Identification and immunocytochemical localization of a new thyrotropin-releasing hormone precursor in rat brain

Identification of urocortin 3 afferent projection to the ventromedial nucleus of the hypothalamus in rat brain

Urocortin 3 (Ucn 3) is a corticotrophin-releasing factor related neuropeptide highly expressed in the brain. Ucn 3 nerve fibers heavily innervate the hypothalamic ventromedial nucleus (VMH), and Ucn 3 injection into the VMH suppresses feeding. Currently, the origin of the Ucn 3 afferent input into the VMH is unknown. In the present study, anatomical tracing shows that the major Ucn 3 afferent input to the VMH resides in the anterior parvicellular part of the paraventricular nucleus of the hypothalamus (PVHap) and the adjacent posterior part of the bed nucleus of stria terminalis (pBNST). VMH also receives moderate Ucn 3 input from the medial amygdala. Ucn 3 neurons located immediately caudal to the PVHap/pBNST in the rostral perifornical hypothalamic area (rPFH) provide only minimal input. The paucity of rPFH-VMH Ucn 3 projection is consistent with the finding that only Ucn 3 neurons in the rPFH co-expressed enkephalin (Enk), and Ucn 3/Enk double-labeled nerve fibers and terminals were observed predominately in the lateral septum (LS), whereas only a few double-labeled fibers were found in other brain areas including the VMH. Furthermore, retrograde tracing demonstrates that Ucn 3 neurons in the rPFH project to the LS. In conclusion, the present study determines that the major Ucn 3 afferent into the VMH originates from the PVHap/pBNST. Moreover, anatomical heterogeneity is observed in the hypothalamic Ucn 3 neuron population as the rostral part (PVHap/pBNST) of the population projects to the VMH and the caudal part (rPFH) co-localizes with Enk and provides major afferent input to the LS.

Monosynaptic pathway between the arcuate nucleus expressing glial type II iodothyronine 5'-deiodinase mRNA and the median eminence-projective TRH cells of the rat paraventricular nucleus

Recent evidence suggests that the thyroid regulation of thyrotropin-releasing hormone (TRH)-containing neurons in the paraventricular nucleus of the hypothalamus involves the activation of other hypothalamic neural circuits. For example, the arcuate nucleus and not the paraventricular nucleus contains the highest enzyme activity of 5'-deiodinase type II, an enzyme that is pivotal for the local synthesis of T3. This experiment was undertaken to demonstrate whether a monosynaptic pathway exists between the arcuate nucleus and those TRH cells of the paraventricular nucleus that are neuroendocrine, i.e. project to the external layer of the median eminence. A specific cRNA probe derived from the coding region of deiodinase type II was used for the in situ hybridization histochemistry which was combined with immunocytochemistry for a specific marker of glial cells, glial fibrillary acidic protein (GFAP). The hybridization signals were present within the hypothalamus in the arcuate nucleus-median eminence region and in the periventricular area. The periventricular labeling was localized to the ependymal layer of the third ventricle and no hybridization product was detected in the paraventricular nucleus and other hypothalamic nuclei adjacent to the third ventricle. Within the median eminence, numerous cells containing the hybridization product were located in the internal layer adjacent to the floor of the third ventricle and in the external layer adjacent to the surface of the brain. In the dorso- and ventromedial regions of the arcuate nucleus, deiodinase type II mRNA-containing cells were also detected. Numerous type II deiodinase mRNA-containing cells in the median eminence and arcuate nucleus were also found to be immunopositive for GFAP. The abundance of arcuate cells expressing the hybridization product was lower than those in the periventricular region or in the median eminence. The anterograde tracer, Phaseolus vulgaris leucoagglutinin, was injected into the medial parts of the arcuate nucleus where the in situ hybridization experiment detected deiodinase type II mRNA. Simultaneously with the anterograde tracing, the retrograde tracer, Fluoro-Gold, was injected into either the median eminence or the general circulation. Light and electron microscopic double and triple immunolabeling experiments on vibratome sections of colchicine-pretreated animals revealed that arcuate fibers innervate TRH cells within the parvicellular region of the paraventricular nucleus. Populations of these TRH cells receiving afferents from the arcuate nucleus were also retrogradely labelled from either the median eminence or the general circulation indicating their direct role in the regulation of thyrotropin secretion from the anterior pituitary. The majority of arcuate nucleus efferents on TRH cells were found to establish symmetrical synaptic connections. The present results provided direct evidence of a monosynaptic pathway between the hypothalamic site of local thyroid hormone production, the arcuate nucleus, and neuroendocrine TRH cells in the paraventricular nucleus. This signalling modality may play an important role in thyroid feedback on TRH cells. Since the arcuate nucleus is involved in the regulation of central mechanisms controlling diverse homeostatic functions, including reproduction and feeding, the pathway described in this study may also carry integrated signals related to reproduction and ingestion to TRH-producing cells.

Increases in thyrotropin-releasing hormone messenger RNA expression induced by a model of human temporal lobe epilepsy: effect of partial and complete kindling

Thyrotropin-releasing hormone and its receptor are differentially distributed throughout the limbic forebrain. In addition to its neuroendocrine function, several non-endocrine central nervous system effects of thyrotropin-releasing hormone and its analogs have been reported, including anticonvulsant effects in animals and humans. Kindling, as a model of temporal lobe epilepsy, produces elevations of endogenous thyrotropin-releasing hormone specifically in seizure-prone limbic regions. The present study used semi-quantitative in situ hybridization to characterize changes in thyrotropin-releasing hormone messenger RNA that occurred during the kindling process (partial kindling), as well as after fully kindled seizures. No significant change in thyrotropin-releasing hormone messenger RNA was detected 1 h postictally, whereas significant elevations were detected in the granule cell layer of the hippocampal dentate gyrus, diffuse nuclei of the amygdala and in layers II and III of piriform and entorhinal cortices from 3 to 48 h after a single generalized seizure in fully kindled rats. Peak messenger RNA expression occurred from 6 to 12 h postictally, with a decline at 24 h, followed by a precipitous return to undetectable levels by 48 h, except in the dentate gyrus. In marked contrast, partial kindling produced no detectable change in thyrotropin-releasing hormone messenger RNA by 6 h after the first occurrence of stage 1-5 seizures. Electrode placement, a single afterdischarge, or a 20-microA stimulation of the amygdala was not associated with accumulation of thyrotropin-releasing hormone messenger RNA. Thus, only full kindled generalized seizures increased thyrotropin-releasing hormone messenger RNA expression in identical limbic regions which also showed postictal elevations in thyrotropin-releasing hormone. However, this enhancement followed a more immediate and shorter lasting time-course than previously demonstrated increases in the tripeptide. These results support the hypothesis that thyrotropin-releasing hormone is an important neuromodulator in epileptic foci.

Changes in thyrotropin-releasing hormone levels in hippocampal subregions induced by a model of human temporal lobe epilepsy: effect of partial and complete kindling

Endogenous thyrotropin-releasing hormone has been hypothesized to modulate seizure activity, possibly by subserving an anticonvulsant function in limbic brain. A specific and sensitive radioimmunoassay was utilized to quantitate thyrotropin-releasing hormone levels in dorsoventrally dissected hippocampal subregions after partially (an experimental paradigm of complex partial epilepsy) or fully kindled (repeated generalized) seizures, to define specific seizure-related limbic pathways that may contain thyrotropin-releasing hormone. Samples were taken from electrode controls and 1, 6, 24, 48 and 144 h after a fully kindled seizure or 24 h after the first occurrence of a stage 3-4 (partially kindled) seizure in rats. Thyrotropin-releasing hormone levels were below controls in all subregions taken 1 h after a fully kindled seizure. They resembled control values 6 h after seizure, were substantially elevated at 24 and 48 h, and then returned to control levels by 144h. Low thyrotropin-releasing hormone levels seen shortly after the seizure presumably indicate peptide depletion during the ictus. The higher levels seen at later times occurred during a postictal period coinciding with refraction to additional seizure-generating stimulation. These values probably reflect enhanced synthesis since the largest increases were seen in subregions (dentate gyrus, hilus/CA4, CA3) that contain perforant path terminals, and where previously observed intrinsic hippocampal thyrotropin-releasing hormone messenger RNA increases were seen. The thyrotropin-releasing hormone response was less robust in ventral hilus/CA4 and CA3 areas, leading to speculation that this smaller response could, in part, explain why the ventral (temporal) hippocampus may be more susceptible to seizure-induced damage. No changes in thyrotropin-releasing hormone were detected after partially kindled seizures, suggesting that thyrotropin-releasing hormone is not involved in epileptogenesis or its stereotypic motor behavior. The time-course and distribution of thyrotropin-releasing hormone elevations seen after a fully kindled (repeated generalized) seizure, and the lack of effect of partial kindling (complex partial seizure) are consistent with previous observations concerning postictal thyrotropin-releasing hormone messenger RNA expression. These neurochemical results support the hypothesis that endogenous thyrotropin-releasing hormone can serve an anticonvulsant neuromodulatory function in specific limbic pathways relevant to temporal lobe epilepsy.

Immunohistochemical mapping of neuropeptides in the premamillary region of the hypothalamus in rats

The topographical distribution of neuropeptide-containing cell bodies, fibers and terminals was studied in the premamillary region of the rat hypothalamus using light microscopic immunohistochemistry. Alternate coronal sections through the posterior third of the hypothalamus of normal and colchicine-treated male rats were immunostained for 19 different neuropeptides and their distributions were mapped throughout the following structures: the ventral and dorsal premamillary, the supramamillary, the tuberomamillary and the posterior hypothalamic nuclei, as well as the premamillary portion of the arcuate nucleus and the postinfundibular median eminence. Seventeen of the investigated neuropeptides were present in neuronal perikarya, nerve fibers and terminals while the gonadotropin associated peptide and vasopressin occurred only in fibers and terminals. Growth hormone-releasing hormone-, somatostatin-, alpha-melanocyte stimulating hormone-, adrenocorticotropin-, beta-endorphin- and neuropeptide Y-immunoreactive neurons were seen exclusively in the premamillary portion of the arcuate nucleus. Thyrotropin-releasing hormone-, dynorphin A- and galanin-containing neurons were distributed mainly in the arcuate and the tuberomamillary nuclei. A high number of methionine- and leucine-enkephalin-immunoreactive cells were detected in the arcuate and dorsal premamillary nuclei, as well as in the area ventrolateral to the fornix. Substance P-immunoreactive perikarya were present in very high number within the entire region, in particular in the ventral and dorsal premamillary nuclei. Cell bodies labelled with cholecystokinin- and calcitonin gene-related peptide antisera were found predominantly in the supramamillary and the terete nuclei, respectively. Corticotropin-releasing hormone-, vasoactive intestinal polypeptide- and neurotensin-immunoreactive neurons were scattered randomly in low number, mostly in the arcuate and the ventral and dorsal premamillary nuclei. Peptidergic fibers were distributed unevenly throughout the whole region, with each peptide showing an individual distribution pattern. The highest density of immunoreactive fibers was presented in the ventral half of the region including the arcuate, the ventral premamillary and the tuberomamillary nuclei. The supramamillary nucleus showed moderately dense fiber networks, while the dorsal premamillary and the posterior hypothalamic nuclei were poor in peptidergic fibers.

Thyrotropin-releasing hormone release is enhanced in hippocampal slices after electroconvulsive shock

Hippocampal thyrotropin-releasing hormone (TRH) release was examined after seizures were induced by electroconvulsive shock (ECS). Rat hippocampal slices taken 12, 24, or 48 h after 3 days of alternate-day ECS treatment or sham-ECS treatment were stimulated with potassium with or without calcium in a superfusion system containing in-line charcoal adsorbent to concentrate TRH. Released TRH and tissue TRH were measured by radioimmunoassay. The TRH content of hippocampal slices was increased fivefold over sham-ECS levels 12, 24, and 48 h after ECS, but this was not associated with an increase in basal TRH release. Potassium-stimulated TRH release was significantly elevated over basal release 12, 24, and 48 h after ECS. Potassium-stimulated calcium-dependent TRH release increased linearly after ECS, reaching its highest level 48 h after seizure. Thus, although enhanced calcium-dependent TRH release was associated with elevated tissue levels, this relationship was not proportional in that tissue TRH was elevated to the same extent at all times after ECS, whereas potassium-evoked calcium-dependent TRH release increased gradually over time after seizure. These results suggest that postictal elevations in TRH are associated with an enhanced capacity for release that develops as a result of a time-dependent shift of TRH from a storage compartment ot a readily releasable pool. The observed elevation in stimulated TRH release may be relevant to seizure-induced modulation of TRH receptors in vivo.

Modulation of the biological activity of thyrotropin-releasing hormone by alternate processing of pro-TRH

Thyrotropin-releasing hormone prohormone contains multiple copies of TRH linked together by connecting sequences. Like other plurifunctional prohormone proteins, pro-TRH undergoes differential proteolytic processing in various tissues to generate, beside authentic TRH, several other novel peptides corresponding to C-terminally extended forms of TRH and connecting fragments. The pro-TRH connecting peptides are, together with TRH, predominant storage forms of TRH-precursor related peptides in the rat hypothalamus. Connecting peptides are co-localized with TRH in the median eminence nerve endings and co-released through a mechanism involving voltage-operated Ca2+ channels. The connecting peptide Ps4 is involved in potentiation of the action of TRH on thyrotropin hormone release by pituitary in vitro and in vivo through interactions with a specific pituitary cell receptor coupled to dihydropyridine and omega-connotoxin sensitive Ca2+ channels of the L-type. It also causes dose-dependent increases in the steady state levels of mRNAs of TSH and prolactin through stimulation of the respective gene promoter activities. These findings indicate that Ps4 and TRH, two peptides which originate from a single multifunctional biosynthetic precursor, can function on the same target tissues in a coordinate manner to promote hormonal secretion. This suggests that differential processing of the TRH prohormone may have the potential to modulate the biological activities of TRH.

Neuroendocrine regulation of thyrotropin-releasing hormone (TRH) in the tuberoinfundibular system

[...] It is now required to list each part needed for mucous excretion. They are two ducts in the brain substance, then a thin portion of membrane shaped as the infundibulum, then the gland that receives the tip of this infundibulum and the ducts that drive the mucus (pituita) from this gland to the palate and nares. [...] and I said that one (duct) [...] from the middle of the common cavity (third ventricle) descends [...] into the brain substance, and the end of this duct is [...] the sinus of the gland where the brain mucus is collected [...].

Distribution of thyrotrophin-releasing hormone receptor messenger RNA in rat pituitary and brain

The distribution sites of messenger RNA encoding for the thyrotrophin-releasing hormone receptor have been studied in rat pituitary and brain. A specific 35S-labelled riboprobe generated from a rat thyrotrophin-releasing hormone receptor complementary DNA clone was used to perform in situ hybridization experiments on brain and pituitary sections. A positive hybridization signal was found in the anterior lobe of the pituitary gland, the intermediate and posterior lobes were negative. Hybridization was also detected in different areas of the brain. These areas include distinct regions in the olfactory system, septal area, amygdaloid complex, cerebral cortex, hypothalamus, hippocampus, basal ganglia and the motor nuclei of cranial nerves in brainstem. This study has shown for the first time the exact site of thyrotrophin-releasing hormone receptor expression in the central nervous system. These results correlate well with regions thought to possess thyrotrophin-releasing hormone recognition sites.

Thyrotropin-releasing hormone gene expression and receptors are differentially modified in limbic foci by seizures

Previous studies using two seizure paradigms, electroconvulsive shock and kindling, suggested potential sites of endogenous thyrotropin-releasing hormone (TRH) action in specific epileptogenic areas. We studied TRH gene expression and TRH receptors in rat limbic areas using the kindling model of epilepsy. Immunoassayable TRH increased 4- to 20-fold over control levels in specific subregions of the hippocampus 24 hours after a single stage 5 seizure. Concurrently, TRH receptor binding was significantly reduced in hippocampal (23-39%) and amygdaloid (21-22%) membranes. Dramatic temporal and spatial changes in prepro-TRH messenger RNA were visualized by in situ hybridization histochemistry in the hippocampal dentate gyrus, the piriform cortex, and the amygdala. Peak hybridization occurred 6 and 12 hours postictally in these loci and returned toward basal levels by 24 hours. These results are consistent with the hypothesis that TRH may have an important role in the pathophysiology epilepsy by modulating excitatory processes.

Septal TRH in alcohol-naive P and NP rats and following alcohol challenge

Regional brain content of TRH was evaluated in selectively bred alcohol-preferring (P) and -nonpreferring (NP) rats before, during, and upon awakening from ethanol sedation. TRH content was significantly lower in both the medial and lateral septum of alcohol-naive P rats compared with alcohol-naive NP rats. Following a sedating dose of ethanol, P rats righted themselves sooner than NP rats. TRH content in the medial septum of P and NP rats was significantly higher when the rats regained their righting reflex. While sedated, TRH in the medial septum of P rats was insignificantly increased. These data are the first to show that endogenous TRH in the medial septum may be involved in arousal from drug-induced sedation and that the events preceding arousal may occur sooner in P than in NP rats. In addition, innate differences in septal TRH may be associated with preference for ethanol.

Thyrotropin-releasing hormone analog injected into the raphe pallidus and obscurus increases gastric contractility in rats

The present study was performed to investigate the influence of the chemical stimulation of medullary raphe nuclei by the stable TRH (thyrotropin-releasing hormone) analog, RX 77368, on gastric contractility. Urethane-anesthetized rats were acutely implanted with miniature strain gauge force transducers on the corpus of the stomach for continuous recording of gastric contractility. Traces were analyzed by computer. Microinjections of vehicle or RX 77368 into the raphe pallidus or raphe obscurus were performed using pressure injection of 50 nl through glass micropipettes 30 min following basal recording of gastric contractility. RX 77368 (0.7-77 pmol) dose dependently stimulated gastric contractility when microinjected into the raphe pallidus and raphe obscurus. The stimulation of gastric contractions induced by microinjection of RX 77368 (77 pmol) into these raphe nuclei was completely blocked by vagotomy and prevented (raphe obscurus) or reduced (raphe pallidus) by atropine. RX 77368 (7.7-77 pmol) microinjected into the inferior olive, pyramidal tract, medial lemiscus was ineffective. These results demonstrate that chemical stimulation of the raphe pallidus and obscurus by RX 77368 stimulates gastric contractility through vagal and muscarinic pathways. These data suggest a role for medullary raphe nuclei in the central vagal regulation of gastric contractility.

Immunoreactive thyroliberin (TRH) precursor forms in human hypothalamus and anterior pituitary tissues

Immunoreactive (IR) proTRH forms were characterized in human hypothalamic tissue with two antisera raised against a hepta- and a decapeptide containing the TRH progenitor sequence (-Gln-His-Pro-Gly-). A similar study was performed in human normal and adenomatous anterior pituitaries, tissues in which TRH synthesis has been previously suggested. IR-proTRH was found in all the samples ranging from 42-775 fmol/mg proteins. Size exclusion chromatography identified a major 25-35 kDa form and a minor 4-8 kDa form. The existence of the major form was confirmed by immunoblotting. The results suggest that both human hypothalamic and normal or adenomatous anterior pituitary tissues synthesize similar IR-proTRH forms.

Processing of TRH precursor peptides in rat brain and pituitary is zinc dependent

The enzymes responsible for the posttranslational processing of precursor proteins to form alpha-amidated peptide hormones require the availability of several cofactors, including zinc, copper and ascorbate ions. Major changes in the availability of these cofactors, as well as the rate of hormone precursor conversion to active hormone, occur during neonatal development, aging and caloric restriction. The effects of 6 weeks of a zinc-deficient (ZD1) diet, pair feeding (PF) and partial zinc deficiency (ZD6) compared to a control diet on the enzymatic cleavage and processing of prepro-TRH to form TRH have been studied in the hypothalamus, brain, and pituitary of young adult male Sprague-Dawley rats. Reverse phase high pressure liquid chromatography (HPLC) revealed that TRH was the major TRH-IR component of the hypothalamus, brain and pituitary. The effect of zinc deficiency on the TRH-Gly-IR HPLC profile of rat brain was to reduce selectively the are of the peaks for TRH-Gly and other low molecular weight pro-TRH peptide fragments with a C-terminal Gly compared to the corresponding TRH-Gly-IR peaks of the control group. We conclude that the processing of prepro-TRH to form TRH is zinc dependent via posttranslational processing enzymes such as carboxypeptidase H.

Hypophysiotrophic TRH-producing neurons identified by combining immunohistochemistry for pro-TRH and retrograde tracing

To determine hypophysiotrophic thyrotropin-releasing hormone (TRH)-producing neurons in the rat hypothalamus, we employed a combination of the immunohistochemistry for TRH prohormone (pro-TRH) and the retrograde tracing of neurons that project to the median eminence (ME) by injecting biotinylated wheat germ agglutinin (WGA) into the ME. In intact rats, immunoreactive pro-TRH-positive neurons occurred in the parvicellular paraventricular nucleus (parvi-PVN), basal part of the anterior and lateral hypothalamus, perifornical area and dorsomedial nucleus, especially accumulating in the parvi-PVN. Twenty-four hours after injection of the WGA into the middle portion of the ME, we found neurons that incorporated the lectin in the anterior periventricular area, the PVN, and the arcuate nucleus. When we examined serial sections consecutively stained with anti-WGA, anti-pro-TRH, and anti-WGA, most of the pro-TRH-labeled neurons in the medial parvi-PVN and a part of the neurons in the anterior periventricular area and in the anterior, lateral, and dorsal parvi-PVN appeared to incorporate WGA. These neurons may correspond with the hypophysiotrophic TRH-synthesizing neurons in the rat hypothalamus.

Co-localization of enkephalin and TRH in perifornical neurons of the rat hypothalamus that project to the lateral septum

Neurons of the lateral septal nucleus are surrounded by terminals immunoreactive for thyrotropin-releasing hormone (TRH) and enkephalin (Enk). Retrograde labeling from the lateral septum in combination with immunocytochemical analyses for Enk and TRH in colchicine-treated rats has revealed that nearly all Enk- (and TRH-) containing perifornical neurons project to the lateral septum. Immunostaining of adjacent, thin paraffin sections for either TRH or Enk and double staining of thick vibratome sections for the two peptides have shown that TRH and Enk immunoreactivities co-exist within the same neurons in the perifornical region of the hypothalamus.

Similar high molecular weight forms of growth hormone-releasing hormone are found in rat brain and testis

We have utilized a new radioimmunoassay for rat growth hormone-releasing hormone (GHRH) to investigate the presence of GHRH in different organ systems of adult rat, and specifically the rat central nervous system (CNS). The highest concentration of GHRH was found, as expected, in the hypothalamus, but significant amounts were also located in the brain cortex, predominantly the frontal cortex, as well as in the testis. Smaller amounts were identified in the cerebellum and brain stem. Sephadex and reversed phase high performance liquid chromatography demonstrated that while hypothalamic GHRH exclusively eluted at the position of rat GHRH (1-43), in testis and brain the major form was predominantly (testis) or wholly (brain) of a higher molecular weight. While this molecular species has yet to be further characterized, the data suggest the similar GHRH-like species exist in the CNS as well as the testis.

Enzyme immunoassays for thyroliberin (TRH) and TRH-elongated peptides in mouse and rat hypothalamus

Enzyme immunoassays (EIAs) for Thyroliberin (TRH) and TRH-elongated peptides were developed. Three haptens less than E-H-P-NH2 (TRH). Less than E-H-P-OH (TRH-OH), and S-K-R-Q-H-P-G-K-R-F (P10) were conjugated by the use of different heterobifunctional cross-linking agents either to sun-flower globulin as carrier or to acetylcholinesterase as tracer. For a same hapten, the same chemical group in the peptide was used to prepare the immunogen and the enzyme conjugate. These EIAs were performed with a second antibody solid phase technique using acetylcholinesterase as label. They permitted the measurement of TRH and TRH-elongated peptides with a sensitivity threshold of 10 fmol/well for TRH and 2 fmol/well for P10. TRH EIA only detected authentic TRH whereas TRH-OH EIA detected TRH and TRH peptides elongated on C terminal part. Anti-P10 serum was specific of TRH peptides elongated both on C and N terminal parts and no cross reactivity was observed with TRH. Using these assays, TRH and TRH-elongated peptides were determined in crude or chromatographed mouse and rat hypothalamus tissular extracts. Several TRH extended forms were identified by P10 EIA, whereas TRH-OH EIA permitted detection of both TRH and TRH-elongated peptides in chromatographed extracts. Authentic TRH was measured by TRH EIA both in crude and chromatographed hypothalamic extracts. These assays can permit the study of the processing and maturation of TRH.

Microinjection of TRH analogs into the raphe pallidus stimulates gastric acid secretion in the rat

The effects of microinjection of the stable thyrotropin-releasing hormone (TRH) analog, RX 77368, [pGlu-His-(3,3'-dimethyl)-Pro-NH2] into the raphe pallidus on gastric acid secretion were studied in urethane-anesthetized rats with gastric fistula. RX 77368 microinjected into the raphe pallidus at doses of 0.07, 0.7 and 7.7 pmol induced a dose-dependent net stimulation of gastric acid secretion (7 +/- 4, 50 +/- 7 and 61 +/- 12 mumol/h respectively). The peak acid response was reached within 30 min and returned to basal level 90 min post-injection. The stimulatory effect was abolished by bilateral cervical vagotomy and pirenzepine pretreatment (1 mg/kg, i.v.). RX 77368 (7.7 pmol) microinjected into the inferior olive or pyramidal tract induced smaller or no gastric acid secretory response. These results demonstrate that chemical stimulation of the raphe pallidus increases gastric acid secretion through vagal pathways and peripheral muscarinic receptors. These data suggest that the nucleus raphe pallidus may be involved in vagal modulation of gastric acid secretion in the rat.

In-vitro production of precursor peptides for thyrotropin-releasing hormone by human semen

Thyrotrophin-releasing hormone (TRH) and related peptides occur in high concentrations in human semen. TRH derives from a 242-amino acid precursor protein, prepro-TRH, with six repetitive sequences of -Lys-Arg-Gln-His-Pro-Gly-Lys/Arg)-Arg- connected by hydrophobic linking sequences. Antibodies to TRH-Gly (pGlu-His-Pro-Gly), a final precursor for TRH formation, were used to detect this tetrapeptide as well as other prepro-TRH fragments which cross-react with these antibodies. The total TRH-Gly immunoreactivity decreased significantly after vasectomy. The TRH-Gly immunoreactivity in semen increased significantly during in-vitro incubation at 0 or 37 degrees C, to a peak value at 5 h, followed by an exponential decline, with t 1/2 equal to 11 h at 37 degrees C. At 60 degrees C, however, the TRH-Gly immunoreactivity rose continuously, attaining, after 20 h, a level 2.2 times that at the start of the incubation (P less than 0.001). Reversed-phase high pressure liquid chromatography (HPLC) revealed both hydrophobic and hydrophilic TRH-Gly immunoreactive peptides in semen with both classes of peptides increasing significantly with heating to 60 degrees C. Cation exchange chromatography of pooled human semen incubated at 60 degrees C revealed a 4.3-fold increase in a TRH-Gly immunoreactive peak which co-eluted with synthetic TRH-Gly, and a 30% increase in another TRH-Gly immunoreactive peak identified as Glu-His-Pro-Gly. A minor, TRH-Gly immunoreactive peak increased 50-fold (P less than 0.001) during 20 h at 60 degrees C. This material co-eluted with Arg-Gln-His-Pro-Gly which is formed by enzymic cleavage of the paired basic residues flanking this sequence in prepro-TRH. When synthetic Arg-Gln-His-Pro-Gly was incubated with fresh semen at 60 degrees C a rapid conversion of most of this peptide to Glu-His-Pro-Gly, Gln-His-Pro-Gly and TRH-Gly occurred within 30 min. These data are consistent with thermal inactivation of the amidation and degrading enzymes at 60 degrees C while the trypsin-like enzymes which cleave the precursor peptide at the paired basic residues remain relatively unaffected. Because other investigators have found the C-terminal amidating enzymes to be associated with secretory vesicles and to be co-secreted with the vesicular contents, we suggest that secretory epithelia of the male reproductive system secrete TRH and TRH-related precursor peptides along with the alpha-amidating enzymes which continue processing of prepro-TRH in the post-ejaculatory seminal fluid.

Molecular biology and regulation of the hypothalamic hormones

Over the past twenty years, each of the five major hypothalamic releasing or release-inhibiting hormones has been sequenced and its gene structure determined. With the use of molecular biological techniques, such as in situ hybridization, Northern blot analysis or gene constructs for in vitro or in vivo transfection studies--together with 'traditional' neuroendocrinological techniques, such as immunocytochemistry, radio-immunoassay and portal vessel cannulation--investigators have been able to address major issues in neuroendocrine regulation. Several common themes have emerged: messenger RNA expression is uniformly present in neurons that are immunopositive for the specific hypothalamic hormone. Steady state RNA levels within the hypophysiotropic neuron groups are either increased or reduced by changes in specific target hormones that conform to predictions based on previous physiological data. Regulation by the requisite peripheral hormone is exquisitely anatomically specific and is not evident in extrahypophysiotropic regions. Determining the receptor or genetic basis of this specificity is a major focus of current research. Clarifying the apparently lesser role of afferent neural pathways to the hypothalamus in regulating releasing hormone mRNA levels is also an important challenge. Clinically, the measurement of levels of releasing hormones in the peripheral circulation appears to be of limited usefulness, except in rare cases of ectopic GRH or CRH secretion. For diagnostic purposes, each of the releasing hormones has specific utility in amplifying the release and measurement of pituitary hormones, both to clarify the overall physiological activity of the hypothalamic-pituitary-target hormone axis and to further define the anatomic locus of any underlying disturbance. The usefulness of somatostatin as a diagnostic tool is presently limited, but the development of SS receptor antagonists might have significant impact in future clinical investigation. The molecular mechanisms of action of the hypothalamic hormones have been separated into those whose receptor-effector function is mediated by the cAMP-adenylate cyclase pathway(s), GRH and CRH, and those working through the phosphoinositide-protein kinase C cascade, GnRH and TRH. Each of the hormone receptors is coupled to intermediary G proteins, somatostatin uniquely to the inhibitory subclass. The mechanisms responsible for sensitization (priming) or desensitization are not fully understood but are presumably related to receptor down regulation and protein phosphorylation.(ABSTRACT TRUNCATED AT 400 WORDS)