Light and electron microscopic observation on the appearance of immunoreactive LHRH in perinatal rat hypothalamus

Development of the hypothalamic luteinizing hormone-releasing hormone-containing neuron system in the rat: in vivo and in transplantation studies

The development of the hypothalamic LHRH-containing neuron system was immunohistochemically investigated in vivo and in tissue transplantation using rat embryos aged from 12.5 to 17.5 days of gestation. The sera used were generated against rat gonadotropic hormone-releasing hormone-associated peptide (28-56) (rGAP) and LHRH. Immunoreaction for rGAP was first found in cells migrated from and in the vomeronasal organ on Days 13.5 and 14.5 of gestation. Immunoreactive cells seem to ascend along the terminal nerves, reaching the medial surface of the forebrain vesicles. Subsequently the cells occurred in the septum and further into their final position in the septopreoptic-diagonal band area on Days 16.5-17.5 of gestation; during this traverse the cells become secretory neurons after changes in morphology and in behavior. Intraventricular transplantation revealed that nasal epithelia of Day 12.5 embryos raised only a few cells immunoreactive both for LHRH and rGAP, but a great number of immunoreactive cells and fibers in the presence of the medial basal hypothalamus (MBH). The fibers formed a median eminence-like structure together with dense capillary plexus that had grown in the cografted MBH. The same phenomenon was apparently observed in the grafts obtained from older embryos of gestation, but not in the combined grafts of the anterior septum and the nasal epithelium or the MBH. We conclude that hypothalamic LHRH neurons originate from the nasal placode and acquire secretory behavior in the presence of the MBH.

Solitary hypothalamic neurons inherently express vasopressin and tyrosine hydroxylase

Hypothalamic neurons were grown as single cells in three-dimensional culture. Solitary neurons lacking cell contacts were immunocytochemically examined for inherent expression of vasopressin (VP), tyrosine hydroxylase (TH), and luteinizing hormone releasing hormone (LHRH). Immunoreactive VP and TH were detected within a day. Sixty to eighty-five percent of neurons displayed homogeneously distributed reaction product for VP or TH. One percent exhibited intense punctate staining of somas and varicosities. Few neurons stained for LHRH. Results indicate that hypothalamic neurons can express appropriate neuropeptides and transmitter-specific products without contacting other neurons or nonneuronal cells. Thus, this culture system may provide a useful model to study intrinsic neuronal processes.

Topographic relations between tyrosine hydroxylase- and luteinizing hormone-releasing hormone-immunoreactive fibers in the median eminence of adult rats

Employing electron microscopic double immunolabeling, we determined a close apposition of tyrosine hydroxylase (TH) and luteinizing hormone-releasing hormone (LHRH) nerve fibers in the rat median eminence (ME). These axo-axonic contacts occurred frequently in the internal and palisade zones, i.e. at the level of the fiber preterminals. In the superficial area of the ME, major TH fibers abutted on the basal lamina and some were projected into the pericapillary space of the portal vessels. Conversely, LHRH fibers were arrested by the endfeet of tanycytes in reaching the basal lamina.

Prenatal development of the gonadotropin-releasing hormone-containing systems in rat brain

Pre-embedding immunofluorescence was used to study the development of the gonadotropin-releasing hormone (GnRH)-containing neuronal systems in the brain of fetal and newborn rats. Immunoreactive cell bodies are first seen in association with the ventral olfactory bulb at the fetal embryonic (E) day 15. At day E 17, single GnRH-containing neurons are found in the nasal system, along the olfactory nerve, in the ganglion terminale, olfactory bulb, septum-diagonal band complex, olfactory tubercle and in the ventrolateral hypothalamus. A major spurt in the development of the brain GnRH-containing systems occurs between days E 18 and E 19. At day E 19, immunoreactive cell bodies are present in all areas as in the adult animals, however, in smaller number. GnRH-containing fibers are first detected in the nasal system at day E 17. At day E 18, GnRH positive projections are present in the nervus terminalis, in the developing organum vasculosum of the lamina terminalis and ventral hypothalamus. By day E 19, GnRH containing connections are established with most of the final target areas. These areas include the caudal olfactory bulb, lateral septum, stria terminalis, fimbria hippocampi, habenula, supramammillary commissure and central gray. In the hypothalamus, 3 major pathways are recognized: a ventral projection which runs in and beneath the optic chiasm toward the median eminence; a ventrolateral tract which is located lateral to the optic chiasm and which projects along the optic tract toward the lateral thalamus as well as to the median eminence; a periventricular network which projects to the habenula and, in a caudal direction, to the mediobasal hypothalamus including the median eminence. The results of the present study suggest that the GnRH neuronal systems develop considerably earlier than previously reported and that the intracerebral GnRH-containing fiber connections are established several days before birth.

Failure of luteinizing hormone-releasing hormone (LHRH) to affect the differentiation of LH cells in the rat hypophysial primordium in serum-free culture

The aims of this study were to investigate the differentiating capacity of adenohypophysial LH cells in a serum-free culture medium and to test whether cytogenesis is affected by synthetic LHRH. The adenohypophysial primordia of fetal rats were isolated on days 11.5 and 12.5 of gestation and cultured without serum for 10 and 9 days, respectively, in synthetic Medium 199 or alpha MEM. Immunohistochemical examination using the PAP method revealed that most culture explants, apart from a few degenerate ones, contained LH cells. In comparison with Medium 199, which has been widely used as a culture medium for hypophysial explants, alpha MEM gave far better results and the primordia cultured in this medium showed better tissue growth and contained a greater number of LH cells. Administration of synthetic LHRH (10 ng/ml) on the first day of culturing had no effect on the number of LH cells, no matter whether or not the culture medium was supplemented with insulin, transferrin or thyroxine. These results suggest that at the early developmental stage LHRH is not essential for the differentiation and/or proliferation of LH cells.

Axovascular relationships in developing median eminence of perinatal rats with special reference to luteinizing hormone-releasing hormone projections

Topographical relationships of neurosecretory axons with the capillaries of the primary portal plexus were studied in the median eminence of rats from the 14th fetal till the 9th postnatal day by means of electron microscopy combined with morphometric analysis. Special attention was given to the light and electron microscopic immunocytochemical examination of luteinizing hormone-releasing hormone projections to the median eminence. Neurosecretory axons possessing secretory granules and clear microvesicles were first observed in the median eminence at the 14th fetal day. However, all of them were situated at a distance from the primary portal plexus. By the 20th fetal day, neurosecretory axons reached the external basal lamina of the primary portal plexus giving rise to so-called axovascular contacts. Some axons even penetrated into the perivascular space, apparently facilitating the neurohormone delivery into the hypophysial portal circulation. From that time on, both the number of the axons abutting on the external basal lamina and the entire area of axovascular contacts increased gradually. As to luteinizing hormone-releasing hormone axons, they grew into the median eminence from the 18th fetal day concentrating in older fetuses and neonates either over the primary portal plexus, or around the infundibular recess of the 3rd ventricle. After birth, the concentration and distribution of luteinizing hormone-releasing hormone axons within the median eminence became similar to those of adults. Luteinizing hormone-releasing hormone axons were found to arise from the neurons of septopreoptic area including the diagonal band of Broca. These data suggest the onset of neurohormone release in the median eminence from the 14th fetal day followed by the establishment of the hypothalamic control over the pituitary functions during the perinatal period in rats.

Immunocytochemical localization in rat brain of a prolactin release-inhibiting sequence of gonadotropin-releasing hormone prohormone

The structure of a precursor protein for gonadotropin-releasing hormone (GnRH) of relative molecular mass 10,000 has recently been deduced from cloned complementary DNA sequences derived from human placental messenger RNA. The 56-amino-acid peptide representing residues 14-69 of this prohormone exhibits potent inhibition of prolactin secretion. To investigate whether the same prohormone is synthesized in mammalian brain and describe the anatomical distribution of the prolactin-inhibiting region of this molecule, we have generated antiserum to a synthetic peptide containing residues 40-53 of the human placental precursor. We report here that a substance recognized by this antibody is present in GnRH-containing neurones of the rat brain and appears to coexist with GnRH in secretory granules of nerve terminals in the median eminence. These results indicate homology between hypothalamic and placental prohormones for GnRH and are consistent with the suggestion elsewhere in this issue that a prolactin-inhibiting factor (PIF) is generated from this prohormone and cosecreted with GnRH by nerve terminals in the median eminence.

Ontogenetic appearance of somatostatin-containing nerve terminals in the median eminence of rats

The development of immunoreactive (ir) somatostatin-containing nerve terminals in the rat median eminence (ME) has been examined electron-microscopically. Nerve fibers containing ir particles scattered throughout the axoplasm are first seen in the external layer of the ME on day 18.5 of gestation, and, on day 21.5 appear to terminate on the basement membrane of the perivascular space of the portal vessels. After birth, the fiber terminals contain several membrane-limited granules, which are labeled with ir PAP particles. Ultrathin, Epon-embedded sections of ME, treated by the protein A gold-labeling method for somatostatin, demonstrate positively labeled granules in the nerve fibers in the postnatal ME, but in the prenatal tissue, no specific gold-labeling is found. These findings show that, in the external layer of the ME, somatostatin storing occurs in the granules in the axonal terminals after birth.

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.

Cyproterone acetate induced changes in the behaviour of hydroxysteroid dehydrogenases in rat Leydig cells during perinatal development

The influence of cyproterone acetate (CA) upon the behaviour of hydroxysteroid dehydrogenases (HSDH) in the Wistar rat Leydig cells was investigated during the perinatal phase with the help of enzymhistochemical cum morphometrical techniques. The pregnant rats as well as their offsprings were injected with CA (dosage: 35 mg/kg body wt) sc, daily from 14 fetal day upto 31 postnatal day (p.n.d.). The animals were killed on 5, 20, and 32 p.n.d.; the enzymhistochemical reactions for 3-beta-HSDH, 11-beta-HSDH, 17-HSDH and 3-alpha-HSDH were performed in the cryostat sections of the testis, and the morphometric evaluation of HSDH positive Leydig cells was carried out. On 5 p.n.d. the activity of 17-beta-HSDH was slightly impaired in the intertubular Leydig cells of the CA treated animals. On 20 p.n.d., CA prevented nearly completely the HSDH activity in the newsly built peritubular Leydig cells; the activities of 3-beta-HSDH, 17-beta-HSDH, and 3-alpha-HSDH resided mainly in the intertubular Leydig cells. On 32 p.n.d. the HSDH activities in the Leydig cells were observed in the control as well as in treated animals. It seems that the differentiation of peritubular Leydig cells, and thereby the steroid production, is delayed by CA, but not entirely blocked.

Enzymhistochemical and morphometrical studies on delta 5-3 beta-hydroxysteroid dehydrogenase during the fetal and neonatal development of rat Leydig cells

The aim of the present report was to study the course of development of rat Leydig cells from 17 fetal day (f.d.) up to 5 postnatal day (p.n.d.), with the help of enzymhistochemical reaction of delta 5-3 beta Hydroxysteroid-dehydrogenase (3 beta-HSDH). Testes were obtained from 17 to 21 days old embryos and from 1 to 5 days old offsprings. Cryostat sections were cut and processed for enzymhistochemical reaction of 3 beta-HSDH, employing dehydroepiandrosterone as substrate. The areas of the Leydig cells, showing the enzymatic activity, were measured morphometrically. The 3 beta-HSDH positive intertubular Leydig cells appear on 17 f.d., and grow further showing a maximum peak, relative to the size of the testis, on 19 f.d. Thereafter, the percentage of the Leydig cells relative to the size of the testis decreases continuously up to 4 p.n.d.. The Leydig cells did not regress during the period of observation. Postnatally, the large complexes disperse into many small complexes.

Differing postnatal development of the somatostatin- and luliberin- systems in the male and female rat

By means of light-microscopic immunohistochemistry the perikarya of the luliberin-(LRF-) and somatostatin systems of neonate rats were found to be in differing stages of development. At a time point when the LRF-producing neurons had obviously attained their final shape and size, the somatostatin-immunoreactive perikarya were still in a postnatal phase of maturation. Whereas the number of the latter perikarya increases with advancing age, the number of LRF-immunoreactive perikarya decreases significantly from postnatal day 7 onward. Both peptide-hormone systems do not project concomitantly and to the same extent to their principal neurohemal regions in the organum vasculosum laminae terminalis (OVLT) and the median eminence (ME). In all presently studied stages of development, despite considerable individual variations in one age group, among the components of the LRF-system the OVLT displays a more intense immunoreactivity than the ME. The somatostatin system, however, projects to the OVLT with a conspicuous temporal delay compared to the ME, and, furthermore, in the OVLT the pattern of immunoreactivity characteristic of adult rats is not yet attained at postnatal day 21. Evidence for differences in the immunoreactivity between male and female animals was restricted to the LRF-system. Finally, the results obtained on the stria terminalis speak in favour of the fact that the long-range extrahypothalamic projections of the somatostatin system also undergo postnatal maturation. In the stria terminalis, somatostatin-immunoreactive fibers can be demonstrated initially on postnatal day 7. They attain their full immunoreactivity on postnatal day 21. Furthermore, in the bed nucleus of the stria terminalis an intermittent cytoplasmic immunoreactivity is observed, which is limited to the animals of postnatal day 7 and disappears completely during the further course of development.

Ultrastructural localization of LH-RH-immunoreactive synapses in the hamster accessory olfactory bulb

Electron microscopic immunocytochemistry was used to localize luteinizing hormone-releasing (LH-RH) immunoreactivity within the male golden hamster accessory olfactory bulb. Two LH-RH-immunoreactive fiber populations were identified in the accessory olfactory bulb. A superficial system of immunoreactive axons was localized to the vomeronasal nerve and glomerular layers, and a periventricular system appeared in granule cell and periventricular layers. LH-RH-immunoreactive varicosities were observed to contain large reactive vesicles (80-120 nm) as well as a variable degree of cytoplasmic reaction product. Additionally, small vesicles with unreactive lumens and mitochondria were often present. Intravaricose segments of immunoreactive fibers invariably displayed fewer reactive vesicles than did varicosities. Within both glomerular and periventricular layers, some LH-RH-immunoreactive varicosities were observed to form asymmetric contacts characterized by prominent postjunctional densities. In the glomerular layer, these junctions could be identified as synaptic by several features. The presence of LH-RH-immunoreactivity in presynaptic elements supports a neuromodulatory role for LH-RH. As the accessory olfactory system is critically involved in the initiation of mating behavior of the male golden hamster, LH-RH-immunoreactive synapses in the accessory olfactory bulb may function to regulate reproductive behavior.

Development of the hypothalamic-hypophysial-gonadotrophic activities in fetal rats

Pituitary responsiveness to LHRH and anti-LHRH serum was investigated in fetal rats aged 18.5-22.5 days. Synthetic LHRH injection in utero into fetuses brought about a remarkable depletion of pituitary-LH with a corresponding increase of serum-LH on day 18.5. On the contrary, anit-LHRH serum administration to day-20.5 fetuses caused a significant augmentation of pituitary-LH 1 day later. These data indicate that LH-gonadotrophs respond to LHRH even on day 18.5, and that endogenous LHRH begins to affect LH gonadotrophs on day 20.5.