dependent protein kinase

The changes in the characteristics of thyrotropin (TSH) binding to thyroid plasma membranes during the activation of cyclic AMP-dependent protein kinase in the membranes were studied. Preincubation of thyroid plasma membranes with TSH or cyclic AMP reduced the maximal binding capacity but increased the association rate for TSH binding. In double reciprocal analysis, a marked reduction of the total number of binding sites and association constant was observed in the membranes treated with cyclic AMP. These reductions were also observed in the membranes preincubated with buffer alone. The degree of these reductions, however, was greater in the membranes pretreated with cyclic AMP. During incubation of the membranes with buffer alone, cyclic AMP formation (activation of adenylate cyclase) was observed though the degree of the formation was lower than that induced by TSH. The results suggested that not only TSH receptor release from thyroid plasma membrane but also the modification of TSH binding activity in the membrane is produced by cyclic AMP-dependent protein kinase.