Gonadotropin-releasing hormone release from the mediobasal hypothalamus of fetal baboons

Pulsatile luteinizing-hormone releasing hormone (LHRH) secretion was measured from the mediobasal-suprachiasmatic-preoptic (MBH-SCN-POA) region of the hypothalamus from fetal baboons (Papio anubis) at midgestation (day 100; term = day 184). The entire MBH-SCN-POA (48 ± 5 mg) was obtained between 1100 and 1200 hours and was immediately placed in icecold phosphate buffer (pH 7.4). The MBH-SCN-POA units were halved at the midline and superfused in parallel at 37.5°C for 5 hours. Then 500 μl of superfusate was collected at 10-minute intervals, and LHRH concentration was measured by radioimmunoassay using the Chen-Ramirez antibody. In fetuses of untreated baboons (N = 3), LHRH pulse amplitude (mean ± SE) was 16.0 ± 4.2 pg, with a period of 30 ± 1 minute; the average 10-minute output of LHRH was 9.4 ± 2.0 pg. In fetal baboons in which the hormonal milieu in the mother was modulated by androstenedione treatment of midpregnancy (N = 3), average LHRH pulse amplitude was 1.7 ± 0.3 pg, with a period of 33.5 ± 4.9 minutes; the average 10-minute output of LHRH was 1.2 ± 0.2 pg. Collectively, these data suggest that as early as midgestation, fetal baboons secrete LHRH in vitro in a pulsatile fashion and with a periodicity of 30–35 minutes. In addition, the decrease in LHRH pulse amplitude and the average 10-minute LHRH output (P < .01, P < .05) in tissue from fetal baboons of mothers in which the normal pattern of steroidogenesis is altered suggest that the output of LHRH systems in the fetus is sensitive to changes in the maternal hormonal milieu.     

Immunocytochemistry of luteinizing hormone-releasing hormone,vasopressin, and corticotropin following deafferentation of the basal hypothalamus of the male rat brain

Summary Luteinizing hormone-releasing hormone (LHRH), vasopressin, and corticotropin systems were examined by immunocytochemical methods in male rats 2 to 20 days after deafferentation of the basal hypothalamus. Axonal degeneration of the vasopressin system (whose perikarya lie rostral to the island) and the corticotropin system (whose perikarya lie within the island) was examined and compared with the response of the LHRH system.Vasopressin immunoreactive staining was absent in the internal zone of the median eminence 10 and 20 days after deafferentation. Disruption of the efferent projections of the opiocortin system caused the loss of almost all fiber staining outside the island by the 5th postoperative day. LHRH staining in the median eminence was modestly reduced in 5 days, considerably reduced in 10 days and negligible 20 days after deafferentation. At 10 and/or 20 days after deafferentation densely stained fibers of all three systems were observed on both sides of the cut. Invasive vasopressinergic fibers reached the lateral median eminence by the 20th postoperative day.This study reports on the response of three neuropeptide systems after complete deafferentation and demonstrates that regeneration can occur across the knife cut.Supported by: NIH Grants AM-22029 and Program Project NS-15345, and USPHS grant 5T32 GM-07136-06The authors wish to express their appreciation to Ms. Barbara Dolf for her technical assistance.     

A new antiserum with conformational specificity for LHRH: usefulness for radioimmunoassay and immunocytochemistry

We have produced and characterized a new high titer, highly specific antiserum for luteinizing hormone-releasing hormone (LHRH), and demonstrated its usefulness for radioimmunoassay (RIA) and immunocytochemistry. The antiserum can be used at a final dilution of 1:500,000 to 1:600,000 for RIAs with a sensitivity of 0.2 pg/tube. Both the amino and carboxy terminal ends of the LHRH molecule are required for antibody recognition, and the antigenic determinant appears to be part of a three-dimensional structure of LHRH. Fragments of LHRH and other brain peptides are not recognized by the antiserum. Using immunocytochemical techniques, we have localized LHRH-containing neurons in the medial basal hypothalamus of the rhesus monkey, guinea pig, and rat. Staining of LHRH fibers and cell bodies was eliminated by preabsorbtion of the immune serum with synthetic LHRH. This antiserum should be useful in studies that require quantification of very low amounts of LHRH and in studies that require correlation between immunocytochemical localization and tissue content or secretion of LHRH.     

LHRH inactivation by reconstituted horse and fetal bovine sera: assessment by reduction of immunoreactivity and biological activity in pituitary cell cultures

Lyophilized horse and fetal bovine sera are commonly incorporated into the growth media used for primary pituitary cell cultures. LHRH degrading activity has been assumed to exist in these preparations but has not actually been demonstrated. During our studies with pituitary cultures, it became necessary to ascertain if LHRH inactivating activity could be demonstrated in these sera. Luteinizing hormone releasing hormone (LHRH) was preincubated in either serum-free medium or medium containing fetal bovine and horse serum. Whether LHRH was lost during these incubations was assessed by diminished immunoreactivity as indicated by radioimmunoassay (RIA) and by diminished biological activity as indicated by reduced release of LH from pituitary cell cultures. Both the RIA and bioassay results indicated LHRH inactivating activity; the loss of LHRH could be prevented by inclusion of bacitracin in the incubations.     

Estrogen and the subcellular distribution of luteinizing hormone releasing hormone: Rate sedimentation studies

Rate sedimentation of the 900×G supernatants (S₁) of hypothalamic homogenates from untreated male rats or ovariectomized rats with or without 5 μg estradiol benzoate (EB) revealed two populations of LHRH particles: a minor, slowly sedimenting one (peak 1) and a major, more rapidly sedimenting one (peak 2). Some LHRH-containing material also sedimented to the bottom of the gradient. The ovariectomized rats displayed more heterogeneity of particulate LHRH than did the male rats. Furthermore, the administration of EB to ovariectomized rats altered the relative sedimentation pattern of LHRH. In ovariectomized rats, hypotonic shock of S₁ prior to rate sedimentation eliminated peak 2 and post-peak 2 LHRH and increased free LHRH at the top of the gradient. Peak 1 LHRH was still present and was elevated after EB treatment. Also, EB treatment lowered the free LHRH at the top of the gradient. These data demonstrate that the administration of EB to an ovariectomized rat alters the subcellular distribution of LHRH.     

Immunohistochemical study of the LHRH-synthesizing neuron system of aged female rats

Summary The LHRH-synthesizing neuron system was studied in young proestrous and old female rats, and in aged ovariectomized or reserpine-treated females. The medial preoptic area and septal region of old animals contains more LHRH positive perikarya compared to that of young proestrous rats. Reserpine treatment moderately increases the number of immunostainable LHRH cells, while ovariectomy is ineffective in this respect.The authors wish to thank Ms. Márta Szelier for her excellent technical assistance and Ms. Márta Soltész for the photographic work     

Estrogen and the subcellular distribution of luteinizing hormone releasing hormone: Rate sedimentation studies

Rate sedimentation of the 900×G supernatants (S₁) of hypothalamic homogenates from untreated male rats or ovariectomized rats with or without 5 μg estradiol benzoate (EB) revealed two populations of LHRH particles: a minor, slowly sedimenting one (peak 1) and a major, more rapidly sedimenting one (peak 2). Some LHRH-containing material also sedimented to the bottom of the gradient. The ovariectomized rats displayed more heterogeneity of particulate LHRH than did the male rats. Furthermore, the administration of EB to ovariectomized rats altered the relative sedimentation pattern of LHRH. In ovariectomized rats, hypotonic shock of S₁ prior to rate sedimentation eliminated peak 2 and post-peak 2 LHRH and increased free LHRH at the top of the gradient. Peak 1 LHRH was still present and was elevated after EB treatment. Also, EB treatment lowered the free LHRH at the top of the gradient. These data demonstrate that the administration of EB to an ovariectomized rat alters the subcellular distribution of LHRH.     

Role of neurotransmitters and neuropeptides in the control of gonadotropin release: A review

Rapid progress has been recorded recently in the understanding of the role of neuro-transmitters and neuropeptides in the control of reproduction and on their apparent potential in the regulation of fertility. Peptides, as well as monoamines, are important in the control of lutinizing hormone releasing hormone and gonadotropin release. The input from brainstem noradrenergic neurons as well as dopamine mediated stimulated release of lutinizing hormone. In addition considerable evidence exist for the occurrence of a specific follicle stimulating hormone-releasing factor. A large number of brain peptides affect the secretion of lutinizing hormone releasing hormone and the endogenous opioid peptides appear to have a physiologically important function in restraining the influence on lutinizing hormone releasing hormone release under most circumstances. Vasoactive intestinal peptide and substanceP stimulate whereas cholecystokinin, neurotensin, gastrin, secretin, somatostatin α-melanosite stimulating hormone and vasotocin inhibit lutinizing hormone release. Of the inhibitory peptides, cholecystokinin and arg-vasotocin are the most potent. Inhibin injected into the ventricle selectively suppresses follicle stimulating hormone release by a hypothalamic action. Thus the control of gonadotropin release is complex and a number of aminergic and peptidergic transmitters are involved.     

Antiovulatory antagonists of LHRH related to antide

We report 104 analogues of the potent antiovulatory antagonist of LHRH, N-Ac-D -Nal-D -Cpa-D -Pal-Ser-Lys(Nic)-D -Lys(Nic)-Leu-Ilys-Pro-D -Ala-NH₂, Antide. We replaced the Nic group in Antide with other acyl substituents to modulate size, hydrophilicity or basicity of the molecule, we also replaced th Lys residues with shorter basic amino acids, and made cyclic 5/6 analogues as well as position 5 or 6 dimers. We substituted Ilys⁸ with other alkyl groups and acyl derivatives. When injected in 0.1% DMSO in water in a typical antiovulatory (AO) assay, Antide gives six rats ovulating out of eight (6/8) at 2 μg, 4/8 at 4 μg, and the histamine release assay (HRA), ED₅₀ is >300 μg/ml; [Lys(N-Isobutyl)⁸]Antide gave 2/8 at 2 μg/rat; [Lys (8-Qis)⁵]Antide gave 1/8 at 1 μg, and 0/8 at 2 μg, and in the HRA ED₅₀, 22 μg/ml; [D -Lys(8-Qis)⁶]Antide gave 4/8 at 1 μg and 0/8 at 2 μg, and in the HRA, ED₅₀ was 27 μg/ml; [Lys(8-Qic)⁸] gave 5/8 at 1 μg, 1/8 at 2 μg/ [Lys(2-Pyc)⁵]Antide gave 5/8 at 1 μg and 0/8 at 2 μg, and in the HRA ED₅₀ was 116 μg/ml; [D -Lys (2-Pyc)⁶]Antide gave 3/8 at 1 μg, and in the HRA, ED₅₀ was 100 - >300 μg/ml; [Lys(2-Pyc)⁵,D -Lys(2-Pyc)⁶]Antide gave 2/8 at 1 μg. The substitutions of the Nic groups of Antide at Lys⁵ or D -Lys⁶ with 8-Qis or with 2-Pyc groups seem to give highly potent antiovulatory antagonists of LHRH and constitute significant new leads to generate potent antiovulatory compounds endowed with moderate or low histamine release.     

In vivo and in vitro studies on the appearance of LHRH neurons in the hypothalamus of perinatal rats

Summary Ontogenetic development of LHRH-containing neurons was studied by fluorescence and enzyme immunohistochemistry in rats. In in vitro studies, the tissues of the septal-chiasmatic and mediobasal hypothalamic areas of fetal rats on day 16.5 or 18.5 of gestation were trypsinized separately for dissociation of the neural cells, and cultured for several days. Immunopositive reaction against LHRH was first detected in nerve cells derived from both areas of the hypothalamus of the fetuses on days 16.5 and 18.5 of gestation, after 8 and 6 days culture, respectively. The cells were small, and seemed to be bipolar in morphology indicating an axon and arborized dendrites. Immunopositive material occurred in the cell soma as well as in the cellular processes. In in vivo studies, immunopositive material, possibly deposited in nerve fibers, appeared first in OVLT and simultaneously in the external layer of the median eminence of fetuses on day 20.5 of gestation. The immunoreactive fibers increased in number in both parts with development, especially after birth in the median eminence. No immunopositive material was detected within any neural cell bodies nor in the cytoplasm of any ependymal cells.This work was financed by the Ministry of Education, Japan. No. 257008. We would like to thank Dr. Katsuhiko Saito (Department of Surgery, Tokushima University) for his kind advice on the preparation of the antibody used for the immunofluorescence study.     

促黄体生成激素释放激素类似物的研究进展

促黄体生成激素释放激素(LHRH)激动剂药物已商品化,用于治疗性激素依赖的癌症,LHRH拮抗剂的研究还处于试验阶段.近几年,在寻找高活性,低组胺释放,水溶性好,稳定性高的拮抗剂研究方面,已取得明显进展.一些较小的环肽及肽模拟物也表现出较好的生物活性.在十肽拮抗剂分子内,中间四肽的βⅡ-turn及N端的三肽对活性影响很大.     

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

Summary 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 diaminobenzidinereaction 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 septopreoptico-infundibular pathways, we also observed GAPimmunopositive processes in several major tracts and areas of the brain, including the amygdala, stria terminalis, 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.Supported by AKA No. 419427, OTKA No. 104, OKKFT 2.1.5.1 and NSF No. INT-8602688     

Electron microscopic observations of the anterior pituitary gland. Part I. The neurons in the "transitional zone" of the anterior pituitary gland

Since [Westlud, K.N., Chils, G.V., 1982. Localization of serotonin fibers in the rat adenohypophysis. Endocrinology 111, 1761-1763] initially identified the serotonin nerve fibers in the anterior pituitary gland, attention has been paid to the rostral zone of the anterior lobe into which nerve fibers enter and subsequently spread to deeper regions of the lobe. The rostral zone is the trifurcated junction of the partes tuberalis, intermedia and distalis, and has the important role(s) for hormone secretion via the "transitional zone" [Sato, G, Shirasawa, N, Sakuma, E, Sato, Y, Asai, Y, Wada, I, Horiuchi, O, Sakamoto, A, Herbert, DC, Soji, T, 2005a. Intercellular communications within the rat anterior pituitary. XI: An immunohistochemical study of distributions of S-100 positive cells in the anterior pituitary of the rat. Tissue and Cell 37, 269-280.]. The objective of this study was to focus on the ultrastructure of this "zone." All of the animals studied were fixed by perfusion with glutaraldehyde via the left ventricle of the heart and examined by electron microscopy. In the "transitional zone," a cluster of neuronal elements was observed between the folliculo-stellate cell-rich area and the anterior lobe. This cluster consisted of myelinated fibers, unmyelinated fibers, neuroendocrine fibers, large cells, and supporting cells. The large cells were perikarya of neurons which made a "ganglion-like" structure with associated satellite cells. Agranular, folliculo-stellate cells were intermingled among the elements. This is the first report that neuronal elements form clusters in the "transitional zone." A relationship of the unmyelinated and neuroendocrine fibers in the basal layer and in the "transitional zone" is discussed.     

Correlative ontogenetic development of catecholamine- and LHRH-containing nerve endings in the median eminence of the rat

Summary The ontogenetic development of catecholamine (CA)-and LHRH-containing nerve endings in the median eminence of the rat was investigated by combining fluorescence histochemistry and immunohistochemistry in the same tissue section. LHRH-terminals appeared earlier than CA-terminals and were already detectable in the lateral part of the external layer of the central ME on the first day after birth. CA-nerve endings were first seen in a corresponding region of the ME on the seventh postnatal day. At this stage both types of terminals showed the earliest manifestation of a correlative pattern of their distribution. Subsequently the development of both types of nerve endings proceeded rapidly, and at 14 days their distribution pattern corresponded to that in adult animals. The authors conclude that at this stage the CA-neurons play a constant and significant role in the release of LHRH into the portal capillaries. The correlation between both types of nerve endings and the ontogenetic development of the capillary plexuses of the hypophysial portal system is discussed.This work was supported in part by a grant (No. 248093, 321426) from the Ministry of Education, Science and Culture, Japan     

Electron microscopic study of immunoreactive LHRH perikarya with special reference to neuronal regulation

Summary In early postnatal rats, immunoreactive LHRH perikarya in the preoptic area were studied by light and electron microscopy. Synaptic junctions were found between the immunoreactive perikaryon or its process, and the immunonegative nerve fibers. The significance of these synapses is discussed in relation to possible mechanisms by which the activities of LHRH neurons are regulated.     

Biosynthesis of LHRH: Inferences from immunocytochemical studies

Inferences regarding biosynthesis of LHRH in rats are made from immunocytochemical studies using LHRH antisera with varied and specific binding requirements. Immunoreactive perikarya were observed with antisera that could bind putative large molecular weight precursors of LHRH. No cells were detected with an antiserum that requires free decapeptide terminals and could not bind extended precursors. No such differential immunoreactivity was apparent in neuronal processes and neurovascular terminals. Features of intracellular processing of LHRH which can be inferred from these immunocytochemical data are: (1) the decapeptide is initially synthesized within neuronal cell bodies as a larger molecular weight peptide, extended at both the N- and C-terminals; (2) processing occurs as the newly synthesized material is transported along neuronal processes; and (3) intermediate molecular forms are converted to the active decapeptide primarily in distal portions of neuronal fibers, including the neurovascular terminal. Immunocytochemical observations in other mammalian species (humans, monkeys, ferrets and bats) allow us to further suggest that the dynamics of maturation of this hormone may differ among mammals.     

Organization of LHRH cells: differential apposition of neurotensin, substance P and catecholamine axons

A wealth of evidence suggests that catecholamines (particularly norepinephrine) influence gonadotropin secretion via a direct interaction with the LHRH neurons. Neuropeptides such as neurotensin (NT) and substance P (SP) are likewise implicated in the control of LHRH secretion, based on pharmacological and preliminary anatomical studies. Since sub-populations of LHRH neurons project to areas of the brain other than the median eminence, a detailed analysis of the topography of axonal interactions of catecholamines (CA), substance P and neurotensin with LHRH cells was conducted in adult male mice using dual immunocytochemical techniques. An analysis of the patterns of apparent contact of NT or SP axons on LHRH cells as determined by close apposition of immunoreactive axons to LHRH cells when viewed under a light microscope at high magnification revealed that the density of NT or SP axons was not a reliable index of the degree of contact; in many locations, NT and SP had similar densities yet a greater portion of the LHRH cells appeared contacted by SP than NT. NT axons were in close contact with up to one-third of the LHRH cells. Analysis of the location of these "contacted" cells did not reveal a discrete subnucleus controlled by NT. Rather, the NT-contacted cells were scattered throughout the LHRH cell field. Interactions of LHRH cells with SP axons were likewise uniform throughout most of the LHRH cell field, with the exception of the most anterior portion of the field. In the anterior septum, few SP axons appeared to contact LHRH cells. Elsewhere, most of the LHRH cells were in contact with SP axons. For the CAs, the fiber density in the regions of the LHRH cells was uniformly moderate, yet the pattern of cells contacted showed variation across the LHRH cell field, with most of the "contacted" cells located near the OVLT and medial preoptic area. These data suggest that LHRH cells may be differentially regulated by NT, SP and the CAs.