Differential response of amphibian PRL and TSH pituitary cells to in vitro TRH treatment

TRH acts as a multifunctional hypophysiotropic factor in vertebrates

Thyrotropin-releasing hormone (TRH) is the first hypothalamic hypophysiotropic neuropeptide whose sequence has been chemically characterized. The primary structure of TRH (pGlu-His-Pro-NH(2)) has been fully conserved across the vertebrate phylum. TRH is generated from a large precursor protein that contains multiple repeats of the TRH progenitor tetrapeptide Gln-His-Pro-Gly. In all tetrapods, TRH-expressing neurons located in the hypothalamus project towards the external zone of the median eminence while in teleosts they directly innervate the pars distalis of the pituitary. In addition, in frogs and teleosts, a bundle of TRH-containing fibers terminate in the neurointermediate lobe of the pituitary gland. Although TRH was originally named for its ability to trigger the release of thyroid-stimulating hormone (TSH) in mammals, it later became apparent that it exerts multiple, species-dependent hypophysiotropic activities. Thus, in fish TRH stimulates growth hormone (GH) and prolactin (PRL) release but does not affect TSH secretion. In amphibians, TRH is a marginal stimulator of TSH release in adult frogs, not in tadpoles, and a major releasing factor for GH and PRL. In birds, TRH triggers TSH and GH secretion. In mammals, TRH stimulates TSH, GH and PRL release. In fish and amphibians, TRH is also a very potent stimulator of alpha-melanocyte-stimulating hormone release. Because the intermediate lobe of the pituitary of amphibians is composed by a single type of hormone-producing cells, the melanotrope cells, it is a suitable model in which to investigate the mechanism of action of TRH at the cellular and molecular level. The occurrence of large amounts of TRH in the frog skin and high concentrations of TRH in frog plasma suggests that, in amphibians, skin-derived TRH may exert hypophysiotropic functions.

Role of corticotropin-releasing hormone as a thyrotropin-releasing factor in non-mammalian vertebrates

The finding that thyrotropin-releasing hormone does not always act as a thyrotropin (TSH)-releasing factor in non-mammalian vertebrates has led researchers to believe that another hypothalamic factor may exhibit this function. In representatives of all non-mammalian vertebrate classes, corticotropin-releasing hormone (CRH) appears to be a potent stimulator of hypophyseal TSH secretion, and might therefore function as a common regulator of both the thyroidal and adrenal/interrenal axes. CRH exerts its dual hypophysiotropic action through two different types of CRH receptors. Thyrotropes express type 2 CRH receptors, while CRH-induced corticotropin (ACTH) secretion is mediated by type 1 CRH receptors on the corticotropic pituitary cells. The stimulating effect of CRH on both TSH and ACTH release has profound consequences for the peripheral action of both hormonal axes. The simultaneous stimulation of the thyroidal and adrenal/interrenal axes by CRH, possibly fine-tuned by differential regulation of the expression of the different CRH receptor isoforms, provides a potential mechanism for developmental plasticity.

Distribution of the mRNAs encoding the thyrotropin-releasing hormone (TRH) precursor and three TRH receptors in the brain and pituitary of Xenopus laevis: effect of background color adaptation on TRH and TRH receptor gene expression

In amphibians, thyrotropin-releasing hormone (TRH) is a potent stimulator of alpha-melanotropin (alpha-MSH) secretion, so TRH plays a major role in the neuroendocrine regulation of skin-color adaptation. We have recently cloned a third type of TRH receptor in Xenopus laevis (xTRHR3) that has not yet been characterized in any other vertebrate species. In the present study, we have examined the distribution of the mRNAs encoding proTRH and the three receptor subtypes (xTRHR1, xTRHR2, and xTRHR3) in the frog CNS and pituitary, and we have investigated the effect of background color adaptation on the expression of these mRNAs. A good correlation was generally observed between the expression patterns of proTRH and xTRHR mRNAs. xTRHRs, including the novel receptor subtype xTRHR3, were widely expressed in the telencephalon and diencephalon, where two or even three xTRHR mRNAs were often simultaneously observed within the same brain structures. In the pituitary, xTRHR2 was expressed selectively in the distal lobe, and xTRHR3 was found exclusively in the intermediate lobe. Adaptation of frog skin to background illumination had no effect on the expression of proTRH and xTRHRs in the brain. In contrast, adaptation of the animals to a white background provoked an 18-fold increase in xTRHR3 mRNA concentration in the intermediate lobe of the pituitary. These data demonstrate that, in amphibians, the effect of TRH on alpha-MSH secretion is mediated through the novel receptor subtype xTRHR3.

Development of radioimmunoassay for bullfrog thyroid-stimulating hormone (TSH): effects of hypothalamic releasing hormones on the release of TSH from the pituitary in vitro

A bullfrog (Rana catesbeiana) thyroid-stimulating hormone (TSH) beta-subunit (TSHbeta) antiserum was produced by employing a C-terminal peptide synthesized on the basis of the amino acid sequence deduced from bullfrog TSHbeta cDNA. Immunohistochemical studies revealed that the bullfrog adenohypophyseal cells that immunologically reacted with the anti-bullfrog TSHbeta corresponded to those positively stained with an antiserum against human (h) TSHbeta. The antiserum was used for the development of a specific and sensitive radioimmunoassay (RIA) for the measurement of bullfrog TSH. The sensitivity of the RIA was 0.75+/-0.07ng TSH/100microl assay buffer. The interassay and intraassay coefficients of variation were 7.6 and 5.3%, respectively. Several dilutions of pituitary homogenates of larval and adult bullfrogs, or medium in which bullfrog pituitary cells were cultured, yielded dose-response curves that were parallel to the standard curve. Bullfrog prolactin, growth hormone, luteinizing hormone, follicle-stimulating hormone, and alpha-subunit derived from glycoprotein hormones did not react in this assay. Immunoassayable TSH in the pituitary culture medium was confirmed to exist in the form of TSHbeta coupled with the alpha-subunit by an immunoprecipitation experiment using the TSHbeta antiserum and an alpha-subunit antiserum. TSH released from pituitary cells into the medium was also confirmed to possess a considerable activity in stimulating the release of thyroxine from the thyroid glands of larval bullfrogs in vitro. The effects of hypothalamic hormones such as mammalian gonadotropin-releasing hormone (mGnRH), ovine corticotropin-releasing hormone (oCRH), and thyrotropin-releasing hormone (TRH) on the release of TSH by dispersed anterior pituitary cells of the bullfrog larvae and adults were also studied. CRH markedly stimulated the release of TSH from both adult and larval pituitary cells. Both TRH and GnRH moderately stimulated the release of TSH from adult pituitary cells but not from the larval cells. This is the first report on the development of an RIA for amphibian TSH, which has provided the direct evidence that the release of TSH from the amphibian pituitary is enhanced by the hypothalamic releasing hormones such as CRH, TRH, and GnRH.

Characterization and functional expression of cDNAs encoding thyrotropin-releasing hormone receptor from Xenopus laevis

Thyrotropin-releasing hormone receptor (TRHR) has already been cloned in mammals wherethyrotropin-releasing hormone (TRH) is known to act as a powerful stimulator of thyroid-stimulating hormone (TSH) secretion. The TRH receptor of amphibians has not yet been characterized, although TRH is specifically important in the adaptation of skin color to environmental changes via the secretion of alpha-melanocyte-stimulating hormone (alpha-MSH). Using a dege-nerate PCR strategy, we report on the isolation of three distinct cDNA species encoding TRHR from the brain of Xenopus laevis. We have designated these as xTRHR1, xTRHR2 and xTRHR3. Analysis of the predicted amino acid sequences revealed that the three Xenopus TRHRs are only 54-62% identical and contain all the highly conserved residues constituting the TRH binding pocket. Amino acid sequences and phylogenetic analysis revealed that xTRHR1 is a member of TRHR subfamily 1 and xTRHR2 belongs to subfamily 2, while xTRHR3 is a new TRHR subtype awaiting discovery in other animal species. The three Xeno-pus TRHRs have distinct patterns of expression. xTRHR3 was abundant in the brain and much scarcer in the peripheral tissues, whereas xTRHR1 was found mainly in the stomach and xTRHR2 in the heart. The Xenopus TRHR subtype 1 was found specifically in the intestine, lung and urinary bladder. These observations suggest that the three xTRHRs each have specific functions that remain to be elucidated. Expression in Xenopus oocytes and HEK-293 cells indicates that the three Xenopus TRHRs are fully functional and are coupled to the inositol phosphate/calcium pathway. Interestingly, activation of xTRHR3 required larger concentrations of TRH compared with the other two receptors, suggesting marked differences in receptor binding, coupling or regulation.

Thyrotropin-releasing hormone immunoreactivity in the brain and the pituitary during Bufo arenarum development

The ontogeny of the thyrotropin releasing hormone (TRH) neuronal system was evaluated by immunocytochemistry in Bufo arenarum. The first appearance of TRH immunoreactive fibers was at early premetamorphosis. These fibers were found in small numbers and weakly stained in the median eminence and pars nervosa. With the advance of larval development, TRH-like material stained intensely and tended to aggregate in the median eminence, pars nervosa and pars intermedia. At climax stages immunoreactive fibers and perikarya (weakly stained) were also identified in the preoptic area. In adult specimens TRH perikarya and neuronal fibers were found in the preoptic and infundibular nuclei of the hypothalamus and in the amygdala, septum and diagonal band of Broca of the telencephalon. In addition, TRH neuronal fibers and endings were found in the preoptic-hypophyseal tract, the external zone of the median eminence, the pars nervosa and pars intermedia. Fibers were absent in the pars distalis. This study represents the first immunocytochemical demonstration of TRH in Bufo species, and serves as a basis for clarification of the neuroendocrine regulation of metamorphosis.

Melatonin accelerates metamorphosis in Xenopus laevis

Delayed metamorphosis associated with large body size has been observed in Woodhousei fowleri tadpoles reared in continuous dark (DD). To evaluate the mechanism by which DD delayed metamorphosis, light-cycle exposure was controlled and thyroxine (T4), melatonin, or drugs that alter prolactin (Prl) concentrations were given to Xenopus laevis tadpoles. It was hypothesized that exogenous melatonin would delay metamorphosis and increase body size, and that elevation of Prl concentrations would have effects similar to melatonin exposure. Xenopus laevis tadpoles were randomized to three light conditions [light/dark (LD, 12 h/12 h), DD, and continuous light (LL)] and subgroups in each light condition were treated with T4, melatonin, bromocriptine (Bro), haloperidol (Hal), or no drug. Each subgroup included 12 tadpoles. Drugs were administered in the water either continuously or daily from 07.00 to 19.00 h (Intermittent). Measurements of total length, leg length, and stage of metamorphosis were obtained at regular intervals. DD resulted in delayed metamorphosis, while LL did not. T4 accelerated metamorphosis as expected, countering the delaying effects of DD. In contrast to the hypothesis, melatonin accelerated metamorphosis and impaired body size compared to controls. Intermittent Hal also accelerated metamorphosis, while Bro delayed it. In DD, both T4 and melatonin led to increased tadpole size in contrast to their counterparts in LD or LL. Delayed metamorphosis in DD is not caused by increased melatonin production. Melatonin and Hal (as given in this study) accelerate metamorphosis. Melatonin acceleration of metamorphosis may occur through alteration of the concentration of prolactin.

Specific binding of [3H]pGlu-3-Me-His-Pro-NH2 ([3H]MeTRH) to hypothalamic membranes of juvenile rainbow trout, Oncorhynchus mykiss

We investigated the existence and nature of specific [3H]pGlu-3-Me-His-Pro-NH2 ([3H]MeTRH) binding sites in juvenile rainbow trout (Oncorhynchus mykiss) hypothalamus. Washed hypothalamic membranes were incubated with [3H]MeTRH in the absence (B0) or presence of pGlu-His-Pro-NH2 (TRH) or MeTRH under various experimental paradigms; incubations were terminated by filtration and bound radioactivity was determined by liquid scintillation spectroscopy. Specific binding (Bsp) was tissue dependent, associable, dissociable, and thermolabile. Estimated rates of association (k+1) and dissociation (k-1) were 1.64 x 10(7) M-1 min-1 and 1.98 x 10(-2) min-1, respectively, providing a kinetically derived dissociation rate constant (Kd) of 1.21 x 10(-9) M. [3H]MeTRH binding was displaceable; LIGAND-analysis of three independent homologous displacement experiments consistently indicated a single class of binding sites with an average Kd = 6.91 (+/- 4.32) x 10(-9) M and average maximum binding capacity (Bmax) of 8.84 (+/- 2.72) x 10(-15) mol/mg protein. Native TRH also displaced the radiolabel in a dose dependent manner; LIGAND-estimates for Kd and Bmax were 1.52 (+/- 0.12) x 10(-9) M and 3.79 (+/- 0.99) x 10(-15) mol/mg protein (n = 3 experiments), respectively. Our data indicate that presence of a single class of specific high-affinity TRH-binding sites in the rainbow trout hypothalamus; these findings suggest a role for TRH in regulating the release of hypophysiotrophic factors in the teleost hypothalamus.

Hormonal storage patterns and morphological heterogeneity of porcine gonadotrope cells during postnatal development

Previous reports indicate that gonadotrope cells of the porcine pituitary gland can be separated into three subpopulations of low- (1.049 g/cm3), middle- (1.062 g/cm3) and high- (1.087 g/cm3) density in a continuous Percoll density gradient. The aim of this work was to study the hormonal storage patterns and morphological features of these subpopulations at three representative ages of the postnatal development: neonatals (30-day-old animals), prepubertals (5-6-month-old animals) and matures (16-18-month-old animals). The low-density subpopulation, present at the three ages studied, was mainly composed of bihormonal LH/FSH cells in neonatal and monohormonal LH cells in prepubertal and mature animals. On the other hand, middle- (only present in prepubertal and mature animals) and high-density subpopulations (only present in neonatal and prepubertal animals) were mainly composed of bihormonal LH/FSH gonadotropes. In ultrastructural terms, these subpopulations exhibit a correlation between density and morphology irrespective of the animal's age. The low-density subpopulation was composed of poorly granulated cells with highly developed biosynthetic machinery (rough endoplasmic reticulum and Golgi complex), while high-density cells were of opposite morphology, with a highly granulated cytoplasm and poorly developed rough endoplasmic reticulum and Golgi complex. The middle-density subpopulation was composed of poorly granulated cells with scarcely developed biosynthetic machinery. In conclusion, these results indicate that porcine gonadotrope cells during postnatal development are composed of three subpopulations of different hormonal storage patterns and morphology. The presence of these subpopulations at the different stages of postnatal development strongly suggests that their proportions may play a major role in the endocrine control process.

Different exocytotic morphology in amphibian prolactin and growth hormone cells stimulated in vitro with TRH

Exocytotic process in growth hormone (GH) and prolactin cells (PRL) of the frog anterior pituitary have been examined using an experimental design that has been previously demonstrated to increase the release of hormone from both cell types. Hemipituitaries of the same animals were superfused either with medium alone or containing 100 ng/ml of thyrotropin-releasing hormone (TRH) for 24 hr. PRL and GH cells were identified by the colloidal gold method using anti-human prolactin and anti-ovine growth hormone as primary antisera. In hemipituitaries cultured with medium alone, PRL and GH cells showed few exocytotic figures with different morphology in both cells types. In TRH treated hemipituitaries, PRL cells showed numerous exocytotic vacuoles containing immunoreactive granulated material that was preferentially located near basal lamina. On the other hand, GH cells showed higher amount of exocytotic vacuoles containing heterogeneous immunoreactive material, located along the cell membrane. In PRL cells single secretory granules are secreted, whereas GH cells showed multigranular exocytosis. These results indicate that in PRL and GH amphibian cells exocytotic process has a different polarity and morphology and that this process increases with TRH stimulation.