Hormonal regulation of thyrotropin alpha and beta subunit mRNAs

We have examined the effects of 3,5 3'-triiodo-L-thyronine (T3), dexamethasone, bromocriptine, thyrotropin releasing hormone (TRH) and estrogen on the levels of pituitary alpha and TSH-beta protein and mRNA levels in hypothyroid mice. After 3 days of treatment with T3 (0.5 micrograms/100 g body weight) serum TSH, alpha and TSH-beta levels were 77%, 79% and 44% of control, respectively. Pituitary alpha and TSH-beta mRNA content was estimated by dot blot hybridization of total RNA with 32P-labelled alpha and TSH-beta plasmid probes. There was no change in alpha mRNA after 3 days of T3 treatment but TSH-beta mRNA had decreased to 60% of control. With T3 at 2 micrograms/100 g body weight for 3 days, TSH protein was 27% of control and TSH-beta was undetectable, but there was no change in alpha. TSH-beta mRNA was decreased to 40% of control at 1 day and was barely detectable at 3 days, whereas alpha mRNA was 70% of control at 1 day and 42% at 3 days. Dexamethasone and bromocriptine caused no consistent change in pituitary levels of alpha and TSH-beta mRNA. Treatment with TRH caused small increases in serum TSH and in both alpha and TSH-beta mRNA levels. Estrogen treatment increased serum TSH and subunit levels and TSH-beta mRNA, but not alpha. We conclude that thyroid hormones decrease alpha and beta subunit mRNA levels discordantly in both the hypothyroid pituitary and in thyrotropic tumors and that the suppressive effect of thyroid hormone is the major regulator of TSH.     

Regulation by thyroxine of the mRNA encoding the alpha subunit of mouse thyrotropin

Thyrotropin (TSH), a glycoprotein hormone of the pituitary consisting of two subunits (alpha and beta), regulates thyroxine (T4) production by the thyroid gland. T4, in turn, regulates TSH biosynthesis and release. We have studied the regulation of the messenger RNA encoding the alpha subunit of TSH by T4 in pituitaries and in a transplantable thyrotropic tumor in mice. Hypothyroid male LAF1 mice bearing the TtT 97 thyrotropic tumor were injected daily with T4 for either 0, 1, 5, 12, or 33 days. Levels of TSH and its unassociated alpha (free alpha) and TSH-beta subunits in the plasma of these animals fell to less than 5% of control values after 33 days. Concentrations of TSH and TSH-beta in both tumor and pituitary also fell to low levels (less than 2% of control), while intracellular concentrations of free alpha subunit remained unchanged. Cellular levels of the mRNA encoding the precursor of the alpha subunit or pre-alpha (alpha mRNA) were measured by cell-free translation followed by electrophoretic analysis of immunoprecipitates of pre-alpha subunit and by nucleic acid hybridization to a radiolabeled cDNA probe specific for the alpha mRNA. In the pituitary, translatable and hybridizable alpha mRNA was decreased slightly after 1 day of T4 and decreased 40-50% after 5 and 12 days. In thyrotropic tumors, both translatable and total alpha mRNA showed a 60% decrease by 1 day and a maximum 85% decrease after 5, 12, and 33 days of T4. Therefore, T4 acts rapidly in vivo to decrease steady state alpha mRNA levels in the thyrotrope, and this decrease is maintained for the duration of treatment with thyroid hormone. This regulatory process is reflected in the sharp decreases in levels of TSH and free alpha subunit in plasma and in lower concentrations of the intact TSH in tissue. In contrast, the maintenance of high tissue concentrations of free alpha subunit after T4 treatment may be a reflection of alterations in a post-translational process specific for the free alpha subunit, as opposed to that of the intact TSH.     

Testosterone increases TSH-beta mRNA, and modulates alpha-subunit mRNA differentially in mouse thyrotropic tumor and castrate rat pituitary.

TSH, LH and FSH, the three pituitary glycoprotein hormones, are each composed of a common alpha-subunit and a hormone specific beta-subunit. Testosterone is known to regulate all three intact hormones differently in the rodent. However, there is only one gene encoding the common alpha-subunit. In order to elucidate the effects of testosterone on TSH subunit synthesis and its regulation of the common alpha-subunit, two in vivo models were studied: castrate rat pituitary was used as a gonadotropin-enriched tissue; and mouse thyrotropic tumor was used as a thyrotropin-enriched tissue. Male castrate rats were treated with testosterone propionate, 500 micrograms/100 g BW, sc, for 11 days. Testosterone increased plasma TSH to 131% of control values (P less than 0.02), while plasma LH fell to undetectable levels, and plasma alpha-subunit fell to 14% of control values (P less than 0.001). Testosterone increased TSH-beta mRNA to 237% of control values (P less than 0.02), while alpha-subunit mRNA fell to 20% of control values (P less than 0.001). Hypothyroid mice bearing thyrotropic tumors were treated with testosterone propionate, 150 micrograms/100 g BW, sc, for 11 days. In this model plasma TSH-beta and alpha-subunit concentrations are 1000-fold higher than in non-tumor bearing animals, and the contribution of pituitary gonadotropes to plasma subunit concentrations is negligible. "Total" TSH-beta and alpha-subunit concentrations were estimated as one-half of intact TSH plus the respective free subunit concentration.(ABSTRACT TRUNCATED AT 250 WORDS)     

RXR receptor agonist suppression of thyroid function: central effects in the absence of thyroid hormone receptor

High-affinity agonists for the retinoic acid X receptors (RXR) have pleotropic effects when administered to humans. These include induction of hypertriglyceridemia and hypothyroidism. We determined the effect of a novel high-affinity RXR agonist with potent antihyperglycemic effects on thyroid function of female Zucker diabetic rats and nondiabetic littermates and in db/db mice. In both nondiabetic and ZFF rats, AGN194204 causes a 70-80% decrease in thyrotropin (TSH), 3,3',5-triiodothyronine, and thyroxine (T(4)) concentrations. In the db/db mouse, AGN194204 causes a time-dependent decrease in thyroid hormone levels with the fall in TSH that was significant after 1 day of treatment preceding the fall in T(4) levels that was significant at 3 days of treatment. Treatment with AGN194204 caused an initial increase in hepatic 5'-deiodinase mRNA levels which then fell to undetectable levels by 3 days of treatment and continued to be low at 7 days of treatment. After treatment for 5 days with AGN194204, both wild-type and thyroid hormone receptor beta (TR beta(-/-))-deficient mice demonstrated a nearly 50% decrease in serum TSH and T(4) concentrations. The results suggest that a high-affinity RXR agonist with antihyperglycemic activity can cause central hypothyroidism independently of TR beta, the main mediator of hormone-induced TSH suppression.     

Serum free thyrotropin subunit in congenital isolated thyrotropin deficiency

In two patients with congenital isolated thyrotropin (TSH) deficiency, serum TSH determined by a sensitive immunoradiometric assay (IRMA) was consistently undetectable. The basal levels of serum free TSH-alpha subunit (TSH-alpha) determined by a specific radioimmunoassay (RIA) were elevated in the hypothyroid state, and decreased to the undectable level during displacement therapy with thyroid hormone. The serum free TSH-alpha significantly increased following intravenous administration of thyrotropin releasing hormone (TRH). Serum free TSH-beta subunit (TSH-beta) was undectable. These findings suggest that TSH deficiency in this disease is not due to absence of thyrotroph in the pituitary gland or deficiency of TSH-alpha, but to abnormalities of the TSH-beta gene.     

Thyroid hormone regulation of messenger ribonucleic acid encoding thyrotropin (TSH)-releasing hormone is independent of the pituitary gland and TSH

Cellular levels of mRNA encoding pro TRH in the rostral paraventricular nucleus are reduced by thyroid hormones. To determine whether this regulatory effect of thyroid hormones requires a functional pituitary gland or, specifically, TSH, we examined the effect of T3 on proTRH mRNA in hypophysectomized, thyro-parathyroidectomized male rats with or without bovine TSH replacement. Hypophysectomy plus thyro-parathyroidectomy reduced serum T4 and TSH to undetectable levels in all animals and elevated TRH mRNA in the paraventricular nucleus over that of sham-operated animals. Eleven consecutive daily injections of T3 significantly reduced TRH mRNA levels in both sham controls and thyro-parathyroidectomized rats. However, 11 daily injections of bovine TSH (1 U/day) failed to alter the effect of T3 on TRH mRNA levels. These results demonstrate that the regulatory influence of thyroid hormones on the biosynthesis of TRH within the thyrotropic center of the brain is independent of the pituitary gland and of TSH.     

Dominant inhibition of thyroid hormone action selectively in the pituitary of thyroid hormone receptor-beta null mice abolishes the regulation of thyrotropin by thyroid hormone

Thyroid hormones, T4 and T3, regulate their own production by feedback inhibition of TSH and TRH synthesis in the pituitary and hypothalamus when T3 binds to thyroid hormone receptors (TRs) that interact with the promoters of the genes for the TSH subunit and TRH. All TR isoforms are believed to be involved in the regulation of this endocrine axis, as evidenced by the massive dysregulation of TSH production in mice lacking all TR isoforms. However, the relative contributions of TR isoforms in the pituitary vs. the hypothalamus remain to be completely elucidated. Thus, to determine the relative contribution of pituitary expression of TR-alpha in the regulation of the hypothalamic-pituitary-thyroid axis, we selectively impaired TR-alpha function in TR-beta null mice (TR-beta-/-) by pituitary restricted expression of a dominant negative TR-beta transgene harboring a delta337T mutation. These animals exhibited 10-fold and 32-fold increase in T4 and TSH concentrations, respectively. Moreover, the negative regulation of TSH by exogenous T3 was completely absent and a paradoxical increase in TSH concentrations and TSH-beta mRNA was observed. In contrast, prepro-TRH expression levels in T3-treated TR-beta-/- were similar to levels observed in the delta337/TR-beta-/- mice, and ligand-independent activation of TSH in hypothyroid mice was equivalently impaired. Thus, isolated TR-beta deficiency in TRH paraventricular hypothalamic nucleus neurons and impaired function of all TRs in the pituitary recapitulate the baseline hormonal disturbances that characterize mice with complete absence of all TRs.     

Pituitary-thyroid axis reactivity to hyper- and hypothyroidism in the perinatal period: ontogeny of regulation of regulation and long-term programming of responses.

To evaluate the role of perinatal thyroid status in the development of pituitary-thyroid axis regulation, we administered triiodothyronine to newborn rats for the first five days postpartum to achieve hyperthyroidism, or propylthiouracil perinatally to rat dams and pups from gestational day 17 through postnatal day 5 to achieve hypothyroidism. Plasma T4, T3, and TSH levels were determined from birth through 50 days postpartum. Administration of exogenous T3 produced the expected immediate suppression of plasma T4 and TSH, with recovery toward normal values beginning within days of discontinuing the T3 regimen. Plasma T3 values were markedly elevated during the period in which T3 was being given, but subsequently became subnormal, with deficits persisting into young adulthood. With the PTU regimen, plasma T4 and T3 levels were markedly suppressed through postnatal day 10, rose over the ensuing two weeks, but nevertheless showed significant deficits into adulthood. TSH levels in the immediate neonatal period were subnormal in the PTU group, despite the marked lowering of circulating thyroid hormones; TSH then rose dramatically to levels four times normal, subsiding to control values by the end of the first month. These results suggest that a critical period exists in which regulation of pituitary-thyroid axis function is programmed. During this phase, TSH secretion can be suppressed by excess thyroid hormones, but cannot be increased by hormone deficiencies. Perhaps more importantly, perinatal thyroid status "programs" its own future reactivity, so that early hypothyroidism results in reduced T4 and T3 levels in adulthood, despite normal levels of TSH.     

Functional state of the thyroid gland during systemic graft vs host reaction

Triiodothyronine (T3), thyroxine (T4) and thyroid stimulating hormone (TSH) serum content was measured in mice during systemic "graft-versus-host" reaction (GVHR), using radioimmunoassay. It was demonstrated that on the 3rd day after GVHR induction the levels of these hormones did not differ from the control values. T3 and T4 concentrations and 125I absorption by thyroid gland diminished by day 10. At the same time TSH level remained unchanged. On day 24 after GVHR induction T3 and T4 content was significantly reduced, although TSH concentration exceeded the control value. 125I absorption was enhanced as compared to the value observed on day 10. The data obtained show the vigorous inhibition of thyroid gland function during systemic GVHR.     

Thyrotropin increases malic enzyme messenger ribonucleic acid levels in rat FRTL-5 thyroid cells

The addition of TSH to FRTL-5 thyroid cells induces a 7- to 8-fold increase in the steady state level of malic enzyme [L-malate-NADP+ oxidoreductase (decarboxylating); EC 1.1.1.40] mRNA, but does not alter beta-actin mRNA levels. Insulin alone or together with TSH has no effect on malic enzyme mRNA. The effect of TSH is not the result of thyroid hormone formation, since the addition of T3 in the presence or in the absence of TSH and the addition of 5% serum (which includes T3 and T4) have no effect. Forskolin (10(-6) M) reproduces the TSH effect, suggesting that cAMP is involved.     

The nude rat is established as a model for endocrine studies: regulation of thyroid function and xenotransplantation of a thyroid tumor cell line.

The thyroid physiology of athymic nude rats, rnu/rnu, is characterized and established here as an animal model to study transplanted thyroid tumors. Male rats were catheterized 5 days before experiments were started. The mean thyroid-stimulating-hormone (TSH) plasma concentrations were 2.9 +/- 0.6 ng/ml during infusion of 0.25 ml/h of 0.9% NaCl (n = 12). T3 plasma concentrations were 2.6 +/- 0.4 ng/ml. T4 plasma levels were 22.0 +/- 5.6 micrograms/dl. A bolus of 0.1 mg thyrotropin-releasing hormone (TRH) significantly increased TSH plasma concentrations (P less than or equal to 0.001; from 2.9 +/- 0.6 to 7.8 +/- 1.1 ng/ml, n = 12). No pulsatile TSH secretion was observed in a 2-hour period with blood samples taken every 10 minutes (n = 12) and hourly sampling disclosed no circadian variation of TSH during a 24-hour period (n = 4). Successful xenografting was possible in 12 of 15 cases using a follicular thyroid carcinoma cell line (FTC 133). Measurement of human thyroglobulin (hTg) by a hTg IRMA revealed high levels in rats with functional FTC tumors, whereas no hTg was detected in untransplanted rats or animals with nonfunctional transplants.     

TSH producing pituitary tumor: biochemical diagnosis and long-term medical management with octreotide.

A 50 year old man with hyperthyroidism secondary to inappropriate secretion of TSH is described. On presentation T3 (42.1 nmol/L), T4 (265 nmol/L) and TSH (17.9 mU/L) were all markedly elevated. A diagnosis of a TSH-secreting pituitary tumor was suspected on the basis of a blunted TSH response to TRH and the absence of suppression of TSH by T3 or bromocriptine, but TSH/alpha subunit molar ratios were uncharacteristically less than 1. Nevertheless, the presence of a tumor was confirmed by computed tomography which demonstrated a 15 mm pituitary macroadenoma. The patient was treated with octreotide which resulted in normalisation of thyroid hormone levels. The duration of action of a single 100 micrograms injection of octreotide was at least 56 hours. The suppression of thyroid hormone levels was similar regardless of the treatment regimen with octreotide (100 micrograms tid, 250 micrograms bid, 100 micrograms bid and continuous subcutaneous infusion (CSI] and no escape was observed during a 16 month treatment period. TSH alpha subunit concentrations were also suppressed during long-term treatment with octreotide (3.3 micrograms/L falling to 1.1 micrograms/L), although no acute changes were noted after administration of single dose octreotide 100 micrograms. Three times the octreotide therapy was discontinued. The incremental rise in TSH and the maximum level of TSH achieved was less on each subsequent occasion, suggesting a suppressive effect of octreotide on the tumor itself. Despite suppression of TSH with octreotide over a 13 month period the pituitary tumor showed no shrinkage on repeat MRI scanning. In conclusion, this patient demonstrates that the differential diagnosis of inappropriate TSH secretion based only on biochemical test may be unreliable.(ABSTRACT TRUNCATED AT 250 WORDS)     

Maturation of the pituitary-thyroid axis during the perinatal period.

To clarify the maturation process of the pituitary-thyroid axis during the perinatal period, thyrotropin (TSH) response to thyrotropin releasing hormone (TRH) and serum thyroid hormone levels were examined in 26 healthy infants of 30 to 40 weeks gestation. A TRH stimulation test was performed on 10 to 20 postnatal days. Basal concentrations of serum thyroxine (T4), free thyroxine (free T4) and triiodothyronine (T3) were positively correlated to gestational age and birth weight (p less than 0.001-0.01). Seven infants of 30 to 35 gestational weeks demonstrated an exaggerated TSH response to TRH (49.7 +/- 6.7 microU/ml versus 22.1 +/- 4.8 microU/ml, p less than 0.001), which was gradually reduced with gestational age and normalized after 37 weeks gestation. A similar decrease in TSH responsiveness to TRH was also observed longitudinally in all of 5 high responders repeatedly examined. There was a negative correlation between basal or peak TSH concentrations and postconceptional age in high responders (r = -0.59 p less than 0.05, r = -0.66 p less than 0.01), whereas in the normal responders TSH response, remained at a constant level during 31 to 43 postconceptional weeks. On the other hand, there was no correlation between basal or peak TSH levels and serum thyroid hormones. These results indicate that (1) maturation of the pituitary-thyroid axis is intrinsically controlled by gestational age rather than by serum thyroid hormone levels, (2) hypersecretion of TSH in preterm infants induces a progressive increase in serum thyroid hormones, and (3) although there is individual variation in the maturation process, the feedback regulation of the pituitary-thyroid axis matures by approximately the 37th gestational week.     

A follow-up study of 85 patients with Graves' disease in remission who developed undetectable serum thyroid-stimulating hormone concentrations using sensitive TSH assays.

Eighty-five patients with Graves' disease in clinical remission after treatment for over 1 year by methimazole therapy (36 patients, group A) or subtotal thyroidectomy (49 patients, group B) who became undetectable for serum thyrotropin levels (TSH less than 0.05 mU/l), were further followed for 1 year or more. Eight patients in group A (22%) and 7 patients in group B (14%) relapsed. Eleven patients in group A (30%) and 5 patients in group B (10%) had fluctuating patterns of free T4 in the upper normal to slightly supranormal range indicative of subclinical hyperthyroidism. The remaining patients continued to have undetectable TSH levels or restored normal TSH levels and normal thyroid hormone concentrations in sera. The results of the present study indicate that the occurrence of undetectable serum TSH concentrations in Graves' disease patients previously treated with methimazole or surgery are not necessarily predictive of clinical relapse because the eventual outcome is variable.     

TSH and prolactin secretions in Hashimoto's thyroiditis following withdrawal of thyroid hormone therapy

Changes in the pituitary-thyroid axis in patients with Hashimoto's thyroiditis following withdrawal of thyroid suppressive therapy were analyzed. The group of patients with thyroid adenoma served as control (group I). Patients with Hashimoto's thyroiditis were divided into 2 groups on the basis of serum TSH levels 8 weeks after discontinuing the exogenous thyroid hormone (group II, less than 10 microunits/ml; group III, more than 10 microunits/ml). During treatment with L-T4(200 micrograms/day) or L-T3(50 micrograms/day), there was no significant difference in serum T4-I and T3 levels among the three groups. Following L-T4 withdrawal, basal serum TSH levels were higher at 2 to 8 weeks in groups II and III than in group I. Serum TSH response to TRH was greater at 4 to 8 weeks in groups II and III than in group I. Following L-T3 withdrawal, basal serum TSH levels were higher at 1 and 2 weeks in group II than in group I, while those of group III were consistently higher during the study. Higher TSH responses to TRH were observed at 1 to 8 weeks in groups II and III. Neither basal nor TRH-induced prolactin (PRL) secretion differed significantly among the three groups. We have demonstrated that pituitary TSH secretion in patients with Hashimoto's thyroiditis is affected more by withdrawal of thyroid hormone therapy than in patients with thyroid adenoma. In addition, the present findings suggest a difference between the sensitivity of thyrotrophs and lactotrophs in Hashimoto's thyroiditis after prolonged thyroid therapy is discontinued.