Effects of intra-amygdaloid TRH injections on motor activity and dominant-submissive behavior in rats competing for water.

The effect of thyrotropin releasing hormone (TRH) microinjections into the central amygdala (10 g in 0.5 1 into each side) on locomotor activity water intake and dominance behavior in a water competition test was investigated in male Wistar rats. TRH increased the general motility without altering the number of rearings. Intra-amygdaloid TRH injection to submissive rats resulted in a loss of subordinate position in these animals in the water competition test. A tendency to decrease dominance followed the injection of the peptide to the dominant animals. The effect of TRH in the dominance test does not appear to involve influence on the thirst drive as microinjection of the peptide did not change significantly the water consumption in thirsty rats.     

Morphine inhibits TRH-induced gastric contractile activity.

This study investigated the effect of centrally and peripherally administered thyrotropin releasing hormone (TRH) on gastric contractile activity of rats 14, 21, 28 and adult (greater than or equal to 50) days (D) of age, and the effect of morphine pretreatment on that response. Rats were anesthetized with urethane, then a tension transducer was implanted on the anterior gastric corpus. Following baseline recording, rats were pretreated with intraperitoneal morphine (2 mg/kg). TRH (5 micrograms) in saline or saline alone (0.6 microliters) was then injected into the cisternum magnum. Additionally, dose response to TRH was examined in 14- and 50-day-old rats. Intracisternal TRH induced a dose-related increase in gastric contractile activity in both 14- and 50-day-old rats. Higher doses of TRH (10 and 30 micrograms) prolonged the response as compared to low doses. Peripheral morphine pretreatment blocked the TRH-induced increase in gastric contractile activity in all age groups although a higher morphine dose (10 mg/kg) was needed to block the effect in 28D rats. Intravenous TRH (5, 10, 30 micrograms) produced an increase in gastric contractile activity in 14D rats which was blocked by vagotomy.     

Effects of morphine on cold-induced TRH release from the median eminence of unanesthetized rats

The effect of morphine perfusion into the median eminence on cold-induced TRH secretion was studied in unanesthetized rats by push-pull cannulation. Perfusion with 10(-6)M morphine blocked the cold-induced TRH peak occurring about 40 min after the transfer of rats from 24 degrees C to 4 degrees C. This inhibition by morphine was blunted by concomitant administration of naloxone (10(-6)M or 10(-5)M), but naloxone alone had no effect on either basal or cold-induced TRH release. We conclude that specific opiate receptors may be located on TRH nerve endings in the ME, and that endogenous opiates may not have any physiological role in the cold-induced TRH response, at least during the two hours that follow cold exposure.     

Effect of intratesticular administration of TRH or anti-TRH antiserum on function of rat testis

The effect of intratesticular administration of thyrotropin-releasing hormone (TRH) and anti-TRH antiserum on steroidogenesis was studied in immature and adult rats. In 9-day-old animals local administration of the neuropeptide resulted in an increase in basal testosterone secretion in vitro. Similar treatment of 15-day-old rats suppressed hCG-stimulated testosterone secretion with no change in basal testosterone production. In both immature groups the treatment did not affect serum testosterone concentration. By contrast, in adults TRH decreased serum testosterone level, but did not influence basal and hCG-stimulated testosterone secretion. Both in immature and adult rats, the changes in steroidogenesis were evident 1 hour posttreatment. Five days after the administration of anti-TRH antiserum into the remaining testis of immature rats subjected to hemicastration just prior to the antiserum treatment, the alterations in steroidogenesis were opposite to those detected after treatment with TRH. In 9-day-old rats the antiserum suppressed steroidogenesis, while in 15-day-old animals it stimulated testosterone secretion. The results suggest that testicular TRH might exert a local action on testicular steroidogenesis, and the effect is age-dependent.     

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.     

Spontaneously hypertensive rats exhibit supersensitivity to the hypertensive and hyperthermic effects of thyrotropin releasing hormone

The effect of thyrotropin releasing hormone (TRH) on colonic temperature and systolic blood pressure of age-matched spontaneously hypertensive (SHR) and normotensive Wistar-Kyoto (WKY) rats was determined. Administration of TRH produced dose-dependent increases in body temperature and systolic blood pressure. TRH-induced changes in both responses were of greater magnitude in SHR rats compared to WKY rats. The results provide the first evidence that SHR rats exhibit supersensitivity to non-neuroendocrinological effects of TRH and that TRH may play a role in the pathophysiology of elevated blood pressure.     

Evidence of a direct TRH effect on the rat exocrine pancreas.

In the present study, the effect of TRH on amylase secretion was determined both in vivo, by cannulating the pancreatic duct of rats, as well as in vitro, by using isolated lobules and dissociated acini. The results show that TRH inhibited both basal and stimulated in vivo amylase secretion. Nevertheless, the in vitro experiments failed to show a TRH-related inhibitory effect when TRH was used alone, although the hormone did blunt the secretion elicited by CCK8 and bethanechol from isolated lobules and dissociated acini. Results suggest that TRH can inhibit stimulated amylase secretion in rats through a direct effect on acinar cells.     

Effects of exposure of pregnant rats to TRH on development of the pituitary-thyroid axis in their progeny

TRH (10 and 1000 micrograms/kg body weight (BW] was injected ip into pregnant rats daily from day 0 to 20 of pregnancy, and the pituitary-thyroid axis of their pups (Mat-TRH rats) was examined on days 0, 4, 10, 21 and 90 after birth. The pituitary TSH content of male Mat-TRH rats was significantly lower on day 4, and higher on day 10 than that of control rats. The serum TSH was significantly higher on day 10 (except female 10 micrograms/kg group). An exaggerated TSH response to exogenous TRH (10 micrograms/kg BW; ip) was observed on day 10 (males, 1000 micrograms/kg group). The serum T4 level of female Mat-TRH rats was low on day 4 (1000 micrograms/kg group), and higher on day 10. On days 21 and 90, the levels of pituitary TSH, serum TSH and T4 in Mat-TRH rats were similar to those in controls, but the TSH response to TRH was still exaggerated (1000 micrograms/kg group). No significant difference between control and TRH-treated mothers was seen on days 10 and 90 postpartum except for a decreased pituitary TSH content on day 10 in the 1000 micrograms/kg group. It is concluded that repeated administration of TRH to pregnant rats shows an effect on the pituitary-thyroid axis function of their progeny in later life.     

Twenty-four hour rhythms of hypothalamic corticotropin-releasing hormone, thyrotropin-releasing hormone, growth hormone-releasing hormone and somatostatin in rats injected with Freund's adjuvant

The effect of Freund's adjuvant injection on 24-hour variation of hypothalamic corticotropin-releasing hormone (CRH), thyrotropin-releasing hormone (TRH), GH-releasing hormone (GRH) and somatostatin levels was examined in adult rats kept under light between 0800 and 2000 h daily. Groups of rats receiving Freund's complete adjuvant or its vehicle 3 days before sacrifice were killed at six different time intervals throughout a 24-hour cycle. In the median eminence, adjuvant vehicle-injected rats exhibited significant 24-hour variations for the four hormones examined, with maxima at noon. These 24-hour rhythms were inhibited or suppressed by Freund's adjuvant injection. In the anterior hypothalamus of adjuvant vehicle-treated rats, CRH content peaked at 1600 h, while two peaks were found for TRH and GRH levels, i.e., at 2400-0400 h and 1600 h. Freund's adjuvant injection suppressed 24-hour rhythm of anterior hypothalamic CRH, TRH and GRH content and uncovered a peak in anterior hypothalamic somatostatin levels at 0400 h. In the medial hypothalamus of adjuvant vehicle-treated rats, significant 24-hour variations were detectable for TRH (peaks at 1600 and 2400 h) and somatostatin (peak at 2400 h) which disappeared after Freund's adjuvant injection. In the posterior hypothalamus of adjuvant vehicle-treated rats, two peaks were apparent for CRH, TRH and somatostatin levels, i.e. at 1600 h and 2400-0400 h, this hormonal profile remaining unmodified after Freund's adjuvant administration. The administration of the immunosuppressant drug cyclosporine (5 mg/kg, 5 days) impaired the depressing effect of Freund's adjuvant injection on CRH, TRH and somatostatin content in median eminence, but not that on GRH. In the anterior hypothalamus, cyclosporine generally prevented the effect of immunization on hormone levels an revealed a second maximum in TRH at 0400 h. Cyclosporine also restored 24-hour variations in TRH and somatostatin levels of medial hypothalamus of Freund's adjuvant-injected rats but was unable to modify them in the posterior hypothalamus. The results further support the existence of a significant effect of immune-mediated inflammatory response at an early phase after Freund's adjuvant injection on hypothalamic levels which was partially sensitive to immunosuppression by cyclosporine.     

Thyrotropin releasing hormone in the pancreas of newborn rats from streptozotocin-treated mothers

The effect of maternal diabetes (induced by i.p. injections of 40-50 mg/kg BW Streptozotocin on the day of mating) on TRH in the pancreas of newborn rats was studied. Determination of peptide alpha amidation activity and TRH precursor level on the day of birth revealed decreased biosynthesis of TRH resulting in profoundly (10 times) lower pancreatic TRH and TRH-OH concentrations in pups of diabetic rats. Pancreatic His-Pro-diketopiperazine (His-Pro-DKP) remained unaffected by maternal diabetes. The depression of pancreatic TRH was less profound 24 h later, and even elevated TRH was measured in the pancreas of pups of diabetic mothers on postnatal day 5. Short term postnatal starvation or nursing of intact pups by the diabetic foster mother did not affect pancreatic TRH. It could be postulated that postnatal TRH development in the rat pancreas is retarded by maternal diabetes, while His-Pro-DKP remains unaltered.     

Thyroid hormone modulation of TRH precursor levels in rat hypothalamus, pituitary, thyroid and blood

In the present study we have examined the in vivo effects of thyroid hormones and TRH on tissue and blood levels of TRH and TRH-Gly (pGlu-His-Pro-Gly), a TRH precursor. Using specific radioimmunoassays (RIAs), we measured TRH immunoreactivity (TRH-IR) and TRH-Gly-IR concentrations in blood, hypothalamus, anterior and posterior pituitary, and thyroid in euthyroid, hypothyroid and thyroxine (T4)-treated 250 g male Sprague-Dawley rats. TRH-Gly-IR and TRH-IR were detected in all of these tissues. Highly significant positive correlations between whole blood TRH-Gly-IR levels and the corresponding serum TSH values (p less than 0.01), whole blood TRH-IR versus serum TSH (p less than 0.01) and whole blood TRH-Gly-IR versus whole blood TRH-IR (p less than 0.01) are consistent with cosecretion of TRH and TRH precursor peptides into the circulation. Euthyroid rats injected with TRH IP (1 microgram/100 g b.wt.) and hypothyroid rats had 4-fold higher whole blood TRH-Gly-IR levels compared to euthyroid controls (p less than 0.0005). Injection of TRH into euthyroid rats significantly increased the TRH-Gly-IR concentration in the hypothalamus, anterior and posterior pituitary and thyroid. The increase in blood TRH-Gly-IR following intravenous TRH may be due, in part, to partial saturation of TRH-degrading enzymes in blood and cell membranes. The ratio of TRH-Gly to TRH was significantly increased in the anterior pituitary by hypothyroidism and TRH injection, suggesting that thyroid hormones and TRH regulate the alpha-amidation of TRH-Gly to form TRH in this tissue. TRH-Gly levels of pooled pituitary and thyroid extracts quantitated by a combination of TRH-Gly RIA and high performance liquid chromatography (HPLC) revealed several-fold increases following incubation at 60 degrees C. Heating at this temperature may block the alpha-amidation activity in extra-hypothalamic tissues but not the "trypsin-like" enzymes which cleave prepro-TRH into TRH-Gly-immunoreactive peptides.     

Immunohistochemical localization of TRH in rat CNS: comparison with RIA studies

The localization of thyrotropin releasing hormone (TRH) in rat brain determined by use of avidin-biotin immunoperoxidase histochemistry was compared with the distribution and quantitation by radioimmunoassay (RIA). Male Sprague-Dawley rats received intracisternal injections of 100 micrograms of colchicine or saline and were sacrificed 24 hours later. Brains were either perfused with lysine-periodate fixative and processed for TRH immunohistochemistry or were dissected into 9 brain regions for TRH RIA. In colchicine pretreated rats. TRH immunoreactive perikarya were observed only in nuclei of the hypothalamus and brain stem. No cell body staining was observable in non-colchicine treated rats. With the exception of the olfactory bulb, brain regions exhibiting dense TRH staining contained high concentrations of TRH as measured by RIA. Colchicine pretreatment did not alter the concentration of TRH in most brain regions, however, there was a significant increase in brain stem TRH content 24 hours following colchicine administration. These findings indicate that immunohistochemical localization of TRH corresponds well with endogenous concentrations of TRH determined by RIA.     

Thyrotropin-Releasing Hormone Reduces myo-Inositol Content in Rat Cerebellum Pretreated with Lithium

The effect of thyrotropin-releasing hormone (TRH) and lithium on myo-inositol metabolism has been assessed in rat cerebral cortex, cerebellar cortex, and sciatic nerves. Sprague-Dawley male rats were injected subcutaneously with 10 mEq/kg of LiCl and intraperitoneally with 10 mg/kg of TRH-tartrate, alone or in combination. Either lithium or TRH alone had little effect on the myo-inositol concentration in cerebellar cortex, whereas the combination of lithium and TRH significantly lowered the level. The myo-inositol level of cerebellar cortex reached its nadir (70% of values in untreated control rats) 30 min after addition of TRH and then returned to the control level at 90 min. In cerebral cortex, both lithium alone and lithium plus TRH significantly reduced the myo-inositol level. No effect was seen on the myo-inositol concentration in sciatic nerves with these regimens. These results suggested that the pharmacological dose of TRH activated phosphatidylinositol turnover in rat cerebellar cortex and subsequently reduced the myo-inositol level in the presence of lithium.     

Cardiovascular effect of intravenously administered thyrotropin-releasing hormone and its concentration in push-pull perfusion of the fourth ventricle in conscious and pentobarbital-anesthetized rats

Changes in the concentration of thyrotropin-releasing hormone (TRH) in cerebrospinal fluid (CSF) were examined by the push-pull perfusion method after intravenous (i.v.) administration of the peptide in conscious and pentobarbital-anesthetized rats. The concentration of endogenous TRH in the perfusate was not changed during the 160-min perfusion period and was similar to that in the CSF (0.92 +/- 0.26 ng/ml) collected before the perfusion in conscious as well as in anesthetized rats. After i.v. administration of TRH (5 mg/kg) to the conscious rats, the peptide concentration in the perfusate increased to 42.23 +/- 14.33 ng/ml during the first 20 min and gradually returned to the basal level 2 hr after administration. The total amount of TRH detected in the perfusate was 20.0 ng. It was reduced by 75% in the anesthetized animals. The increases in blood pressure and heart rate, seen after i.v. as well as intracerebroventricular administration of TRH in the conscious rats, was significantly inhibited in the anesthetized rats. These results indicate that systemically administered TRH exerts its cardiovascular effect at central site(s), and that the transportation and the effect of the peptide is suppressed by pentobarbital anesthesia.     

In vivo and in vitro effect of naloxone on prolactin response to TRH in rat

In adult male Wistar rats submitted to a standardized noise stress, intravenous TRH induced a prolactin (PRL) secretory response. Prior IV naloxone administration not only lowered plasma PRL levels in those stressed rats but abolished also the stimulatory action of TRH. This effect was further studied by superfusion experiments on enriched PRL cell suspensions (70% lactotrophs) from female adult Wistar rats. Naloxone kept unaffected the basal PRL secretion but lowered significantly that induced by TRH. These experiments suggest a dual effect of naloxone on rat PRL secretion, one exerted on central opioid receptors lowering stress-related increased basal PRL levels, the other inhibiting the TRH-dependent PRL secretion exerted at the lactotroph level itself.     

TRH: Cardiovascular and sympathetic modulation in brain nuclei of the rat

The cardiovascular and sympathetic effects of TRH in discrete cardiovascular-related brain nuclei were studied. Microinjections of TRH were made into the nucleus preopticus medialis (POM) of conscious rats and the nucleus tractus solitarius (NTS) of pentobarbitone-anesthetized, artificially respired rats. POM injections (1 μl, 0.8–80 nM) elicited dose dependent pressor and tachycardic responses which were accompanied by increased levels of norepinephrine (NE) and epinephrine (EPI) in the plasma. These pressor/tachycardic effects of TRH were also elicited in adrenal demedullated (ADM-x) rats, but completely abolished in ADM-x rats pretreated with bretylium (30 mg/kg, IA). NTS injections (0.1 μl, 30 and 150 nM) had a short depressor effect on blood pressure (BP) and a delayed increase in heart rate (HR). From these findings we suggest that the POM, a central nucleus in the AV3V region, may be an important forebrain site for autonomic regulation by TRH, mediated through the sympathetic nervous system.     

Characterization of an in vitro method for demonstrating thyrotropin-releasing hormone-stimulated prolactin secretion.

Anterior pituitaries of normal adult male rats were subjected to synthetic thyrotropin-releasing hormone (TRH) treatment in an acute incubation system which employed pretreatment of the glands with plasma obtained from the donor animals. Following a 60-min preincubation period in a 1:1 mixture of Krebs-Ringer bicarbonate buffer (KRB) and plasma, media and hemipituitary prolactin (PRL) concentrations were significantly (p less than 0.01) increased after a 40-min treatment with 500 pg TRH. The TRH effect was absent among hemipituitaries preincubated in KRB alone. Plasma obtained from older donors was more potent than was plasma from younger rats in this effect. TSH secretion was markedly increased by 500 pg TRH, whether or not plasma preincubation was employed. A dose response of PRL release to concentrations of TRH from 100 pg to 6.0 ng was observed. Crude extracts of median eminence also effected enhanced PRL release using the plasma preincubation technique. The results suggest that plasma preincubation of explanted pituitaries increases PRL cell sensitivity to TRH, perhaps by enzymatic inactivation of endogenous TRH bound to cellular membrane receptors.     

Evidence for a rapid in vivo effect on estradiol-17 beta on prolactin secretion in ovariectomized rats.

Repeated intraarterial injections of synthetic thryrotropin releasing hormone (TRH, 1 microgram/rat) increased plasma prolactin levels 4 hours after a single subcutaneous injection of 10 micrograms estradiol-17 beta (E2-17 beta) in rats ovariectomized 1, 2 or 4 weeks and at 2 hours after E2-17 beta injection in rats ovariectomized for 6 weeks. The effect of TRH was still present at 24 but not 48 hours after estradiol treatment. TRH-induced increases in plasma prolactin were similar in groups of rats treated with 10 micrograms E2-17 beta (s.c.) or implanted with 0.5 cm Silastic capsules of crystalline E2-17 beta (s.c.) whereas smaller, yet significant, TRH-induced increases in plasma prolactin were observed in rats injected s.c. with 1.0 microgram E2-17 beta. Single intraarterial injections of TRH at 4 or 8 hours after E2-17 beta treatment induced increases in plasma prolactin similar in magnitude to those observed at the same times after E2-17 beta in rats given repeated TRH injections. No effect of TRH was observed in ovariectomized rats given sesame oil and E2-17 beta treatment did not influence plasma prolactin in rats given saline instead of TRH. Intraarterial administration of serotonin creatinine sulfate (5-HT, 10 mg/kg body weight) induced marked increases in plasma prolactin in rats ovariectomized for 4 weeks which were potentiated at 2 and 6 hours after E2-17 beta (10 micrograms) treatment. The data show that estradiol has a fairly rapid stimulatory effect on plasma levels of prolactin induced by two different secretagogues but the exact site and mechanism of action remain unresolved.     

Increase of thyrotropin response to thyrotropin-releasing hormone (TRH) and TRH release in rats during pregnancy

Regulation of thyrotropin (TSH) release by thyrotropin releasing hormone (TRH) in the anterior pituitary gland (AP) of pregnant rats was studied. The pregnant (day 7, 14, and 21) and diestrous rats were decapitated. AP was divided into 2 halves, and then incubated with Locke's solution at 37 degrees C for 30 min following a preincubation. After replacing with media, APs were incubated with Locke's solution containing 0, or 10 nM TRH for 30 min. Both basal and TRH-stimulated media were collected at the end of incubation. Medial basal hypothalamus (MBH) was incubated with Locke's medium at 37 degrees C for 30 min. Concentrations of TSH in medium and plasma samples as well as the cyclic 3':5' adenosine monophosphate (cAMP) content in APs and the levels of TRH in MBH medium were measured by radioimmunoassay. The levels of plasma TSH were higher in pregnant rats of day 21 than in diestrous rats. The spontaneous release of TSH in vitro was unaltered by pregnancy. TRH increased the release of TSH by AP, which was higher in pregnant than in diestrous rats. Maternal serum concentration of total T3 was decreased during the pregnancy. The basal release of hypothalamic TRH in vitro was greater in late pregnant rats than in diestrous rats. After TRH stimulation, the increase of the content of pituitary cAMP was greater in late pregnant rats than in diestrus animals. These results suggest that the greater secretion of TSH in pregnant rats is in part due to an increase of spontaneous release of TRH by MBH and a decrease of plasma thyroid hormones. Moreover, the higher level of plasma TSH in rats during late pregnancy is associated with the greater response of pituitary cAMP and TSH to TRH.     

Central hormonal replacement and home-cage dominance in castrated rats

The effect of central placement of gonadal hormones on reinstating home-cage dominance behaviors in castrated rats was studied. Following the placement of testosterone or estradiol into the preoptic area of castrated rats, some dominance behaviors were reinstated to precastration levels, while neither hormone implants into the septum nor cholesterol implants into either the preoptic or septal areas produced any reliable effects.