Detection of anti-Mullerian hormone receptor II protein in the postnatal rat testis from birth to sexual maturity

Anti-Mullerian hormone (AMH) produced by the immature Sertoli cells negatively regulates the postnatal Leydig cell (i.e. adult Leydig cells/ALC) differentiation, however, the mechanism is sparsely understood. AMH negatively regulates the steroidogenic function of fetal Leydig cells (FLC) and ALC. However, when this function is established in the ALC lineage and whether AMH has a function in FLC in the postnatal testis are not known. Therefore, the objectives of this study were to examine the presence of AMH receptor type II (AMHR-II) in FLC and cells in the ALC lineage in the postnatal mammalian testis using the rat model Male Sprague Dawley rats of days 1, 5, 7-21, 28, 40, 60 and 90 were used. AMHR-II in testicular interstitial cells was detected in testis tissue using immunocytochemistry. Findings showed that the mesenchymal and the progenitor cells of the ALC lineage, were negative for AMHR-II. The newly formed ALC were the first cell type of the ALC lineage to show positive labeling for AMHR-II, and the first detection was on postnatal day 13, although they were present in the testis from day 10. From days 13-28, labeling intensity for AMHR-II in the ALC was much weaker than those at days 40-90. FLC were also positive. The time lag between the first detection of the newly formed ALC in the testis and the first detection of AMHR-II in them suggests that the establishment of the negative regulatory role of AMH on ALC steroidogenesis does not take place immediately upon their differentiation; no change in cell size occurs during this period. The absence of AMHR-II in mesenchymal cells suggests that it is unlikely that the negative regulatory effect of AMH on ALC differentiation in the postnatal testis is achieved via a direct action of AMH on mesenchymal cells. The presence of AMHR-II in postnatal FLC suggests a possible role by AMH on FLC, which warrants future investigations.     

Evidence for a role for anti-Mullerian hormone in the suppression of follicle activation in mouse ovaries and bovine ovarian cortex grafted beneath the chick chorioallantoic membrane

The first critical transition in follicular development, the activation of primordial follicles to leave the pool of resting follicles and begin growth, is poorly understood, but it appears that the balance between inhibitory and stimulatory factors is important in regulating the exodus of follicles from the resting pool. There is evidence that anti-Mullerian hormone (AMH; also known as MIS) inhibits follicle activation in mice, but whether it plays a similar role in non rodent species is not known. When pieces of bovine ovarian cortex, rich in primordial follicles, are cultured in serum-free medium, most follicles initiate growth, but when cortical pieces are grafted beneath the chorioallantoic membrane (CAM) of chick embryos, follicle activation does not occur. Since embryonic chick gonads of both sexes produce and secrete high levels of AMH, the hypothesis that the AMH in the chick circulation inhibits follicle activation was tested. In Experiment 1, whole newborn mouse ovaries were grafted beneath the CAM (placed "in ovo") or cultured in vitro for 8 days. In vitro (or after 8 days in vivo) follicles activated and proceeded to the primary or secondary stage, but activation was suppressed in ovo. This inhibition was reversed if ovaries were removed from beneath the CAM and cultured in vitro. In contrast, when ovaries from mice null mutant for the AMH type II receptor were CAM-grafted in Experiment 2, follicle activation occurred in a similar fashion to activation in vitro. This finding strongly implicates AMH as the inhibitor of follicle activation in ovo. Since chick embryonic gonads are the source of circulating AMH, chicks were gonadectomized in Experiment 3, prior to grafting of pieces of bovine ovarian cortex beneath their CAMs. Bovine primordial follicles activated in the gonadectomized chicks, similar to the results for mice lacking the AMH type II receptor. Taken together these experiments provide strong evidence that AMH is the inhibitor of mouse follicle activation present in the circulation of embryonic chicks and provide indirect, and hence more tentative, evidence for AMH as an inhibitor of bovine follicle activation.     

Thyroid hormone levels in rats exposed to alcohol during development

Maternal ingestion of alcohol appears to cause a pattern of congenital anomalies with a reduction of pre- and postnatal growth in the offspring. In order to study the possible implication of thyroid function in the effects of pre- and/or postnatal exposure to alcohol, we have studied serum thyroxine (T4) and triiodothyronine (T3) levels in rats from alcohol-fed mothers during the postnatal period (0-50 days). Blood alcohol levels of ethanol-treated pregnant rats were approximately equal to 20-25 mM and their serum T4 levels were decreased, compared with the pair-fed controls, at 15 and 21 days of gestation. No significant changes were observed in T3 levels. Prenatal alcohol exposure was associated with a decrease in both T4 and T3 levels in pups at birth. Although T4 levels continued reduced in the 40-50 days of the postnatal period, no clear effects were observed on T3 levels during this time. Moreover, the more marked alterations were obtained when the offspring were postnatally and pre + postnatally exposed to alcohol. Significant decreases were found in both T4 and T3 levels following postnatal exposure, except at the 20-25th day when a marked but transient increase in T4 levels was observed. These results indicate that alcohol exposure disturbs the hypothalamo-pituitary-thyroid axis, as measured by T3 and T4 hormone levels, mainly when the rats are exposed during the postnatal period.     

Effects of hypothyroidism on anti-mullerian hormone expression in the prepubertal rat testis

Differentiation of adult Leydig cells (ALC) in the prepubertal rat testis is stimulated by thyroid hormone (Thy) and inhibited by the Anti-Mullerian Hormone (AMH) produced by the immature Sertoli cell (SC). As Thy induces SC maturation in the prepubertal rat testis, we hypothesized that Thy stimulation of ALC differentiation is mediated via inhibition of AMH production by the SC with their maturation. If this hypothesis is true, AMH production by the prepubertal Sertoli cells in hypothyroid rats should not decline immediately after birth as in euthyroid rats, but should be maintained throughout the hypothyroid period at a similar or higher level to that of day 1 rats. This concept was tested using control rats of postnatal days (pd) 1, 7 and 14 and hypothyroid (fed 0.1% propyl thiouracil/PTU to lactating mothers) rats of pd7 and pd14. Presence of AMH in SC was examined by immunocytochemistry for AMH. Results demonstrated that testes of pd1 rats had intense AMH positive labeling exclusively in cytoplasm of SC. In testes of pd7 and pd14 control and PTU rats, a positive but weak labeling was also observed in cytoplasm of some SC; Germ cells and testicular interstitial cells were negative for AMH at all tested ages in both experimental groups. These findings suggest that AMH production by the prepubertal SC is independent of Sertoli cell maturation and not regulated by Thy. Therefore, Thy regulation of ALC differentiation in the prepubertal rat testis is unlikely to be mediated via inhibition of AMH produced by the SC with their maturation.     

Effect of selenium on thyroid hormone metabolism in filial cerebrum of mice with excessive iodine exposure

The effects of supplementing selenium on thyroid hormone metabolism were studied on mice with excessive iodine exposure. The serum concentrations of thyroxine (T₄) and triiodothyronine (T₃) and the activities of iodothyronine 5′ and 5-deiodinase (D2, D3) were measured in the brain of filial mice to study the influence of selenium on thyroid hormone metabolism. Measurements were carried out on postnatal day 0, 14, and 28. It was found that selenium supplementation alleviated the adverse effects of excessive iodine on progeny. The serum TT₄ level as well as TT₄ and TT₃ concentrations and D3 activity in cerebrum of progeny decreased, whereas D2 activity increased in the cerebrum of progeny on postnatal day 0 and 14. Selenium supplementation exerted some favorable effects on thyroid hormone metabolism in cerebrum of progeny of dam with excessive iodine intake.     

Thyroid hormone response to thyrotropin releasing hormone after cold treatment during pre- and postnatal development in the domestic fowl

The purpose of the present study was to compare the effect of periodic cooling during the establishment of a functional pituitary-thyroid axis at days 11-14 of incubation and at other developmental stages, on the subsequent thyroid hormone response to thyrotropin releasing hormone (TRH). In the first and second experiment chick embryos were cooled for 6 hr/day to 30 degrees C from day 11 till 14 and from day 15 till 18 respectively, whereas control groups were incubated throughout at 37.8 degrees C. In both experiments the thyroxine (T4) response upon TRH in 19 day-old embryos was higher in the previously cold treated embryos, according to the percentages of increase. However, the higher T4 response in the cold treated animals disappeared in 1 or 7 day-old chicks hatched from the 2nd experiment, but remained present in chicks of the same ages in the 1st experiment. In a third experiment the T4 response to TRH injection immediately and 3 and 8 days after a temperature treatment (25 degrees C or 12 degrees C) for one week on four weeks old broiler chickens was found to be similar in both temperature groups. In all experiments there was a concomitant triiodothyronine (T3) increase after TRH injection, but differences between experimental groups were observed at days 15 and 19 of incubation and immediately after the postnatal temperature treatment. As an overall conclusion the results indicate that cold treatment only during the establishment of the hypothalamo-hypophysial control of thyroid function can have a long lasting effect by enhancing the T4 response to TRH injection.     

Compensatory role of thyroid hormone receptor (TR) alpha 1 in resistance to thyroid hormone: study in mice with a targeted mutation in the TR beta gene and deficient in TR alpha 1

Resistance to thyroid hormone (RTH) is caused by mutations of the thyroid hormone receptor beta (TR beta) gene. Almost all RTH patients are heterozygous with an autosomal dominant pattern of inheritance. That most are clinically euthyroid suggests a compensatory role of the TR alpha1 isoform in maintaining the normal functions of thyroid hormone (T3) in these patients. To understand the role of TR alpha1 in the manifestation of RTH, we compared the phenotypes of mice with a targeted dominantly negative mutant TR beta (TR betaPV) with or without TR alpha1. TR betaPV mice faithfully recapitulate RTH in humans in that these mice demonstrate abnormalities in the pituitary-thyroid axis and impairment in growth. Here we show that the dysregulation of the pituitary-thyroid axis was worsened by the lack of TR alpha1 in TR betaPV mice, and severe impairment of postnatal growth was manifested in TR betaPV mice deficient in TR alpha1. Furthermore, abnormal expression patterns of T3-target genes in TR betaPV mice were altered by the lack of TR alpha1. These results demonstrate that the lack of TR alpha1 exacerbates the manifestation of RTH in TR betaPV mice. Therefore, TR alpha1 could play a compensatory role in mediating the functions of T3 in heterozygous patients with RTH. This compensatory role may be especially crucial for postnatal growth.     

Thyroid hormone regulates alpha and alpha + isoforms of Na,K-ATPase during development in neonatal rat brain

The brain contains two molecular forms of Na,K-ATPase designated alpha found in non-neuronal cells and neuronal soma and alpha + found in axolemma. Previously we have shown that the abundance of both forms (determined by immunoblots) as well as Na,K-ATPase activity increases 10-fold between 4 days before and 20 days after birth (Schmitt, C. A., and McDonough, A. A. (1986) J. Biol. Chem. 261, 10439-10444). Hypothyroidism in neonates blunts these increases. Neonatal, but not adult brain Na,K-ATPase is thyroid hormone (triiodothyronine, T3) responsive. This study defines the period during which brain Na,K-ATPase responds to T3. The start of the critical period was defined by comparing Na,K-ATPase activity and alpha and alpha + abundance in hypothyroid and euthyroid neonates (birth to 30 days of age). For all parameters, euthyroid was significantly higher by 15 days of age. The end of the critical period was defined by dosing hypothyroid neonates with T3 daily (0.1 micrograms/g body weight) beginning at increasing days of age, and sacrificing all at 30 days then assaying enzyme activity and abundance. Those starting T3 treatment on or before day 19 were restored to euthyroid levels of Na,K-ATPase activity and abundance, while those starting T3 treatment on or after day 22 remained at hypothyroid levels of enzyme activity and abundance. We conclude that brain Na,K-ATPase alpha and alpha + isoforms are sensitive to T3 by as late as 15 days of age and that the period of thyroid hormone responsiveness is over by 22 days.     

A thyrotoxic skeletal phenotype of advanced bone formation in mice with resistance to thyroid hormone

Thyroid hormone (T3) regulates bone turnover and mineralization in adults and is essential for skeletal development during childhood. Hyperthyroidism is an established risk factor for osteoporosis. Nevertheless, T3 actions in bone remain poorly understood. Patients with resistance to thyroid hormone, due to mutations of the T3-receptor beta (TRbeta) gene, display variable phenotypic abnormalities, particularly in the skeleton. To investigate the actions of T3 during bone development, we characterized the skeleton in TRbetaPV mutant mice. TRbetaPV mice harbor a targeted resistance to thyroid hormone mutation in TRbeta and recapitulate the human condition. A severe phenotype, which includes shortened body length, was evident in homozygous TRbetaPV/PV animals. Accelerated growth in utero was associated with advanced endochondral and intramembranous ossification. Advanced bone formation resulted in postnatal growth retardation, premature quiescence of the growth plates, and shortened bone length, together with increased bone mineralization and craniosynostosis. In situ hybridization demonstrated increased expression of fibroblast growth factor receptor-1, a T3-regulated gene in bone, in TRbetaPV/PV perichondrium, growth plate chondrocytes, and osteoblasts. Thus, the skeleton in TRbetaPV/PV mice is thyrotoxic and displays phenotypic features typical of juvenile hyperthyroidism.     

Thyroid hormone responses to feeding in ob/ob mice

Many of the disturbances which characterize adult C57BL/6 ob/ob mice, including obesity, hypometabolism and hypothermia could arise from reduced circulating levels of thyrotropin and thyroid hormones. In the present study, measurement of these hormones in ad libitum-fed obese and lean mice housed at 22 degrees C revealed that mutant mice had levels of TSH equal to those of their ?/+ siblings, while total T4 and T3 concentrations were slightly higher than those of lean controls. The hormonal responses of obese mice to overnight food deprivation or to meal ingestion were also similar to those of lean control mice. Males of both phenotypes typically had higher TSH, T4 and T3 concentrations than did females, and in male mice the circulating levels of each hormone were much more responsive to the feeding condition. The present data are consistent with recent reports of defective target tissue responses and impaired hormone deiodination rather than depressed pituitary-thyroid hormone levels in accounting for the metabolic disturbances which characterize ob/ob mice.     

Contrasting skeletal phenotypes in mice with an identical mutation targeted to thyroid hormone receptor alpha1 or beta

Thyroid hormone (T(3)) regulates bone turnover and mineralization in adults and is essential for skeletal development. Surprisingly, we identified a phenotype of skeletal thyrotoxicosis in T(3) receptor beta(PV) (TRbeta(PV)) mice in which a targeted frameshift mutation in TRbeta results in resistance to thyroid hormone. To characterize mechanisms underlying thyroid hormone action in bone, we analyzed skeletal development in TRalpha1(PV) mice in which the same PV mutation was targeted to TRalpha1. In contrast to TRbeta(PV) mice, TRalpha1(PV) mutants exhibited skeletal hypothyroidism with delayed endochondral and intramembranous ossification, severe postnatal growth retardation, diminished trabecular bone mineralization, reduced cortical bone deposition, and delayed closure of the skull sutures. Skeletal hypothyroidism in TRalpha1(PV) mutants was accompanied by impaired GH receptor and IGF-I receptor expression and signaling in the growth plate, whereas GH receptor and IGF-I receptor expression and signaling were increased in TRbeta(PV) mice. These data indicate that GH receptor and IGF-I receptor are physiological targets for T(3) action in bone in vivo. The divergent phenotypes observed in TRalpha1(PV) and TRbeta(PV) mice arise because the pituitary gland is a TRbeta-responsive tissue, whereas bone is TRalpha responsive. These studies provide a new understanding of the complex relationship between central and peripheral thyroid status.     

Prolactin and growth hormone stimulation of lactation in mice requires thyroid hormones.

This experiment tested the hypothesis that thyroid hormones are essential for a milk production response to growth hormone (GH) and prolactin (PRL). Prior to breeding, female transgenic mice expressing the herpes simplex type-I thymidine kinase in the thyroid were treated with ganciclovir to ablate thyroid follicular cells. To provide for normal gestation, thyrocyte-ablated mice were supplied thyroxine (T4) in drinking water (0.2 microgram/ml) until 7 days before parturition. Litter size was adjusted to 9 pups, hormone administration began on Day 2 of lactation, and mice were sacrificed on Day 12. There were 5-6 mice in each of 7 treatments that included nonablated controls, thyrocyte-ablated controls, and thyrocyte-ablated mice treated with T4, GH, PRL, GH + T4, and PRL + T4. Thyroxine was administered in drinking water, and GH and PRL (20 microgram/d) were administered by subcutaneous injection. Compared with thyrocyte-ablated controls, litter weight gain was unaffected when dams were treated with GH, PRL, or T4 alone. However, when dams were treated with GH or PRL in combination with T4, litter weight gain increased 13% compared with thyrocyte-ablated controls and 18% compared with GH or PRL-treated mice. Concentration of T4 in serum of pups averaged 62 ng/ml and did not differ among treatments. Concentration of T4 in serum of dams averaged 76 ng/ml when T4-treated. Thyroxine 5'-deiodinase (5'D), the enzyme that converts T4 to triiodothyronine, was quantitated in liver, kidney, and mammary gland. Quantity of 5'D was lower in liver and kidney of thyrocyte-ablated dams without T4 than in respective tissues of mice treated with T4, and there was no effect of GH or PRL. However, in mammary gland, 5'D was increased by treatment with GH, PRL, or T4. Data show that thyroid hormones are necessary for a galactopoietic response to GH and PRL and demonstrate a unique organ-specific regulation of 5'D by galactopoietic hormones.     

Thyroid hormone levels in the developing obese-hyperglycemic syndrome.

Examination of the thyroid hormone levels of C57BL/6J ob/ob mice and their lean littermates between the ages of 6 days and 22 weeks revealed that obese mice have significantly reduced hormone concentrations between 10 and 21 days of age. Thereafter, the values remained equal to, or above those or their lean littermates. The present data indicate that the hypometabolism and abnormal thermal regulation of weanling mice could be a result of diminished thyroid hormone levels, but that other mechanisms must be responsible for the persistence of these abnormalities in adult ob/ob mice.     

Thyroid hormone inhibits ERK phosphorylation in pressure overload-induced hypertrophied mouse hearts through a receptor-mediated mechanism

Pressure overload-induced cardiac hypertrophy results in a pathological type of hypertrophy with activation of signaling cascades like the extracellular signal-regulated kinase (ERK) pathway, which promotes negative cardiac remodeling and decreased contractile function. In contrast, thyroid hormone mediates a physiological type of hypertrophy resulting in enhanced contractile function. In addition, thyroid hormone action is diminished in pressure overload-induced cardiac hypertrophy. We hypothesized that thyroid hormone status modulates ERK activity and that administration of thyroid hormone could alter the activity of this kinase in cardiac hypertrophy induced by pressure overload. ERK is activated by phosphorylation; accordingly, we investigated phosphorylation of ERK in hearts of control, hypothyroid, and hyperthyroid mice. In addition, the effect of T3 treatment on ERK phosphorylation in hypertrophied hearts from transverse aortic-constricted (TAC) mice was investigated. Results showed that phosphorylated ERK (p-ERK) was decreased by 25% in hyperthyroid mice. In contrast, hypothyroid mice presented increased p-ERK by 80%. TAC mice presented a greater than fourfold increase of p-ERK compared with control mice. Interestingly, T3 administration dramatically canceled TAC-induced ERK phosphorylation (36% lower compared with control). Raf-1 is upstream of the ERK pathway. TAC mice presented a 45% increase in phospho-Raf-1 (Ser338). T3 treatment inhibited this effect of pressure overload and further decreased p-Raf-1 (Ser338) by 37%, compared with control. Overexpression of thyroid hormone receptor-α in cultured cardiomyocytes potentiated the inhibitory effect of T3 on ERK phosphorylation. We concluded that thyroid hormone has an inhibitory effect on the Raf-1/ERK pathway. Furthermore, treatment of TAC mice with T3 inhibited Raf-1/ERK pathway by a thyroid hormone receptor-dependent mechanism.     

Normal timing of oligodendrocyte development depends on thyroid hormone receptor alpha 1 (TRalpha1)

The timing of oligodendrocyte development is regulated by thyroid hormone (TH) in vitro and in vivo, but it is still uncertain which TH receptors mediate this regulation. TH acts through nuclear receptors that are encoded by two genes, TRalpha and TRbeta. Here, we provide direct evidence for the involvement of the TRalpha1 receptor isoform in vivo, by showing that the number of oligodendrocytes in the postnatal day 7 (P7) and P14 optic nerve of TRalpha1-/- mice is decreased compared with normal. We demonstrate that TRalpha1 mediates the normal differentiation-promoting effect of TH on oligodendrocyte precursor cells (OPCs): unlike wild-type OPCs, postnatal TRalpha1-/- OPCs fail to stop dividing and differentiate in response to TH in culture. We also show that overexpression of TRalpha1 accelerates oligodendrocyte differentiation in culture, suggesting that the level of TRalpha1 expression is normally limiting for TH-dependent OPC differentiation. Finally, we provide evidence that the inhibitory isoforms of TRalpha are unlikely to play a part in the timing of OPC differentiation.     

Thyroid dependent maturation of β-adrenergic receptors in the rat lung

β-Adrenergic receptors were identified in membranes of fetal and postnatal rat lung with (?)-[³H]dihydroalprenolol, [³H]DHA. β-Receptor number (Bmax) increased 11-fold from day 18 of gestation to adult levels by day 28 of postnatal life. The increase of β-adrenergic receptors occurring between postnatal days 15 and 28 was dependent on thyroxine (T4) in propylthiouracil treated pups. β-Adrenergic receptors on day 28 were identical in euthyroid (PTU + T4) as compared to normal control pups (489±31 and 491±30 femtomoles·mg^?1) however receptors were markedly reduced in 28 day hypothyroid pups (PTU alone), Bmax = 294±21.5, m±S.E. p<0.01. Treatment of the hypothyroid pups with T4 for three days on postnatal day 25 increased β-adrenergic receptors approximately two-fold by day 28. This thyroid hormone dependent increase in lung β-adrenergic receptors occurs between postnatal days 15 and 28 coincident with the known increase in thyroid gland activity in the rat pup.