Carmen C. Pazos-Moura

Divergent roles for thyroid hormone receptor β isoforms in the endocrine axis and auditory system

Thyroid hormone receptors (TRs) modulate various physiological functions in many organ systems. The TR alpha and TR beta isoforms are products of 2 distinct genes, and the beta 1 and beta 2 isoforms are splice variants of the same gene. Whereas TR alpha 1 and TR beta 1 are widely expressed, expression of the TR beta 2 isoform is mainly limited to the pituitary, triiodothyronine-responsive TRH neurons, the developing inner ear, and the retina. Mice with targeted disruption of the entire TR beta locus (TR beta-null) exhibit elevated thyroid hormone levels as a result of abnormal central regulation of thyrotropin, and also develop profound hearing loss. To clarify the contribution of the TR beta 2 isoform to the function of the endocrine and auditory systems in vivo, we have generated mice with targeted disruption of the TR beta 2 isoform. TR beta 2-null mice have preserved expression of the TR alpha and TR beta 1 isoforms. They develop a similar degree of central resistance to thyroid hormone as TR beta-null mice, indicating the important role of TR beta 2 in the regulation of the hypothalamic-pituitary-thyroid axis. Growth hormone gene expression is marginally reduced. In contrast, TR beta 2-null mice exhibit no evidence of hearing impairment, indicating that TR beta 1 and TR beta 2 subserve divergent roles in the regulation of auditory function.

Maternal high‐fat diet induces obesity and adrenal and thyroid dysfunction in male rat offspring at weaning

•  Perinatal maternal high‐fat diet changes milk composition, resulting in obesity and hyperglycaemia in male offspring at weaning. •  Offspring obesity is associated with hyperleptinaemia and changes in the central leptin signalling pathway in the hypothalamic arcuate nucleus. •  Maternal high‐fat diet increased adrenal catecholamines in offspring but reduced liver and adipose tissue adrenoreceptors, thereby contributing to increased adiposity in these animals. •  Early obesity and hyperleptinaemia in offspring may have a stimulatory effect on the hypothalamus–pituitary–thyroid axis as an adaptive response to the positive energy balance. •  Both catecholamines and thyroid hormones may impact cardiovascular function, thereby contributing to the development of hypertension.

Thyroid hormone action is required for normal cone opsin expression during mouse retinal development.

PURPOSE The expression of S- and M-opsins in the murine retina is altered in different transgenic mouse models with mutations in the thyroid hormone receptor (TR)-beta gene, demonstrating an important role of thyroid hormone (TH) in retinal development. METHODS The spatial expression of S- and M-opsin was compared in congenital hypothyroidism and in two different TR mutant mouse models. One mouse model contains a ligand-binding mutation that abolishes TH binding and results in constitutive binding to nuclear corepressors. The second model contains a mutation that blocks binding of coactivators to the AF-2 domain without affecting TH binding. RESULTS Hypothyroid newborn mice showed an increase in S-opsin expression that was completely independent of the genotype. Concerning M-opsin expression, hypothyroidism caused a significant decrease (P < 0.01) only in wild-type animals. When TRbeta1 and -beta2 were T3-binding defective, the pattern of opsin expression was similar to TRbeta ablation, showing increased S-opsin expression in the dorsal retina and no expression of M-opsin in the entire retina. In an unexpected finding, immunostaining for both opsins was detected when both subtypes of TRbeta were mutated in the helix 12 AF-2 domain. CONCLUSIONS The results show, for the first time, that the expression of S- and M-opsin is dependent on normal thyroid hormone levels during development.

Effect of thyroid hormones on pituitary neuromedin B and possible interaction between thyroid hormones and neuromedin B on thyrotropin secretion

Neuromedin B (NB), a bombesin-like peptide, has been recently characterized as a physiological paracrine/autocrine inhibitor of thyrotropin (TSH) secretion. We hypothesized on the basis of our prior experiments that thyroid hormones stimulate pituitary NB secretion which mediates, at least in part, the TSH-suppressive effect of thyroid hormone. Here, we evaluated the time-course of the effect of thyroid hormones administration to eu- and hypothyroid rats on the anterior pituitary content of NB and on serum TSH. As previously reported, the pituitary content of NB increased in hyperthyroidism and decreased in hypothyroidism. Chronic treatment of hypothyroid rats with a physiological dose of thyroxine (0.8 microgram/100 g b.w. s.c, for 3 or 5 days) normalized pituitary NB content, while 5 days of treatment with a pharmacological dose of thriiodothyronine (0.4 microgram/100 g b.w.) induced an increase above that of normal pituitaries. Thyroxine and triiodothyronine injected once, s.c., into hypothyroid rats required 30 min to normalize NB content, which reached higher than normal values in 3-6 h. At these times, the increment in NB preceded or was simultaneous with the suppression of serum TSH. This rapid and marked effect on pituitary neuromedin B content, associated in time with TSH suppression, is in agreement with the hypothesis that neuromedin B may mediate at least in part, the acute suppression of TSH release by thyroid hormone, a hypothesis that still needs further verification.

Pituitary neuromedin B content in experimental fasting and diabetes mellitus and correlation with thyrotropin secretion

Fasting and diabetes mellitus in the rat model have been associated with abnormalities of thyrotropin (TSH) secretion. Neuromedin B is a bombesin-like peptide highly concentrated in the pituitary gland that has been shown to have inhibitory action on TSH secretion, acting as an autocrine/paracrine factor. Here, we aimed to determine if the pituitary content of neuromedin B would change in fasted rats (1, 2, 3, and 4 days of food deprivation) and streptozotocin (55 mg/kg body weight)-diabetic rats. The total pituitary content of neuromedin B was decreased in fasted rats, except at 2 days of fasting, as was the total protein content in the gland; however, the concentration of the peptide (femtomoles per milligram protein) did not significantly change until the fourth day of food deprivation, when an abrupt decrease in total protein happened and therefore neuromedin B concentration increased. In rats after 20 days of diabetes induction, pituitary neuromedin B increased. Serum thyroxine (T4) and triiodothyronine (T3) decreased in both disorders, whereas serum TSH was normal or decreased in 4-day fasted rats. Therefore, the caloric deprivation of diabetes and fasting changed the pituitary neuromedin B content and concentration, by mechanisms that remain to be elucidated. Since neuromedin B has been shown to act as a local inhibitor of TSH release, the results raise the possibility that increased neuromedin B concentration might be involved in the altered TSH secretion of diabetes mellitus and fasting.

Nailfold capillaroscopy in hypothyroidism and hyperthyroidism : Blood flow velocity during rest and postocclusive reactive hyperemia

Direct intravital microscopic examinations of nailfold capillaries were made in three groups of subjects: 15 healthy volunteers (C) and 11 patients, six with hypothyroidism (h) and five with hyperthyroidism (H). The groups h and H were examined twice, before the onset of treatment and when they returned to euthyroidism. Capillary blood flow velocity (CBFV) was measured during rest and after release of 60-second arterial occlusion. To assess autoregulatory capacity the authors determined peak CBFV postoc clusion and time to reach it in single capillaries. In patients with hypothyroidism, before the onset of the treatment, the mean resting and the mean peak CBFV were significantly lower (resting CBFV—group C: 0.93 ±0.11 mm/s (mean ±SE); group h: 0.33 ±0.09 mm/s; and mean peak CBFV—group C: 1.49 ±0.14 mm/s; group h: 0.79 ±0.19 mm/s). The time to reach mean peak CBFV postocclusion was significantly prolonged (group C: 8.9 ±0.65 s and group h: 19.2 ±2.0 s) compared with the group of healthy volunteers. When these patients achieved euthyroidism, all the studied parameters returned to control levels. In patients with hyperthyroidism only minor changes in CBFV could be detected. In patients with hypothyroidism, the skin microvascular autoregulatory mech anisms are disturbed. The impairments of the reactive hyperemia response could be corre lated with the control of the disease (thyroid state).

Effect of Triiodothyronine on Adiponectin Expression and Leptin Release by White Adipose Tissue of Normal Rats

Previous studies have shown that alterations in thyroid status may lead to changes in serum leptin and adiponectin, both in humans and rodents. The mechanisms, especially for adiponectin, are unclear. In the present study, we investigated the effect of triiodothyronine (T3) on the expression of adiponectin mRNA and the release of leptin and adiponectin by white adipose tissue (WAT) explants obtained from epididymal (visceral) or inguinal (subcutaneous) depots from normal rats. We also analyzed the effects of other known regulators of adiponectin and leptin release, such as rosiglitazone and dexamethasone. T3 acted directly at rat WAT explants in a depot-specific manner and in a unique fashion to each hormone. T3 was able to inhibit leptin release only by epididymal explants, and to reduce adiponectin mRNA expression only in inguinal explants. However, T3 was incapable of modifying adiponectin release by both explants. Additionally, rosiglitazone exhibited an inhibitory effect on adiponectin release by both WAT explants, even though adiponectin mRNA was importantly upregulated only in inguinal explants. Rosiglitazone acted as an inhibitor of leptin release by both studied fat depots, while only epididymal explants responded to the stimulatory effect of dexamethasone on leptin release. Therefore, the present model of isolated rat white adipose tissue explants highlights the fact that the regulation of hormonal production by white adipose tissue depends on the type of depot and its anatomical location. In this context, our results show for the first time a potential inhibitory effect of T3 on adiponectin mRNA expression specifically on WAT from a subcutaneous depot.

Dose-dependent effects of 17-beta-estradiol on pituitary thyrotropin content and secretion in vitro

We studied the basal and thyrotropin-releasing hormone (TRH) (50 nM) induced thyrotropin (TSH) release in isolated hemipituitaries of ovariectomized rats treated with near-physiological or high doses of 17-beta-estradiol benzoate (EB; sc, daily for 10 days) or with vehicle (untreated control rats, OVX). One group was sham-operated (normal control). The anterior pituitary glands were incubated in Krebs-Ringer bicarbonate medium, pH 7.4, at 37 degrees C in an atmosphere of 95% O2/5% CO2. Medium and pituitary TSH was measured by specific RIA (NIDDK-RP-3). Ovariectomy induced a decrease (P < 0.05) in basal TSH release (normal control = 44.1 +/- 7.2; OVX = 14.7 +/- 3.0 ng/ml) and tended to reduce TRH-stimulated TSH release (normal control = 33.0 +/- 8.1; OVX = 16.6 +/- 2.4 ng/ml). The lowest dose of EB (0.7 microgram/100 g body weight) did not reverse this alteration, but markedly increased the pituitary TSH content (0.6 +/- 0.06 microgram/hemipituitary; P < 0.05) above that of OVX (0.4 +/- 0.03 microgram/hemipituitary) and normal rats (0.46 +/- 0.03 microgram/hemipituitary). The intermediate EB dose (1.4 micrograms/100 g body weight) induced a nonsignificant tendency to a higher TSH response to TRH compared to OVX and a lower response compared to normal rats. Conversely, in the rats treated with the highest dose (14 micrograms/100 g body weight), serum 17-beta-estradiol was 17 times higher than normal, and the basal and TRH-stimulated TSH release, as well as the pituitary TSH content, was significantly (P < 0.05) reduced compared to normal rats and tended to be even lower than the values observed for the vehicle-treated OVX group, suggesting an inhibitory effect of hyperestrogenism. In conclusion, while reinforcing the concept of a positive physiological regulatory role of estradiol on the TSH response to TRH and on the pituitary stores of the hormone, the present results suggest an inhibitory effect of high levels of estrogen on these responses.

Effect of testosterone propionate treatment on thyrotropin secretion of young and old rats in vitro

The aim of this study was to evaluate the influence of androgens on TSH secretion during aging in Dutch rats. Male young (2 months) and old (16-21 months) rats were castrated (Cx) or sham-operated (C) and received testosterone propionate (TP--4 mg/Kg B.W., i.m., 7 days) or vehicle. Female adult (3 months) and old (12 and 17 months) intact rats received TP or corn oil in the same dose. The rats were decapitated, trunk blood was collected and anterior pituitaries were dissected out for in vitro incubation. In Cx young male rats, only TSH pituitary content showed lower levels than in their controls. Cx TP-treated rats showed higher serum TSH and in vitro basal and TRH-induced TSH secretion, but TP only partially reversed the decrease in pituitary TSH promoted by castration. The old male rats showed lower basal in vitro TSH secretion and pituitary TSH content. In Cx old male rats, serum and basal in vitro TSH concentrations were higher than those of old controls and TP treatment further increased basal in vitro TSH secretion, as well as, stimulated TRH-induced TSH secretion. Interestingly, TP had no effect on intact young or old male rats. However, in intact old female rats, TP stimulated in vitro TSH secretion but, as observed in the intact male, TP had no effect on adult female rats. These results suggest a stimulatory role of testosterone on TSH secretion of young and old male rats. Thereafter, it seems that the testes of old rats secrete some testicular factor that inhibits TSH secretion. However, in male rats with normal testosterone levels TP treatment did not increase further TSH secretion, but in old female rats it had a stimulatory effect.

Role of Neuromedin B in the In Vitro Thyrotropin Release in Response to Thyrotropin-Releasing Hormone from Anterior Pituitaries of Eu-, Hypo-, and Hyperthyroid Rats

Abstract A role of neuromedin B (NB), a bombesin-like peptide, as an inhibitory paracrine/autocrine regulator of thyrotropin secretion has been suggested. We previously reported (10) that basal thyroid-stimulating hormone (TSH) release in vitro was decreased by NB and increased in the presence of a highly potent antiserum against NB (aNB). In these experiments, we studied the effects of NB (10-11-10-7 M) and antiserum against NB (aNB, 1:2000 dilution) on basal TSH release and the response to thyrotropin-releasing hormone (TRH) (0.5 × 10-8 M) from incubated anterior pituitaries from eu-, hypo-, and hyperthyroid rats. As expected, in euthyroid rats NB decreased basal and TRH-stimulated TSH release, but only at the highest concentration tested (10-7 M). Incubation of the pituitaries from euthyroid rats with the antiserum against NB increased basal TSH release above that from glands of normal rabbit serum-incubated controls, as anticipated based on the concept that NB inhibits TSH release from the pituitary glands of euthyroid animals. The antiserum did not augment the response to TRH, suggesting that NB released in this situation, although suppressing basal release, had no effort on the stimulated release induced by TRH. Glands from hypothyroid rats had a slightly lower basal TSH release and decreased response to TRH than glands from euthyroid rats. They responded with a decrease in basal TSH release at a much lower concentration of NB (10-9 M) than pituitaries from euthyroid animals. Surprisingly, pituitaries from hypothyroid rats showed a paradoxical increased release of TSH in response to the lowest concentration of NB (10-11 M), which decreased with increasing concentrations and was not distinguishable from control release in the presence of TRH at the highest concentration of NB (10-7 M). We hypothesize that the increased responsiveness to the inhibition of basal TSH release by NB in the hypothyroid pituitaries may be related to an upregulation of NB receptors in this situation, in which the release of NB is diminished because of loss of feedback via thyroid hormones. [P.S.E.B.M. 1996, Vol 211]