GnRH-associated Peptide Research Articles

Characterization and localization of mRNA encoding the salmon-type gonadotrophin-releasing hormone precursor of the masu salmon.

Gonadotrophin-releasing hormone (GnRH) is considered to have an important role in the control of reproduction in salmonid fish, although we do not have any direct evidence. To clarify this problem by molecular techniques, we first determined the nucleotide sequence of the mRNA encoding the precursor of salmon-type GnRH (sGnRH) from the masu salmon, Oncorhynchus masou. The masu salmon sGnRH precursor was composed of a signal peptide, sGnRH and a GnRH-associated peptide (GAP) which was connected to sGnRH by a Gly-Lys-Arg sequence. The amino acid sequence of sGnRH and Gly-Lys-Arg were highly conserved when compared with the corresponding regions of African cichlid sGnRH and mammalian GnRH precursors. However, the GAP region was markedly divergent, with a 66% amino acid similarity to African cichlid GAP and an 8.3-15% similarity to mammalian GAPs. Northern blot analysis indicated the presence of a single mRNA species of about 600 bases in the olfactory bulb and telencephalon and in the diencephalon. The signal was more intense in the former regions. An in-situ hybridization study further revealed that sGnRH neurones were distributed in the olfactory nerve, the ventral part of the olfactory bulb, the ventral part of the telencephalon, the lateral preoptic area and the preoptic nucleus. The sGnRH neurones were thus longitudinally scattered between the olfactory nerve and the lateral preoptic area in the rostroventral part of brain. The intensity of the hybridization signals and the size of hybridization-positive somata were much greater in the olfactory nerve and the rostral olfactory bulb than in the other regions. Preoptic sGnRH neurones were scarcely detected in immature masu salmon, whereas they were more frequently observed in maturing animals. It is possible that the olfactory and the preoptic sGnRH neurones have different physiological roles in salmonid fish.

The Atlantic salmon prepro-gonadotropin releasing hormone gene and mRNA

Screening for the gene encoding salmon gonadotropin releasing hormone (sGnRH) in an Atlantic salmon ( Salmo salar) genomic library resulted in isolation of a positive clone designated λsGnRH-1. An anchor polymerase chain reaction (PCR) technique was used to amplify GnRH cDNA derived from salmon hypothalamic mRNA. The cDNA sequence was aligned to the 7607 base pair genomic sequence which was shown to encode the entire prepro-GnRH gene. The cDNA proved that the cloned gene is expressed in the hypothalamus of mature salmon. The coding domain of sGnRH differs from the mammalian GnRH by six nucleotide changes which allow the two amino acid differences between the two GnRH variants. Salmon GnRH associated peptide (GAP) differs extensively in sequence and size from the mammalian counterpart. Compared to the GnRH cDNA of a cichlid species the similarity is 69.3% in the protein coding sequence.

Inhibition of Prolactin Release by Gonadotropin-Releasing Hormone-Associated Peptide in Benign, Dopamine-Sensitive and in Malignant, Dopamine-Resistant Pituitary Tumors

Since the gonadotropin-releasing hormone-associated peptide (GAP) has been reported to be capable of inhibiting prolactin release from normal lactotrophs, with the present study we have examined the in vitro effects of GAP on prolactin release in an estrone-induced, dopamine-sensitive rat pituitary adenoma and two malignant, transplantable and dopamine-resistant rat pituitary tumors, 7315a and MtTW15. Enzymatically dispersed cells obtained from the three types of tumor were cultured in multiwell dishes for 4 days. On the fifth day, the cells were exposed for 4 h to human GAP 1-56 or to the analog GAP 42-56 or to rat GAP 1-53, at various concentrations. In some experiments, the effect of a pretreatment of the cells for 16 h with pertussis toxin before exposure to human GAP was also evaluated. In the three tissues, rat GAP was able to inhibit prolactin release in a dose-dependent manner. Human GAP 1-56 and GAP 42-56 were able to inhibit prolactin release in a dose-dependent manner in all cells except those of the MtTW15 tumor. Furthermore, in adenomatous cells, the inhibitory effects of these peptides were suppressed by pretreatment of the cells with pertussis toxin. These findings indicate that GAP is capable of inhibiting prolactin release even in dopamine-resistant pituitary tumors. This inhibition is exerted through a pertussis toxin-sensitive G-protein-dependent signaling mechanism in adenomatous cells.

GnRH-associated peptide (GAP) is present in the rat striatum and affects the synthesis and release of dopamine.

A possible interference of the GnRH-associated peptide (GAP) with the metabolism of dopamine in the rat striatum was investigated. The presence of the precursor of the peptide in this central region of dopaminergic terminals was first evidenced using specific RIA. The action of GAP on dopamine release was investigated in the caudate nucleus using the local superfusion with a push-pull cannula supplied with an artificial CSF containing the tritiated precursor of dopamine [( 3H]tyrosine). Addition of GAP (1 microM) to the superfusing fluid resulted in an increase of the release of the newly synthesized dopamine without a significant modification of the total amine release. In situ neutralization of GAP by addition in the CSF of a rabbit serum containing antibodies directed against the GAP produced opposite effects evidencing a tonic function for this peptide. In addition to the increased specific activity of the dopamine released during GAP treatment, the alterations observed in the efflux (and the specific activity) of dihydroxyphenyl acetic acid and the activation of dopamine synthesis obtained in vitro in striatal slices in the presence of GAP led us to conclude that the GAP system could be considered as a positive control of dopamine synthesis.

Immunohistochemical detection of proluteinizing hormone-releasing hormone peptides in neurons in the human hypothalamus.

To determine the presence of LHRH prohormone products in the human hypothalamus, antisera raised against LHRH and GnRH-associated peptide (GAP) were used to search for the presence of the corresponding antigens in the human adult and fetal hypothalamus by an immunohistochemical approach. The comparison of immunostaining on adjacent sections shows that all of the cells labeled with LHRH antiserum are also labeled with GAP antiserum and vice versa. Labeled cells are detectable during the 9th week of fetal life, this being the earliest time evaluated. At this time, the LHRH/GAP-positive cells frequently have a neuroblastic appearance. The first detectable fibers appear during the 11th week, and these were observed in the lamina terminalis cinerea and median eminence. In the adult brain, fibers and endings labeled with LHRH or GAP antiserum in the median eminence demonstrate the same topography and morphological characteristics, which are distinct from fibers labeled with other neuropeptide antisera. These results show that the LHRH precursor molecule is produced throughout life in the human hypothalamus, including the earliest stages of development of the peptidergic neurons. Moreover, the detection of LHRH- and GAP-positive fibers in the median eminence by the 11th week of fetal life suggests the possibility of an early role of LHRH and, possibly, other LHRH prohormone-derived peptides in the development of anterior pituitary function during the fetal period.

Immunocytochemical study of GnRH and GnRH-associated peptide in male Syrian hamsters as a function of photoperiod and gonadal alterations.

Hypothalamic luteinizing-hormone-releasing hormone (GnRH) and gonadotropin-releasing-hormone-associated peptide (GAP) biosynthesis and storage were estimated by immunocytochemistry in male golden hamsters maintained in different photoperiods. Intact or castrated male hamsters with subcutaneously inserted testosterone implants were exposed to long-day (14:10) or short-day photoperiods (10:14) for 4-8 weeks. Exposure to short photoperiod for 4 weeks, an interval characterized by a suppression of gonadotropin secretion but not gonadal regression, was associated with an increase in the number of GnRH- and GAP-immunoreactive cells in the diagonal band of Broca/medial septum. Furthermore, morphometric analysis revealed that these animals displayed significantly more GnRH but not GAP immunoreactivity in the median eminence as opposed to hamsters exposed to long-day photoperiods. In additional studies, gonadally regressed hamsters exposed to short day lengths for 8 weeks had equal numbers of GnRH cells as did the long-day controls. These patterns suggest that reproductive quiescence in golden hamsters is not the result of depletions of neuronal GnRH stores available for secretion.

Morphological Characterization of Immortalized Hypothalamic Neurons Synthesizing Luteinizing Hormone-Releasing Hormone

An immortalized LHRH cell line has recently been developed by genetically targeting these neurons for tumorigenesis. One of the subclones, the GT1-7 cells, was characterized at both the light and electron microscopic levels to study the cellular and subcellular organization of these cells, particularly as they relate to biosynthesis, processing, and secretion. The cells were fixed onto slides 18-36 h after plating. LHRH and GnRH-associated peptide (GAP) immunoreactivities (IR) were detected by immunocytochemistry using colloidal gold labeling. These cultured cells exhibited the classical neuronal appearance of LHRH neurons, and they established numerous interconnections. Neighboring neurons were coupled by tight junctions, while more distant cells were interconnected with neural axon-like processes and collaterals. This cellular organization is suggestive of a neural network where neuronal activity is coordinated. At the ultrastructural level, the nondividing cells possessed indented nuclei, well developed Golgi complexes, and abundant numbers of ribosomes and secretory granules. Clathrin-coated vesicles were found in fusion with the plasma membrane. The ribosomes and secretory vesicles were particularly prominent, suggestive of high rates of protein biosynthesis and secretion. All of the cells immunostained for both LHRH and GAP; however, GAP IR was always more pronounced than that for LHRH. This finding was corroborated by biochemical data reported in a companion paper. The GAP IR was associated with ribosomes and secretory vesicles. By comparison, LHRH IR was restricted mainly to the secretory vesicles. Using colloidal gold particles of different sizes to denote LHRH or GAP IR, it was determined that both GAP and LHRH IR were colocalized within the same secretory vesicle. Taken together, these data suggest that pro-LHRH is biosynthesized on the ribosomes, packaged as an intact protein into the secretory vesicles, processed to LHRH and GAP-(1-56) within these vesicles, and transported to the periphery of the cell in preparation for secretion. These morphological data emphasize the utility of using these immortalized LHRH neuronal cells to dissect the cellular and subcellular architecture involved in biosynthesis, processing, and secretion. In addition, our results provide the first detailed evidence for the intracellular pathway involved in pro-LHRH biosynthesis, processing, and secretion in these cultured neuronal cells.

Metabolism of Pro-Luteinizing Hormone-Releasing Hormone in Immortalized Hypothalamic Neurons*

An immortalized hypothalamic neuronal cell line was recently developed by genetically targeting the expression of the simian virus-40 large T-antigen in LHRH neurons. These GT1 cells were subcloned to GT1-1, GT1-3, and GT1-7 cells, and they have been shown to express the mRNA for pro-LHRH and secrete LHRH-like immunoreactive (IR) materials into the media. The purpose of our study was to biochemically and immunologically characterize the IR materials within and secreted from these cells. Both LHRH- and GnRH-associated peptide (GAP)-like IR materials were present and were secreted from these four cell lines. Up to 3% of the total cellular protein was composed of LHRH and GAP materials. When materials from the cell lysate and media were separated according to mol wt (Mr), at least three different pro-LHRH species were detected. These precursors contained both LHRH- and GAP-like IR determinants, and they eluted in the void volume and at approximately 10,000-12,000 and 8,400-8,500 Mr. A material that contained GAP-like IR eluted at approximately 6,500-6,800 Mr. This species is probably mouse GAP-(1-56) because it eluted on a reverse phase column in the approximate position of rat GAP-(1-56). Cell lysates contained a single LHRH-like IR form which coeluted on a size-exclusion column with synthetic LHRH. This material stimulated secretion of LH from anterior pituitary cells in a dose-response manner. By comparison, two different molecular forms of LHRH were detected in media at approximately 1,500 and 540 Mr. HPLC analyses revealed these peaks to be heterogeneous and to contain at least (Gln1)LHRH-(Gly11,Lys12,Arg13), (Gln1)LHRH-(Gly1,Lys12), LHRH-(Gly11), and LHRH. These experiments demonstrate that the cells contain and secrete multiple molecular forms of the pro-LHRH and that processing of the prohormone must involve 1) cleavage by an endopeptidase to give GAP-(1-56) and a C-terminally extended LHRH, 2) removal of C-terminal basic amino acids by a carboxypeptidase, 3) amidation of LHRH-(Gly11) to LHRH, and 4) cyclization of glutamine to pyroglutamate at the N-terminal of LHRH. These results provide the first evidence for intermediates in the metabolic pathway of pro-LHRH to LHRH.

Postnatal Development of Gonadotropin-Releasing Hormone and Cyclophilin Gene Expression in the Female and Male Rat Brain*

The rat preoptic area-anterior hypothalamic continuum (POA-AH) contains about 400-800 neurons that express the decapeptide GnRH and the 56-amino-acid GnRH-associated peptide. Originating from the olfactory placode, these neurons migrate and establish their final distribution and connections in the POA-AH several days before birth. The aim of the present study was to examine whether the biosynthesis of the mRNA encoding the precursor (proGnRH) common to GnRH and GnRH-associated peptide undergoes postnatal changes corresponding to the development of sexual maturation. The POA-AH content of proGnRH messenger RNA (mRNA) was followed from postnatal day 1 to day 90 in female and male Sprague-Dawley rats killed by decapitation between 1000-1200 h. Cytoplasmic RNA fractionated from individual POA-AH homogenates was purified using proteinase K digestion. Cytoplasmic proGnRH mRNA was quantitated simultaneously with cyclophilin mRNA (an internal standard control) using solution hybridization-RNase protection assay, with the protected fragments separated through polyacrylamide gel electrophoresis. In the POA-AH, the concentrations of proGnRH mRNA (femtograms mRNA per microgram total RNA) increased significantly with age in both sexes (P less than 0.001). In males, proGnRH mRNA levels increased by day 30 some 2-fold over the values of days 5 and 10, and the levels established on day 30 were maintained through adulthood. In females, the first rise in proGnRH mRNA levels occurred on day 30, followed by an additional increase on day 45 to levels seen in adulthood. Levels of proGnRH mRNA established in adulthood were significantly higher in females than in males (P less than 0.03). The concentrations of cyclophilin mRNA (picograms mRNA per microgram total RNA) remained essentially unchanged in both sexes during the same period of time when proGnRH mRNA levels were increasing. These results provide evidence for postnatal sex-related increases in the levels of proGnRH mRNA in the rat POA-AH, which are likely to reflect differential regulation by gonadal steroids.

The Gonadotropin-Releasing Hormone Associated Peptide Reduces Calcium Entry in Prolactin-Secreting Cells*

The precursor molecule to the GnRH contains a peptide named GnRH-associated peptide (GAP) with PRL-inhibiting properties. In this work, we have studied the electrophysiological properties and responses to GAP of three different types of PRL-secreting cells: 1) the rat tumor cell line GH3, 2) normal rat pituitary cells in primary culture, and 3) human PRL-secreting adenoma cells. Using different but complementary techniques we show that GAP reduces intracellular Ca++ levels, [Ca++]i, and inhibits Ca++ transients in these cells. This reduction of [Ca++]i results from coordinate actions of GAP on K+ and Ca++ conductances and may explain the inhibitory effect of GAP on hormonal secretion by PRL-secreting cells.

Selective FSH-releasing activity of [D-Trp 9]GAP 1–13: Comparison with gonadotropin-releasing abilities of analogs of GAP and natural LHRHs

We had previously shown that fragments of human gonadotropin-releasing hormone associated peptide (GAP) stimulated FSH and LH release in vivo. In particular, GAP 1−13 had a preferential FSH-releasing activity. To decrease enzymatic degradation, analogs of GAP 1–13 with D-amino acid substitutions were synthesized. The activities were tested in ovariectomized, estrogen-progesterone primed (OEP) rats and compared with those of GAP 1−13, mammalian (m), chicken II (eII), and lamprey (1) LHRH. The peptides were injected (IV) into conscious, OEP rats and blood samples were obtained via the jugular catheter. [D-Trp 9]GAP 1–13 selectively stimulated FSH release at a dose of 1 μg. Multiple injections of this analog (10 μg every 30 min for 5 injections) induced a marked elevation of plasma FSH values which peaked ( p < 0.001) after the third injection. By contrast, [D-Trp 9]GAP 1–13 had no effect on LH and prolactin (PRL) release after either single or multiple injections. These doses of [DAla 4] GAP 1–13 had no effect on the release of FSH, LH or PRL. Both human GAP 1–13 and its [D-Trp 9] analog exerted a selective FSH-releasing effect at a dose of 10 μg, however, the [D-Trp 9] analog was more potent than GAP 1–13 on FSH release. The potency of [D-Trp 9]GAP 1–13 in releasing FSH was approximately 1 100th that of mLHRH. Chicken II LHRH had slightly selective FSH-releasing activity with a potency 1 10th that of mLHRH. Lamprey LHRH had a preferential LH-releasing activity and a potency 1000 times less than mLHRH. In conclusion, [D-Trp 9]GAP 1–13 is a selective FSH-releasing peptide of potential clinical value.

Gonadotropin-Releasing Hormone-associated Peptide Immunoreactivity in Bovine Colostrum

Gonadotropin-releasing hormone(GnRH)-associated peptide (GAP) is a 56-amino acid peptide found on the C-terminal of the GnRH (also called luteinizing hormone-releasing hormone) precursor and is assumed to be co-produced with GnRH. The purpose of this report is to demonstrate the presence of GAP immunoreactivity in bovine colostrum. Radioimmunoassay of acidified methanolic extracts demonstrated a concentration of GAP immunoreactivity of approximately 1.5 +/- 0.1 pmol/g dry skim bovine colostrum. Gel filtration (Sephadex G-10) and high-performance liquid chromatography of extracts containing GAP immunoreactivity showed it to be of low molecular weight and a high hydrophobic character. The presence of GAP immunoreactivity in bovine colostrum suggests that the GnRH precursor is synthesized and processed in mammary tissue itself.

Immunocytochemical demonstration of GAP-like immunoreactive neuronal elements in the human hypothalamus and pituitary

GnRH-associated peptide (GAP)-like immunonreactive elements located in the human hypothalamus were investigated by PAP immunocytochemistry using specific antiserum against [pro-GnRH (14-69) OH]. Immunoreactive neuronal perikarya were distributed in the MPOA, PVN and infundibular nucleus, with the largest numbers of GAP-like immunoreactive perikarya found in the infundibular nucleus. We also detected the coexistence of GAP-like and GnRH-like immunoreactivities in the same neuronal perikarya in the MPOA by using a double immunolabelling procedure. In addition to the above regions immunoreactive neuronal perikarya were present in the region dorsal to the medial mammillary nucleus. GAP-like immunoreactive fibers were distributed in same areas that immunoreactive perikarya were observed. Many immunoreactive terminals were found adjacent to capillaries in the infundibulum. Immunoreactive dots, presumably terminals, were observed in the posterior pituitary and these were particularly evident along the margin adjacent to the anterior pituitary. The distribution pattern and density of GAP-like immunoreactive neuronal elements are compared with those of other mammalian species. We also compared GAP-like immunoreactive elements with that of GnRH as has been previously observed in the human hypothalamus.

Effects of GnRH-associated peptide and its component peptides on prolactin secretion from the tilapia pituitary in vitro

The rostral pars distalis (RPD), containing mainly prolactin (PRL)-secreting cells, of the pituitary from immature and mature tilapia was incubated for 16 hr at 27° in hypoosmotic medium (300 mOsm/kg) in the presence (10 −8 and 10 −11 M) or absence of the human GnRH-associated peptide (GAP) molecule, a potent PRL-inhibiting factor in mammals (Nikolics et al., Nature ( London) 316, 511, 1985), and of a series of its component peptides. The release of the two forms of PRL in tilapia into the medium was measured by sodium dodecyl sulfate-polyacrylamide gel electrophoresis followed by densitometry. The variability inherent in this method was normalized by calculating PRL release as the percentage of the total hormone present in both tissue and medium. Newly synthesized PRL was detected by incorporation of [ 35S]methionine, introduced into the culture medium, by the PRL molecules. In immature tilapia, GAP inhibited the release of total PRL while stimulating the release of newly synthesized large PRL. Among the GAP fragments tested, 28–36 was the fragment that most significantly affected PRL secretion. Both concentrations of fragment 28–36 stimulated the release of newly synthesized PRL from immature rostral pars distalis (RPDs). This stimulation appears to be dependent on the osmotic pressure of the medium since this fragment did not affect PRL secretion in hyperosmotic medium (340 mOsm/kg). Fragment 38–49 inhibited total PRL release from mature RPDs. Fragment 51–66 stimulated the release of total PRL from mature RPDs. Examination of tissue and medium values in densitometric units after incubation with fragments 28–36 and 51–66 indicated that while the tissue content of PRL was decreased, the medium content of PRL was not affected. This suggests that fragments 28–36 and 51–66, in opposition to the situation found when the data are expressed as percentage release of PRL, may not stimulate PRL release but may instead decrease the tissue content of PRL. These results suggest that the entire human GAP molecule, as well as some of its fragments, may have direct effects on the PRL cells in the tilapia pituitary.

Correlative Changes of the Gonadotropin-Releasing Hormone and Gonadotropin-Releasing-Hormone-Associated Peptide Immunoreactivities in the Pituitary Portal Plasma in Female Rats

The precursor protein of gonadotropin-releasing hormone (GnRH) contains a 56-amino acid peptide, known as GnRH-associated peptide (GAP), and GnRH. Both of these peptides are localized in the same neurons and coprocessed under varieties of physiological conditions. In the present study, we evaluated whether these two peptides are cosecreted into the pituitary portal blood in female rats under the conditions in which the secretion of hypothalamic GnRH and pituitary luteinizing hormone (LH) are known to be altered. The immunoreactivities of GAP-like peptide (IR-GAP-LI) and GnRH (IR-GnRH) in the portal plasma were 2- to 15-fold higher than those observed in peripheral plasma of female rats. In the pubertal females, the preovulatory LH surge which occurred in the afternoon of the day before vaginal opening (puberty) was found to coincide with surges of IR-GAP-LI and IR-GnRH in the pituitary portal plasma. The surges of IR-GAP-LI and IR-GnRH in portal plasma corresponded with a fall in the preoptic and hypothalamic contents of these peptides. In the adult rats, the levels of IR-GAP-LI and IR-GnRH in portal plasma and LH in peripheral plasma were significantly higher during the afternoon of proestrus than those in the afternoon of diestrus. Ovariectomy increased the portal plasma levels of IR-GAP-LI and GnRH and peripheral plasma levels of LH as compared to the level of these hormones in diestrous females. These results indicate that both GnRH and GAP-LI are cosecreted into pituitary portal blood and that changes in the endocrine environment similarly affect both GnRH and GAP secretion.

Role of Substance P in the Medial Preoptic Area in the Regulation of Gonadotropin and Prolactin Secretion in Normal or Orchidectomized Rats

The present studies were designed to evaluate the role of substance P (SP) in the control of the release of luteinizing hormone (LH), follicle stimulating hormone (FSH) and prolactin (PRL). SP was microinjected into the medial preoptic area (MPOA) of conscious, freely moving intact or orchidectomized (ORCX; 21 days post-ORCX) adult male rats. Microinjection of SP into the MPOA induced a significant decrease in plasma LH and FSH concentrations, effects which were accompanied by an elevation in plasma PRL concentration. To examine the participation of endogenously secreted SP in the activity of the MPOA neurons controlling release of these cited pituitary hormones, another study was performed in which either a potent and specific antagonist to SP (D-Pro2, D-Trip7,9-SP; SP-ANT) or an antibody against SP (SP-AB), was injected into the MPOA. SP-ANT and SP-AB both elevated plasma LH, FSH and decreased plasma PRL concentration. These data suggest that endogenous SP within the MPOA exerts an important inhibitory tonus over LH and FSH release and an excitatory tonus over PRL release. In conclusion, SP seems to participate as a neurotransmitter or neuromodulater in the control of LH, FSH and PRL secretion, at least in part, by acting at the level of MPOA, a region in which the neuronal cell bodies that produce LH-releasing hormone and the associated gonadotropin-releasing hormone-associated peptide are located.

Estradiol stimulates preoptic area-anterior hypothalamic proGnRH-GAP gene expression in ovariectomized rats

The decapeptide gonadotropin-releasing hormone (GnRH) and the 56-amino acid GnRH-associated peptide (GAP) are derived from a common precursor translated from the proGnRH-GAP mRNA. Studies using solid-phase hybridization techniques (i.e., Northern blot analysis, dot blot analysis, or in situ hybridization autoradiography) have yielded a controversy as to whether estradiol stimulates, inhibits, or has any effect on proGnRH-GAP gene expression in the preoptic area-anterior hypothalamus (POA-AH) of the ovariectomized (OVX) rat. Using a sensitive and quantitative solution hybridization-nuclease protection assay, which ensures complete hybridization of target RNA to probe RNA, we examined the effects of OVX and estradiol replacement on the amount of proGnRH-GAP mRNA in individual POA-AH dissections. Rats sacrificed at different intervals after OVX showed a significant time-dependent decrease (34–60%) in the levels of POA-AH proGnRH-GAP mRNA relative to sham-operated animals; OVX rats treated with estradiol, however, had proGnRH-GAP mRNA levels comparable to those of sham-OVX animals. To verify these observations, levels of the proGnRH-GAP peptide, measured by radioimmunoassay with antibodies directed against the cleavage and amidation site between the GnRH and the GAP portions of the precursor molecule, were also found to decrease (37%) after OVX and increase (63–85%) following estradiol replacement, relative to intact rats. These data support the view that estradiol stimulates the levels of both proGnRH-GAP mRNA and its primary translation product in the POA-AH region of the OVX rat.

Testosterone Selectively Influences Protein Kinase-CCoupled Secretion of Proluteinizing Hormone-Releasing Hormone-Derived Peptides*

LHRH and GnRH-associated peptide (GAP) are two major pro-LHRH-derived peptides which are secreted from median eminence (ME) nerve terminals in vitro. The purpose of the present experiment was to determine whether manipulation of gonadal steroid levels in vivo influenced selectively the in vitro secretion of LHRH and GAP under basal or K+ and phorbol ester (PDBu) stimulation. Secretion of both peptides under each of these three conditions was reduced at least 2-fold in 2-week orchidectomized (ORDX) rats relative to the level in intact controls. Tissue stores of LHRH and GAP were also depressed in the ME of ORDX relative to control rats. When the data were expressed in terms of the percentage of peptide secreted per ME, both groups secreted similar percentages of the peptides into the medium under basal and K+-stimulated conditions. Interestingly, PDBu-activated secretion of LHRH and GAP remained depressed in ORDX animals. The nerve terminals from ORDX animals were not susceptible to a more rapid depletion of releasable peptides, since both groups secreted similar percentages of the peptides during repeated K+ depolarization. By comparison, protein kinase C (PKC)-coupled secretion from ORDX rats was selectively affected, since secretion of pro-LHRH-derived peptides became even more depressed with successive activation with PDBu. Immediate replacement with testosterone after ORDX fully restored the peptide levels in tissue and the LHRH and GAP secretory response to PKC activation. Since testosterone influenced both tissue stores and PDBu-stimulated secretion of LHRH and GAP, this steroid may selectively regulate biosynthesis and secretion of pro-LHRH-derived peptides through activation of the metabolic cascade involving the PKC system.

Immunocytochemical localization of the gonadotropin-releasing hormone-associated peptide portion of the LHRH precursor in the hypothalamus and extrahypothalamic regions of the rat central nervous system.

The gonadotropin-releasing hormone-associated peptide (GAP) of the LHRH precursor and the decapeptide LHRH were localized in the rat brain by immunocytochemistry in 12- to 18-day-old animals, by use of thick Vibratome sections and nickel intensification of the diaminobenzidine-reaction product. Our results indicate that the GAP portion of the LHRH precursor is present in the same population of neurons that contain LHRH in the rat brain. An important difference observed was that the GAP antiserum, in contrast to LHRH antisera, stained several perikarya in the medial basal hypothalamus. GAP-immunoreactive perikarya were observed in the following regions: the olfactory bulb and tubercle, diagonal band of Broca, medial septum, medial preoptic and suprachiasmatic areas, anterior and lateral hypothalamus, and several regions of the hippocampus. In addition to the preoptico-terminal and the septo-preoptico-infundibular pathways, we also observed GAP-immunopositive processes in several major tracts and areas of the brain, including the amygdala, stria terminals, stria medullaris thalami, fasciculus retroflexus, stria longitudinalis medialis, periventricular plexus, periaqueductal gray of the mesencephalon and extra-cerebral regions, such as the nervus terminalis and its associated ganglion. These results confirm the specificity of previous immunocytochemical results obtained with antisera to LHRH. The presence of GAP immunoreactivity in nerve terminals of the rat brain indicates that GAP or a GAP-like peptide is located in the proper site to serve as a hypophysiotropic substance and/or as a neurotransmitter or neuromodulator.

Relation between luteinizing hormone and prolactin pulses in ovariectomized rats with or without dopamine inhibition.

GnRH and GnRH-associated peptide (GAP) have been shown to be cosecreted as spontaneous pulses in hypophysial portal blood. In addition, GAP has been proposed as a physiological inhibitor of PRL secretion. The present investigation was performed to determine whether GAP might play a role in the moment to moment regulation of PRL release in the ovariectomized rat. We anticipated that an inverse relation might exist between PRL and LH pulses if GAP is a physiological regulator of PRL and is coreleased with GnRH. Serial blood samples were collected at 6-min intervals over 4 h from ovariectomized rats bearing chronic jugular catheters and were analyzed for plasma concentrations of PRL and LH by RIA. Release patterns were assessed using a pulse detection algorithm. Some animals were pretreated 30 min before blood sampling with domperidone (a dopamine antagonist that does not cross the blood-brain barrier) to unmask PRL inhibitory responses to GAP that might not otherwise be observable in the presence of normal dopamine inhibition. PRL secretory patterns were pulsatile but highly irregular, in contrast to the regular rhythmic patterns of circulating LH. Domperidone treatment significantly increased the number of PRL pulses. PRL pulse amplitudes, and mean PRL concentrations compared to those in vehicle-injected controls. LH pulses after domperidone administration were more frequent, resulting in slightly higher mean LH concentrations. In both vehicle- and domperidone-injected rats, 60-80% of PRL pulses were concordant with LH pulses (concordance defined as PRL and LH peaks occurring within one sample of each other). Assuming that GAP is cosecreted with GnRH, these data fail to support an acute physiological role for GAP during undisturbed PRL release in the ovariectomized rat because the expected relation between PRL and LH pulses in the event of such a role was not observed. To test a role for GAP more directly, domperidone-treated rats were injected with a rabbit anti-GAP serum during serial blood collection. No increase in PRL release was elicited by this treatment, and pulsatile PRL and LH secretion were unaffected compared to those in control animals injected with hyperimmune serum. To determine whether GnRH is the PRL-releasing secretagogue responsible for concordant PRL and LH pulses, some rats were pretreated 4 h before blood sampling with a potent GnRH antagonist, followed by domperidone 30 min before sampling. Treatment with GnRH antagonist virtually abolished LH pulses, but had no effect on PRL pulses.(ABSTRACT TRUNCATED AT 400 WORDS)