Mast cells in the rat brain synthesize gonadotropin‐releasing hormone

Mast cells occur in the brain and their number changes with reproductive status. While it has been suggested that brain mast cells contain the mammalian hypothalamic form of gonadotropin‐releasing hormone (GnRH‐I), it is not known whether mast cells synthesize GnRH‐I de novo. In the present study, mast cells in the rat thalamus were immunoreactive to antisera generated against GnRH‐I and the GnRH‐I associated peptide (GAP); mast cell identity was confirmed by the presence of heparin, a molecule specific to mast cells, or serotonin. To test whether mast cells synthesize GnRH‐I mRNA, in situ hybridization was performed using a GnRH‐I cRNA probe, and the signal was identified as being within mast cells by the binding of avidin to heparin. GnRH‐I mRNA was also found, using RT‐PCR, in mast cells isolated from the peritoneal cavity. Given the function of GnRH‐I in the regulation of reproduction, changes in the population of brain GnRH‐I mast cells were investigated. While housing males with sexually receptive females for 2 h or 5 days resulted in a significant increase in the number of brain mast cells, the proportion of mast cells positive for GnRH‐I was similar to that in males housed with a familiar male. These findings represent the first report showing that mast cells synthesize GnRH‐I and that the mast cell increase seen in a reproductive context is the result of a parallel increase in GnRH‐I positive and non‐GnRH‐I positive mast cells. © 2003 Wiley Periodicals, Inc. J Neurobiol 56: 113–124, 2003     

Localization of immunoreactive lamprey gonadotropin-releasing hormone in the rat brain

A highly specific antiserum against lamprey gonadotropin-releasing hormone (GnRH) was used to localize 1-GnRH in areas of the rat brain associated with reproductive function. Immunoreactive 1-GnRH-like neurons were observed in the ventromedial preoptic area (POA), the region of the diagonal band of Broca and the organum vasculosum lamina terminalis, with fiber projections to the rostral wall of the third ventricle and the organum vasculosum lamina terminalis. Another population of 1-GnRH-like neurons was localized in the dorsomedial and lateral POA, with nerve fibers projecting caudally and ventrally to terminate in the external layer of the median eminence. Other fibers apparently projected caudally and circumventrically to terminate around the cerebral aqueduct in the mid-brain central gray. By using a highly specific antiserum directed against mammalian luteinizing hormone-releasing hormone (m-LHRH), the localization of the LHRH neuronal system was compared to that of the 1-GnRH system. There were no LHRH neurons in the dorsomedial or the lateral region of the POA that contained the 1-GnRH neurons. As expected, there was a large population of LHRH neurons in the ventromedial POA associated with the diagonal band of Broca and organum vasculosum lamina terminalis. In both of these regions, there were many more LHRH neurons than 1-GnRH neurons and the LHRH neurons extended more dorsally and laterally than the 1-GnRH neurons. The LHRH neurons seemed to project to the median eminence in the same areas as those that were innervated by the 1-GnRH neurons. Absorption studies indicated that 1-GnRH cell bodies were eliminated by adding 1 microg of either 1-GnRH-I or 1-GnRH-III, but not m-LHRH to the antiserum before use. Fibers were largely eliminated by the addition of 1 microg 1-GnRH-III to the antiserum. No chicken GnRH-II neurons or nerve fibers could be visualized by immunostaining. Because the antiserum recognized GnRH-I and GnRH-III equally, we have visualized an 1-GnRH system in rat brain. The results are consistent with the presence of either one or both of these peptides within the rat hypothalamus. Because 1-GnRH-I has only weak nonselective gonadotropin-releasing activity, whereas 1-GnRH-III is a highly selective releaser of follicle-stimulating hormone, and because 1-GnRH neurons are located in areas known to control follicle-stimulating hormone release selectively, our results support the hypothesis that 1-GnRH-III, or a closely related peptide, may be mammalian follicle-stimulating hormone-releasing factor.     

Mast cells in the human brain

Mast cells, as adjudged by the metachromatic staining of their cytoplasmic granules, were found in 79% of the 97 humans brains studied. They were most numerous and most consistently present in the infundibulum, pineal organ, area postrema and choroid plexuses. They were also numerous in the leptomeninges surrounmding the pineal organ and infundibulum. Occasional mast cells were also seen within the supraoptic crest, the subfornical organ, the ventricles and the leptomeninges at sites other than over the infundibulum and pineal organ. They were not detectable elsewhere in the brain or spinal cord. In the infundibulum, pineal organ, area postrema and telencephalic choroid plexuses mast cells were most numerous in young individuals (i.e., 0-19 years of age); thereafter, their numbers progressively decreased with aging. Elsewhere mast cell numbers remained about the same with aging. Except in the area postrema where mast cells were more numerous and more consistently present in males, sex-related differences in mast cell number or distribution were not detected. No differences in either the abundance, the distribution or the percentage of individuals possessing mast cells at any of these sites were apparent between 'normative' brains, lesioned brains ('stroke', lobotomy, etc.) or those from individuals with either congenital or acquired encephalopathies.     

Interleukin-6 stimulates gonadotropin-releasing hormone secretion from rat hypothalamic cells

There are reports that both interleukin-1 beta and interleukin-6 (IL-6) stimulate the release of adrenocorticotropin through stimulation of hypothalamic corticotropin-releasing factor. We established a primary culture system for hypothalamic neurons producing gonadotropin-releasing hormone (GnRH) and examined whether IL-6 stimulated their GnRH secretion. We demonstrated immunohistochemically that some of these neurons contained GnRH-like immunoreactivity. In primary cultures of these GnRH neurons, we found that the calcium ionophore A23187 stimulated GnRH secretion in a dose- and time-dependent manner. These hypothalamic cells secreted IL-6 spontaneously, producing about 10 ng/l in 24 h, and their IL-6 secretion was significantly stimulated by E2 at 10(-9)-10(-8) mol/l. This stimulatory effect was observed within 3 h. IL-6 also stimulated the release of GnRH in a dose- and time-dependent manner, and these effects of IL-6 were significantly blocked by anti-IL-6 antiserum. These results suggest that the central action of IL-6 on the GnRH neurons may be an important physiological event in the hypothalamus.     

Evidence for gonadotropin-releasing hormone receptor mRNA expression by estrogen in rat granulosa cells

The hormonal regulation of ovarian gonadotropin-releasing hormone (GnRH) receptor mRNA expression has been examined by in situ hybridization in hypophysectomized immature rats. In hypophysectomized rats, GnRH receptor mRNA expression is localized in the interstitial cells. After diethylstilbestrol treatment, most follicles grow to form early antral follicles and express GnRH receptor mRNA in the peripheral part of the granulosa layer, indicating that the expression in the growing follicles is estrogen-dependent. Only weak or no expression of the receptor mRNA is detectable in the atretic follicles of hypophysectomized rats, whereas very strong expression has been observed in the granulosa cells of atretic follicles of intact immature rats. Administration of testosterone or a GnRH agonist, both of which are atretic agents for ovarian follicles, to hypophysectomized rats markedly increases the apoptotic cell death of the granulosa cells but fails to induce GnRH receptor mRNA expression. The co-administration of these agents with diethylstilbestrol causes the granulosa cells of atretic follicles to express the receptor mRNA very strongly, suggesting that this mRNA expression in the atretic follicles is also estrogen-dependent. On the other hand, expression of the receptor mRNA in the ovarian interstitial cells is not affected by hypophysectomy or hormone treatments. All of these results clearly indicate that estrogen is essential for the expression of ovarian GnRH receptor mRNA in the granulosa cells of atretic follicles and growing follicles, whereas the expression in the interstitial cells is estrogen-independent.     

Evidence for different gonadotropin-releasing hormone response sites in rat ovarian and pituitary cells

The participation of type I GnRH receptor (GnRH-R) on GnRH-II-induced gonadotropin secretion in rat pituitary cells was investigated. Furthermore, we extended the study of GnRH-II action to ovarian cells. The GnRH-II was able to mobilize inositol triphosphate (IP(3)) and to induce LH and FSH release in a dose-dependent manner in pituitary cells and in a GnRH-I-like manner. The GnRH-analog 135-18 (agonist for type II GnRH-R and antagonist for type I GnRH-R) was unable to elicit any cellular response tested in these pituitary cells. The GnRH-II responses were blocked by the type I GnRH-R-antagonists CRX or 135-18, suggesting that these effects were mediated by the type I GnRH-R. In contrast to pituitary cells, GnRH-I, but not GnRH-II, elicited an IP(3) response in superovulated ovarian cells; 135-18 also had no effect. However, GnRH-II as well as GnRH-I presented antiproliferative effects on these cells. Surprisingly, 135-18 had stronger antiproliferative effects than either GnRH peptide. The 135-18 analog, but not GnRH-I or GnRH-II, increased progesterone secretion in superovulated ovarian cells. These results strongly suggest that GnRH-II is able to stimulate rat pituitary cells through the type I GnRH-R, with no evidence for the presence of type II GnRH-R. On the other hand, our results indicate a putative GnRH-R in superovulated ovarian cells with response characteristics that differ from those of the GnRH-R in the pituitary.     

Cholinergic afferents to gonadotropin-releasing hormone neurons of the rat

Gonadotropin-releasing hormone-synthesizing neurons represent the final common pathway in the hypothalamic regulation of reproduction and their secretory activity is influenced by a variety of neurotransmitters and neuromodulators acting centrally in synaptic afferents to gonadotropin-releasing hormone neurons. The present study examined the anatomical relationship of cholinergic neuronal pathways and gonadotropin-releasing hormone neurons of the preoptic area. The immunocytochemical detection of choline acetyltransferase or vesicular acetylcholine transporter revealed a fine network of cholinergic fibers in this region. At the light microscopic level, the cholinergic axons formed appositions to the gonadotropin-releasing hormone immunoreactive cell bodies and dendrites. Results of electron microscopic studies confirmed the absence of glial interpositions in many of these neuronal contacts. Classical cholinergic synapses, which belonged to the asymmetric category, were only observed rarely on gonadotropin-releasing hormone neurons. The lack of synaptic density in most contacts corroborates previous observations on the cholinergic system elsewhere in the brain. Further, it suggests a dominantly non-synaptic route also in this cholinergic neuronal communication. This study provides direct neuromorphological evidence for the involvement of the cholinergic system in the afferent neuronal regulation of gonadotropin-releasing hormone neurons. The sources of cholinergic afferents and the receptorial mechanisms underlying this interaction will require further clarification.     

Ultrastructural localization of gonadotropin-releasing hormone in the porcine gonadotropic cells

Summary The comparative ultrastructural localization of LH, FSH and GnRH clearly shows that the granules of the FSH/LH cells contain all three hormones. The separate storage of LH and FSH in a significant number of cells, which in the same granules also display GnRH, may suggest that LH-RH is also FSH-RH and may help to explain the non-parallel release of LH and FSH under some functional conditions.     

Inhibitory effect of beta-endorphin on gonadotropin-releasing hormone and thyrotropin-releasing hormone releasing activity in cultured rat anterior pituitary cells

To study the effect of human beta-endorphin (beta h-End) on pituitary response to gonadotropin-releasing hormone (LH-RH) and thyrotropin-releasing hormone (TRH) in vitro, we used dispersed rat pituitary cells. When beta h-End (10(-7) M) was simultaneously added along with LH-RH, its stimulatory effect was blocked and naloxone (NAL, 10(-5) M) did not reverse the beta h-End inhibitory effect. NAL alone elicited an increase in LH release, but in the presence of both stimulants (LH-RH and NAL), LH secretion was lower than that observed with LH-RH alone. TRH stimulatory activity of TSH and PRL secretion was blunted by the presence of beta h-End (10(-7) M) and was not reversed by NAL (10(-5) and 10(-3) M). These data suggest that beta h-End directly blocks the LH, TSH- and PRL-secreting activity of both LH-RH and TRH at the pituitary level. This beta h-End effect is not reversed by the specific opiate receptor blocker NAL.     

Multiple molecular forms of gonadotropin-releasing hormone in teleost fish brain

Gonadotropin-releasing hormone (GnRH) immunoreactive peptides in extracts of hake (Merluccius capensis) and tilapia (Tilapia sparrmanii) brain were investigated by high performance liquid chromatography (HPLC) and radioimmunoassay with region-specific antisera. In hake brain, content and concentration of GnRH was higher in the pituitary gland than in the hypothalamic lobes or extrahypothalamic brain. Hake pituitary gland GnRH was purified by six consecutive HPLC systems. The major GnRH molecular form co-eluted with salmon brain GnRH (Trp7, Leu8-GnRH) in four different HPLC systems which were specifically designed to separate the four natural vertebrate GnRHs (mammalian, salmon, chicken I and II). The immunoreactive peak in the final purification step had a retention time identical to that of Trp7, Leu8-GnRH and an UV absorbance (280 nm) peak appropriate for two tryptophan residues in the peptide, as in Trp7, Leu8-GnRH. Six additional less hydrophobic forms of GnRH were detected. Tilapia brain extract contained two major GnRH molecular forms which had identical retention times to chicken GnRH I (Gln8-GnRH) and Trp7, Leu8-GnRH in an HPLC system which separates the natural vertebrate GnRHs. The immunological properties of these two immunoreactive peaks, determined by relative interaction with four region-specific GnRH antisera raised against vertebrate GnRHs, were identical to those of Gln8-GnRH and Trp7, Leu8-GnRH. Additional GnRH molecular forms were also detected. In summary, these findings indicate that a major GnRH molecule in hake pituitary gland is Trp7, Leu8-GnRH, while tilapia brain contains both Trp7, Leu8-GnRH and Gln8-GnRH. Additional GnRH molecular forms were detected in both species.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of progesterone on gonadotropin-releasing hormone receptor concentration in cultured estrogen-primed female rat pituitary cells

Acute (0.5–4 h) treatment of estradiol (E)-primed female rat pituitary cells with progesterone (P) augments gonadotropin-releasing hormone (GnRH)-induced LH release, whereas chronic (48 h) P-treatment reduces pituitary responsiveness to the hypothalamic decapeptide. Dispersed E-primed (48 h, 1 nM) rat pituitary cells were cultured for 4 or 48 h in the presence of 100 nM P to assess the effects of the progestagen on GnRH receptors and on gonadotrope responsiveness to the decapeptide. P-treatment (4 h) significantly augmented GnRH-receptor concentrations (4.44 ± 0.6 fmol/10⁶ cells) as compared to cells treated only with E (2.6 ± 0.5fmol/10⁶ cells). Parallel significant changes in GnRH-induced LH secretion were observed. The acute increase in GnRH-receptor number was nearly maximal (180% of receptor number in cells treated with E alone) within 30 min of P addition. Chronic P-treatment (48 h) significantly reduced pituitary responsiveness to GnRH as compared to E-treatment. The GnRH-receptor concentrations (3.9 ± 0.6 fmol/10⁶ cells), however, remained elevated above those in E-primed cells. GnRH-receptor affinity was not influenced by any of the different treatments. These results indicate that the acute facilitatory P-effect on GnRH-induced LH release is at least chronologically closely related to an increase in GnRH-receptor concentration. The chronic negative P-effect on pituitary responsiveness to GnRH, however, shows no relation to changes in available GnRH receptors.     

Mast cells: the immune gate to the brain

Mast cells were originally considered wandering histiocytes, but are now known to derive from the bone marrow and enter the tissues as immature or precursor cells which then differentiate under micro-environmental influences such as interleukin-3. At least three types of mature mast cells have been identified as serosal (lung, peritoneal, skin), mucosal (nasal, gastrointestinal) and brain (dural, perivascular, parenchymal) with their own distinct biochemical, morphological and functional characteristics. Mast cells are necessary for immediate hypersensitivity reactions where they release numerous biologically powerful mediators in response to immunoglobulin E (IgE) and antigen (Ag), and appear to be required for delayed reactions. Anaphylatoxins, basic peptides and drugs, as well as certain neuropeptides and hormones, can also trigger mast cell secretion. Recent evidence indicates that mast cells are found in close proximity to neurons, an association which may be regulated by nerve growth factor. Moreover, mast cells may be capable of selective release of mediators which could, in turn, regulate further secretion. This information suggests that mast cells may serve as a link between the immune, endocrine and nervous systems and could have an important role in the access of lymphocytes and pathogens to the brain. The possible role of such interactions in the pathophysiology of specific neuroinflammatory conditions is also discussed.     

Modulation of gonadotropin-releasing hormone receptor concentration in cultured female rat pituitary cells by estradiol treatment

Short-term (0.5-4 h) treatment of rat pituitary cells in culture with estradiol (E2) results in a significant decrease of Gonadotropin-Releasing Hormone (GnRH) induced LH-release. We studied whether changes in the concentrations of GnRH-receptors (GnRH-R) might account for this phenomenon: pituitary cells from adult female rats were incubated for 4 or 24 h in the presence or absence of 10(-9) M E2. Then saturation curves of D-Ala6-des-Gly10-GnRH ethylamide binding were obtained. In addition, binding studies were carried out in cultures incubated for 0.5, 1, 2 or 4 h with or without 10(-9) M E2 using a near saturating concentration of GnRH-analog. No changes of GnRH-R affinity occurred (4 h experiments: Ka in vehicle treated cells: 0.94 +/- 0.2 x 10(9) M-1, Ka in E2 treated cells: 1.06 +/- 0.3 x 10(9) M-1; 24 h experiments: Ka vehicle: 0.95 +/- 0.2 x 10(9) M-1, Ka E2: 0.82 +/- 0.3 x 10(9) M-1). The GnRH-R concentrations, however, were significantly reduced (44 +/- 3%; P less than 0.001) by 4 h E2 treatment and increased (by 68 +/- 8%; P less than 0.01) by 24 h of E2 treatment. The GnRH induced LH-release in aliquots of the same cell preparations was significantly reduced after 4 h and markedly increased after 24 h of E2 treatment. The experiments on the time-course of the reduction of D-Ala6-GnRH-binding by E2 treatment showed that the number of GnRH-R was significantly decreased (24 +/- 1%; P less than 0.05) already after 0.5 h of exposure to the estrogen. This is also the time period after which the negative E2-effect on GnRH-induced LH-release becomes significant. These data provide first evidence that the short-term negative E2-effect on GnRH induced LH-release by rat pituitary cells in culture could be mediated via a reduction of available GnRH-R.     

Neuroanatomical localization of cells containing gonadotropin-releasing hormone messenger ribonucleic acid in the primate brain by in situ hybridization histochemistry

Using in situ hybridization histochemistry, we have mapped the anatomic localization of perikarya containing mRNA that codes for GnRH and GnRH-associated protein (GAP) in the forebrain of four male macaques, Macaca fascicularis. DNA oligomers, with sequences complementary to either the GnRH or the GAP portion of the mRNA sequence, were synthesized and hybridized to paraformaldehyde fixed, coronal sections of the basal forebrain and hypothalamus. GnRH mRNA was found in the same population of cells as those containing GAP mRNA. GnRH/GAP mRNA-containing cell bodies were observed consistently in the medial septal nucleus, the diagonal band of Broca, the medial preoptic area, supraoptic nucleus, and ventromedial-infundibular region. We detected the presence of GnRH mRNA and GAP mRNA within the same neuroanatomic regions previously shown to include perikarya containing immunoreactive GnRH. The ventromedial-infundibular region and the medial preoptic region contained the greatest number of GnRH/GAP mRNA-containing perikarya (37.0% and 22.5%, respectively). The diagonal band contained 21.0% and the supraoptic nucleus 13.0% of the cells, while the medial septum contained the fewest number (6.7%). This study demonstrates the feasibility of using in situ hybridization as a strategy to study the developmental and steroidal regulation of GnRH gene expression in the nonhuman primate.     

Solubilization and purification of rat pituitary gonadotropin-releasing hormone receptor

Gonadotropin-releasing hormone (GnRH) receptors were solubilized from rat pituitary membrane preparations in an active form by using the zwitterionic detergent CHAPS (3-[(3-cholamidopropyl)dimethylammonio]-1-propanesulfonic acid). The solubilized receptor exhibits high affinity, saturability, and specificity. The soluble supernatant retained 100% of the original binding activity when stored at 4 or -20 degrees C in the presence of 10% glycerol. The receptors were resolved into two components on the basis of chromatography on wheat germ agglutinin-agarose. Homogeneous receptor preparation was obtained by two cycles of affinity chromatography on immobilized avidin column coupled to [biotinyl-D-Lys6]GnRH. The overall recovery of the purified receptor was 4-10% of the initial activity in the CHAPS extract, and the calculated purification -fold was approximately 10,000 to 15,000. Analysis of iodinated purified GnRH receptors by autoradiography indicated the presence of two bands, Mr = 59,000 and 57,000. This was confirmed by photoaffinity labeling of the partially purified receptors and suggests that both components can specifically bind the hormone.     

Immunoreactivity to gonadotropin-releasing hormone and gonadotropic hormone in the brain and pituitary of the rainbow trout Salmo gairdneri

Summary Immunoreactivity to gonadotropin-releasing hormone (GnRH) and gonadotropic hormone (GTH) was studied at the light-microscopical level in the brain and pituitary of rainbow trout at different stages of the first reproductive cycle using antisera against synthetic mammalian GnRH and salmon GTH. GnRH perikarya were localized exclusively in the preoptic nucleus, both in the pars parvicellularis and the pars magnocellularis. A few somata contacted the cerebrospinal fluid. Not all neurosecretory cells were GnRH-positive, indicating at least a bifunctionality of the preoptic nucleus. We recorded no differences between sexes or stages of gonadal development in the location of GnRH perikarya, whereas gradual changes were found in staining intensity during the reproductive cycle. GnRH fibres ran from the partes parvicellularis and magnocellularis through the hypothalamus and merged into a common tract at the transverse commissure before entering the pituitary. In the pituitary, GnRH was localized in the neural tissue of the neurointermediate lobe and, to a lesser extent, in the neural protrusions penetrating the proximal pars distalis. The bulk of GTH-positive cells was situated in the proximal pars distalis. Some cells were found more rostrally amidst prolactin cells or in the neurointermediate lobe. Only a limited number of GTH cells appeared to be in close contact with GnRH-positive material.     

Activation of translation in pituitary gonadotrope cells by gonadotropin-releasing hormone

The neuropeptide GnRH is a central regulator of mammalian reproductive function produced by a dispersed population of hypothalamic neurosecretory neurons. The principal action of GnRH is to regulate release of the gonadotropins, LH and FSH, by the gonadotrope cells of the anterior pituitary. Using a cultured cell model of mouse pituitary gonadotrope cells, alphaT3-1 cells, we present evidence that GnRH stimulation of alphaT3-1 cells results in an increase in cap-dependent mRNA translation. GnRH receptor activation results in increased protein synthesis through a regulator of mRNA translation initiation, eukaryotic translation initiation factor 4E-binding protein, known as 4EBP or PHAS (protein, heat, and acid stable). Although the GnRH receptor is a member of the rhodopsin-like family of G protein-linked receptors, we show that activation of translation proceeds through a signaling pathway previously described for receptor tyrosine kinases. Stimulation of translation by GnRH is protein kinase C and Ras dependent and sensitive to rapamycin. Furthermore, GnRH may also regulate the cell cycle in alphaT3-1 cells. The activation of a signaling pathway that regulates both protein synthesis and cell cycle suggests that GnRH may have a significant role in the maintenance of the pituitary gonadotrope population in addition to directing the release of gonadotropins.