Thyrotropin-releasing hormone and a homologous peptide in the male rat reproductive system

TRH and a TRH-like peptide have been shown to occur throughout the male rat reproductive system by TRH radioimmunoassay, SP-Sephadex C25 cation exchange chromatography, high pressure liquid chromatography and parallel line analysis. The total concentration of TRH and TRH-like peptide was highest in the prostate followed by the testis, cauda epididymis and seminal vesicles. Dilution curves for extracts of prostate, testis and seminal vesicles were parallel with TRH while the corresponding curve for epididymis was nonparallel.     

High concentrations of p-Glu-His-Pro-NH2 (Thyrotropin-releasing hormone) occur in rat prostate

Thyrotropin-releasing hormone (TRH) immunoreactivity occurs in high concentration within the rat prostate. Previous studies have shown that the immunoreactive species consists of more than one TRH-like tripeptide which cross-reacts in the TRH radioimmunoassay. The component which was highly retained during cation exchange chromatography was subjected to a preparative scale isolation, purification and structural analysis. The methods used included methanol extraction, waterethyl ether partitioning, cation exchange chromatography, affinity chromatography, high pressure liquid chromatography, TRH radioimmunoassay, in vitro pituitary bioassay, TRH receptor assay, and amino acid analysis. The mean concentration of the predominant amino acids (Glu, His, Pro), 344 pmoles/ml, and the TRH concentration measured by TRH radioimmunoassay prior to acid hydrolysis, 372 pmoles/ml, were nearly identical. Because the material analyzed cochromatographed with synthetic TRH in several chromatographic systems, had a radioreceptor potency which was indistinguishable from that for synthetic TRH, and released TSH and prolactin but not growth hormone from rat pituitaries in vitro, it is concluded that pGlu-His-Pro-NH₂ is one of the TRH-like peptides in the rat vental prostate.     

The TRH-like peptide pGlu-Glu-ProNH2 is present in the porcine pituitary but not in reproductive tissues.

The peptide pGlu-Glu-ProNH2, which differs from thyrotrophin-releasing hormone (TRH) by only one amino acid, was initially detected and characterised in the rabbit prostate complex and more recently in human semen and rat pituitary. A previous study reported that TRH and a homologous peptide were present in a range of porcine tissues and it was of interest to further characterise these peptides. In this study, high levels of TRH-immunoreactivity have been demonstrated in the porcine pituitary, the majority of which was authentic TRH; although 9% was found to be chromatographically identical to pGlu-Glu-ProNH2. In contrast, TRH-immunoreactivity was not detected in follicular fluid, ovary or prostate. The unexpected finding that pGlu-Glu-ProNH2 is present in the porcine pituitary but absent from regions of the reproductive tract may be of biological significance.     

Effects of prostatic inhibin and thyroid releasing hormone on lipid peroxidation in rat prostate

Effects of prostatic inhibin and thyroid releasing hormone (TRH) on lipid peroxidation in rat prostate was studied in an in vitro system. It was found that both inhibited the lipid peroxidase activity thus having a protective role in the prostate.     

TRH-related peptides in the rabbit prostate complex during development.

The novel peptide, pyroglutamylglutamylprolineamide (pGlu-Glu-ProNH2), has recently been isolated and characterized from the rabbit prostate complex. The tripeptide is present in high concentrations in the prostate complex and semen, together with a 40-50 residue polypeptide which contains a TRH-immunoreactive fragment at its C-terminus. The present study investigates changes in the levels of these TRH-related peptides in rabbits aged 11 weeks, 4 months, 7 months, 13 months and 2 years. For each age group the peptides were extracted from the prostate complex, separated by gel exclusion chromatography, and located by TRH radioimmunoassay. The TRH-immunoreactive fragment was released from the polypeptide by trypsin digestion prior to radioimmunoassay. Very low concentrations of TRH-immunoreactive peptides were present at 11 weeks of age, but considerable levels of both peptides were found in all the other age groups. Anion exchange chromatography, under conditions which resolve TRH and pGlu-Glu-ProNH2, showed that the majority of the low molecular weight TRH immunoreactivity co-eluted with synthetic pGlu-Glu-ProNH2. The remaining TRH immunoreactivity, which had not bound to the anion resin, also failed to bind to a cation exchange column at pH 2.0, indicating that it was not authentic TRH. Dissection of the prostate complex into its four constitutive regions (vesicular gland, coagulating gland, prostate and bulbourethral gland) followed by extraction, chromatography and TRH radioimmunoassay of each region showed that the TRH-related peptides were located in the prostate.     

Rapid modulation of TRH and TRH-like peptide release in rat brain and peripheral tissues by ghrelin and 3-TRP-ghrelin

Ghrelin is not only a modulator of feeding and energy expenditure but also regulates reproductive functions, CNS development and mood. Obesity and major depression are growing public health concerns which may derive, in part, from dysregulation of ghrelin feedback at brain regions regulating feeding and mood. We and others have previously reported that thyrotropin-releasing hormone (TRH, pGlu-His-Pro-NH(2)) and TRH-like peptides (pGlu-X-Pro-NH(2), where "X" can be any amino acid residue) have neuroprotective, antidepressant, anti-epileptic, analeptic, anti-ataxic, and anorectic properties. For this reason male Sprague-Dawley rats were injected ip with 0.1mg/kg rat ghrelin or 0.9mg/kg 3-Trp-rat ghrelin. Twelve brain regions: cerebellum, medulla oblongata, anterior cingulate, posterior cingulate, frontal cortex, nucleus accumbens, hypothalamus, entorhinal cortex, hippocampus, striatum, amygdala, piriform cortex and 5 peripheral tissues (adrenals, testes, epididymis, pancreas and prostate) were analyzed. Rapid and profound decreases in TRH and TRH-like peptide levels (increased release) occurred throughout brain and peripheral tissues following ip ghrelin. Because ghrelin is rapidly deacylated in vivo we also studied 3-Trp-ghrelin which cannot be deacylated. Significant increases in TRH and TRH-like peptide levels following 3-Trp-ghrelin, relative to those after ghrelin were observed in all brain regions except posterior cingulate and all peripheral tissues except prostate and testis. The rapid stimulation of TRH and TRH-like peptide release by ghrelin in contrast with the inhibition of such release by 3-Trp-TRH is consistent with TRH and TRH-like peptides modulating the downstream effects of both ghrelin and unacylated ghrelin.     

PMA-sensitive protein kinase C is not necessary in TRH-stimulated prolactin release from female rat primary pituitary cells.

In GH3 cells and other clonal rat pituitary tumor cells, TRH has been shown to mediate its effects on prolactin release via a rise of cytosolic Ca2+ and activation of protein kinase C. In this study, we examined the role of protein kinase C in TRH-stimulated prolactin release from female rat primary pituitary cell culture. Both TRH and PMA stimulated prolactin release in a dose-dependent manner. When present together at maximal concentrations, TRH and PMA produced an effect which was slightly less than additive. Pretreatment of rat pituitary cells with 10(-6) M PMA for 24 hrs completely down-regulated protein kinase C, since such PMA-pretreated cells did not release prolactin in response to a second dose of PMA. Interestingly, protein kinase C down-regulation had no effect on TRH-induced prolactin release from rat pituitary cells. In contrast, PMA-pretreated GH3 cells did not respond to a subsequent stimulation by either PMA or TRH. Pretreatment of rat pituitary cells with TRH (10(-7) M, 24 hrs) inhibited the subsequent response to TRH, but not PMA. Forskolin, an adenylate cyclase activator, stimulated prolactin release by itself and in a synergistic manner when incubated together with TRH or PMA. The synergistic effects of forskolin on prolactin release was greater in the presence of PMA than TRH. Down-regulation of protein kinase C by PMA pretreatment abolished the synergistic effect produced by PMA and forskolin but had no effect on those generated by TRH and forskolin. sn-1,2-Dioctanylglycerol (DOG) pretreatment attenuated the subsequent response to DOG and PMA but not TRH. The effect of TRH, but not PMA, on prolactin release required the presence of extracellular Ca2+. In conclusion, the mechanism by which TRH causes prolactin release from rat primary pituitary cells is different from that of GH3 cells; the former is a protein kinase C-independent process whereas the latter is at least partially dependent upon the activation of protein kinase C.     

Effects of calcium hopantenate on the release of thyrotropin-releasing hormone from the rat adrenal gland in vitro

The effects of calcium hopantenate (HOPA), a GABA agonist, on the release of thyrotropin-releasing hormone (TRH) from the rat adrenal gland were studied in vitro. The adrenal glands were incubated in medium 199 with 1.0 mg/ml of bacitracin (pH 7.4) (medium) for 20 min. The amount of TRH release into the medium was measured by radioimmunoassay. The TRH release from the rat adrenal gland was inhibited significantly in a dose-related manner with the addition of HOPA to the medium. HOPA's effects on TRH release from the adrenal gland were blocked with the addition of bicuculline, a GABA receptor inhibitor. The elution profile of methanol-extracted rat adrenal gland TRH was identical to that for synthetic TRH. The findings suggest that HOPA inhibits TRH release from the rat adrenal gland, and that its effects are mediated via the GABA receptor.     

Effects of dopamine on the release of thyrotropin-releasing hormone from the rat retina in vitro.

The effects of dopamine on the release of thyrotropin-releasing hormone (TRH) from the rat retina in vitro were studied. The rat retina was incubated in the medium 199 (pH 7.4) with 1.0 mg/ml of bacitracin and 100 micrograms/ml of ascorbic acid. The amount of TRH release into the medium was measured by radioimmunoassay. The TRH release from the rat retina was inhibited significantly in a dose-related manner with the addition of dopamine, but not with pimozide. The inhibitory effects of dopamine on TRH release from the rat retina were blocked with an addition of pimozide to the medium. The elution profile of methanol-extracted rat retina on sephadex G-10 was identical to that of synthetic TRH. From these findings it is concluded that the dopaminergic system inhibits TRH release from the rat retina in vitro.     

大鼠睾丸前促甲状腺激素释放激素原及其受体的表达与发育变化

为研究促甲状腺激素释放激素（thyrotrophin-releasing hormone,TRH)及其受体（TRH receptor,TRHR)在大鼠睾丸组织中的表达规律和在生殖发育调节中的作用,依据大鼠下丘脑中的前TRH原（PreproTRH,ppTRH)和垂体中的TRH－R cDNA设计引物,采用RT－PCR法从大鼠睾丸组织中获得了ppTRH和TRH－R的cDNA克隆,测序后构建表达载体,在大肠杆菌中表达了可溶性的pTRH t TRH-R融合蛋白,利用实时动态定量RT－PCR（real time quantitative RT-PCR)法观察了ppTRH和TRH－R在不同发育阶段大鼠睾丸中的表达变化,发现在睾丸间质细胞发育的初期阶段（第8天）,没有ppTRH和TRH－R的表达,但从第15天起能观察到pp-TRH和TRH－R的表达,并且表达量在20天,35天,60天和90天逐渐增加,这些结果表明：大鼠睾丸组织能特异性表达ppTRH和TRH－R,并且表达量与发育过程相关,ppTRH和TRH－R体外表达产物的获得为后续研究其功能奠定了基础。     

Dopamine inhibits thyrotropin-releasing hormone release from rat adrenal gland in vitro

The effects of dopamine on the release of thyrotropin-releasing hormone (TRH) from the rat adrenal gland were studied in vitro. The rat adrenal glands were incubated in medium 199 with 1.0 mg/ml of bacitracin and 100 micrograms/ml of ascorbic acid (pH 7.4) (medium) for 20 min. The amount of TRH release into the medium was measured by radioimmunoassay. The immunoreactive TRH (ir-TRH) release from the rat adrenal gland was inhibited significantly in a dose-related manner with the addition of dopamine and enhanced with the addition of pimozide or domperidone to the medium. Dopamine's effects on ir-TRH release from the adrenal gland were blocked with the addition of pimozide or domperidone. The elution profile of methanol-extracted rat adrenal gland was identical to that of synthetic TRH. The findings suggest that the dopaminergic system inhibits TRH release from the rat adrenal gland.     

Effects of acetylcholine on thyrotropin-releasing hormone release from the rat caecum in vitro

Effects of acetylcholine on the release of thyrotropin-releasing hormone (TRH) from the rat caecum in vitro were studied. The rat caecum was incubated in medium 199 with 1.0 mg/ml of bacitracin and 100 micrograms/ml of ascorbic acid (pH 7.4) (medium). The amount of TRH release into the medium was measured by radioimmunoassay. The immunoreactive TRH (ir-TRH) release from the rat caecum was enhanced significantly in a dose-related manner with the addition of acetylcholine, but not changed with atropine. The stimulatory effect of acetylcholine on ir-TRH release from the rat caecum was blocked with an addition of atropine. Elution profile of acid-methanol-extracted rat caecum on Sephadex G-10 was identical to that of synthetic TRH. The findings suggest that the cholinergic system stimulates TRH release from the rat caecum in vitro.     

Ontogenesis of TRH mRNA in the rat pancreas

The rapid changes in TRH levels in the rat pancreas during the neonatal period make this organ an interesting model for the study of the regulation of TRH biosynthesis. Pancreatic RNAs were isolated by the guanidinium thiocyanate method and layered onto CsCl cushion. Northern blot preparations were hybridized with 32P labeled TRH cDNA probe. Pancreatic TRH mRNA was first detected in 19-day old fetuses and reached the highest level on day 0, then decreased, being barely detectable 14 days after birth. The neonatal injection of streptozotocin induced a dramatic drop of TRH mRNA levels 24 hours later. This result suggests that the peculiar evolution of TRH level in pancreas is partly due to the evolution of the expression of the TRH gene.     

Thyrotropin-releasing hormone in the gastrointestinal tract.

TRH immunoreactivity has been shown to occur throughout the rat gastrointestinal tract. This immunoreactivity demonstrates parallelism with TRH, is destroyed by fresh human serum, and co-chromatographs with TRH on a Sephadex G-10 column and on a SP Sephadex C-25 column. In addition pancreatic extracts showed bioactivity in a mouse bioassay for TRH.     

Thyrotropin-releasing hormone gene expression in normal thyroid parafollicular cells

The rat TRH gene encodes a 255-amino-acid precursor polypeptide, preproTRH, containing five copies of TRH and seven non-TRH peptides. Expression of this gene is well documented in the central nervous system, particularly in the hypothalamus. Thyroids also contain TRH immunoreactivity, but it is unknown whether this immunoreactivity results from expression of the TRH gene or from other genes encoding TRH-like products. Since the CA77 neoplastic parafollicular cell line expresses the TRH gene, we investigated whether TRH gene expression also occurs in normal thyroid parafollicular cells. Northern analysis of total thyroid RNA with a preproTRH-specific RNA probe identified a single hybridizing band the same size as authentic TRH mRNA found in hypothalamus and CA77 cells. Gel filtration analysis of thyroid extracts identified the same 7-kilodalton and 3-kilodalton species of immunoreactive preproTRH53-74 previously identified in hypothalamus and CA77 cells. Immunoreactive preproTRH115-151, not previously identified, was found in all three tissues. Part of this immunoreactivity comigrated with the synthetic preproTRH115-151 standard on gel filtration and reversed-phase HPLC. PreproTRH53-74 was localized to thyroid parafollicular cells by immunostaining. These findings demonstrate authentic TRH gene expression by normal rat thyroid parafollicular cells and establish the CA77 cell line as the only model system of a normal TRH-producing tissue. In addition to expanding the range of neuroendocrine peptides known to be produced by parafollicular cells, these results also suggest a potential paracrine regulatory role for TRH gene products within the thyroid.     

The computer modelling of human TRH receptor, TRH and TRH-like peptides

The aim of this work was to verify the possibility of interactions between the human TRH receptor (an integral membrane protein which belongs to family 1 of G-protein coupled receptors) and TRH-like peptides presented in the prostate gland. These peptides are characterized by substitution of basic amino acid histidine (related to authentic TRH) for neutral or acidic amino acid, such as glutamic acid, phenylalanine, glutamine or tyrosine. The physiological function of TRH-like peptides in peripheral tissues is not precisely known. However, according to our recent experiments, we assume the existence of a local hormonal network formed by TRH-like peptides and TSH in the prostate gland. The network can be associated with circulating thyroid and steroid hormones, and may represent a new regulatory mechanism influencing the proliferative ability of prostatic tissue. A similar network of authentic TRH and TSH was already found in the gastrointestinal tract. The experimentally determined 3D-structures of human TRH receptor (hTRHr) and TRH-like peptides are not available. From this point of view we used de novo modeling procedures of G-protein coupled receptors on an automated protein modeling server used at the Glaxo Wellcome Experimental Research (Geneva, Switzerland). 3D-structures of TRH-like peptides were determined with a computer program CORINA (written by the team of J. Gasteiger, Computer-Chemie-Centrum and Institute for Organic Chemistry, University of Erlangen-Nurenberg, Germany). The generated PDB files with 3D-coordinates were visualized with Swiss-Pdb Viewer Release 3.51 (Glaxo Wellcome). From recent results it is evident that polar amino acids belonging to the extracellular terminus of hTRHr transmembrane regions can participate in interactions between TRH and hTRHr. There is no direct evidence that TRH-like peptides interact with the presented hTRHr model. On the contrary, with respect to the similar 3D-shape and the identity of terminal amino acids, it appears that these interactions are highly probable as well as the nearly 100 % cross-reactions between TRH or TRH-like peptides and antibody specific against authentic TRH. Closed terminal amino acids (pyroglutamic acid and proline-amide) of TRH or TRH-like peptides are important for these interactions. Desamido-TRH or glutamyl metabolites will be repelled by the negative potential of ASP195 (E: D93) and GLU298 (G: E137).     

Effects of opioid peptides on thyrotropin-releasing hormone release from the rat caecum in vitro

Effects of opioid peptides (beta-endorphin, dynorphin (1-13). alpha-neoendorphin, beta-neoendorphin, leucine-enkephalin, methionine-enkephalin) on the release of thyrotropin-releasing hormone (TRH) from the rat caecum were studied in vitro. The rat caecum was incubated in medium 199 with 1.0 mg/ml of bacitracin (pH 7.4) (medium). The amount of TRH release from the rat caecum into the medium was measured by radioimmunoassay. The immunoreactive TRH (ir-TRH) release from the rat caecum was inhibited significantly in a dose-related manner with the addition of opioid peptides. The inhibitory effects of opioid peptides on ir-TRH release from the rat caecum were blocked with an addition of naloxone. The elution profile of acid-methanol-extracts of rat caecum on Sephadex G-10 was identical to that of synthetic TRH. The findings suggest that opioid peptides inhibit TRH release from the rat caecum in vitro.     

Effect of thyrotropin-releasing hormone on rat myometrium

The effect of TRH in vitro was observed on electromyograms and isometric tension changes in the uterine horn isolated from the rat. TRH induced transient prolongation of the duration of spike bursts in the electromyogram and an increased tension in contraction of diestrous uterine horns. No distinct response to TRH was elicited in preparations from rats during other estrous stages. TRH produced a contraction associated with a burst of spike potentials in the quiescent horn from the estrogen-primed ovariectomized rat. Priming with progesterone was not a prerequisite for responsiveness to TRH. In a medium with a high Ca concentration, diestrous uteri were quiescent but a transient contraction associated with a burst of spike potentials was induced by TRH. In a Ca-free medium, TRH failed to elicit any response in the diestrous uterus but acetylcholine induced a contraction without associated spike potentials. It appears that TRH stimulates Ca-influx into the uterine muscle in which responsiveness is dependent on estrogen priming.     

The effects of dopaminergic antagonism by sulpiride on TRH and VIP-induced prolactin release in nonsuckled lactating rats

Prolactin (PRL) release was studied in female rats during midlactation using pharmacologic manipulations designed to mimic the hypothalamic effects of suckling. In the first experiment pituitary dopamine (DA) receptors were blocked by sulpiride (10 micrograms/rat i.v.). One hour later, thyrotropin-releasing hormone (TRH, 1.0 micrograms/rat i.v.) was given to induce PRL release. TRH released significantly more PRL following DA antagonism than when no DA antagonism was produced, suggesting that DA receptor blockade increased the sensitivity of the AP to TRH. In a second experiment, VIP (25 micrograms/rat) increased plasma prolactin 3-4 fold but this effect was not enhanced significantly by prior dopamine antagonism with sulpiride. We conclude that dopamine antagonism enhances the PRL releasing effect of TRH but not VIP in lactating rats.     

Thyrotropin-releasing hormone and a homologous peptide in the reproductive system of the female rat and pig

TRH and a TRH homologous peptide have been shown to occur throughout the female rat and pig reproductive systems by TRH radioimmunoassay, SP-Sephadex C-25 cation exchange chromatography, and parallel line analysis of the assays. The total amount of TRH and TRH homologous peptide immunoreactivity was highest in the oviducts followed by the ovary and then uterus. The concentration of TRH immunoreactivity in all reproductive organs of the rat fell gradually from one month of age. TRH and the TRH homologous peptide were not parallel on serial dilution and measurement in the same TRH radioimmunoassay. The rapid degradation of TRH by pig follicular fluid may explain the higher measured concentration of TRH homologous peptide compared to TRH not only in pig follicular fluid but also in the pig ovary as a whole.