Relationship of catecholamines and LHRH: light microscopic study

An Inhibitory Circuit From Brainstem to GnRH Neurons in Male Mice: A New Role for the RFRP Receptor

RFamide-related peptides (RFRPs, mammalian orthologs of gonadotropin-inhibitory hormone) convey circadian, seasonal, and social cues to the reproductive system. They regulate gonadotropin secretion by modulating gonadotropin-releasing hormone (GnRH) neurons via the RFRP receptor. Mice lacking this receptor are fertile but exhibit abnormal gonadotropin responses during metabolic challenges, such as acute fasting, when the normal drop in gonadotropin levels is delayed. Although it is known that these food intake signals to the reproductive circuit originate in the nucleus tractus solitarius (NTS) in the brainstem, the phenotype of the neurons conveying the signal remains unknown. Given that neuropeptide FF (NPFF), another RFamide peptide, resides in the NTS and can bind to the RFRP receptor, we hypothesized that NPFF may regulate GnRH neurons. To address this question, we used a combination of techniques: cell-attached electrophysiology on GnRH-driven green fluorescent protein-tagged neurons in acute brain slices; calcium imaging on cultured GnRH neurons; and immunostaining on adult brain tissue. We found (1) NPFF inhibits GnRH neuron excitability via the RFRP receptor and its canonical signaling pathway (Gi/o protein and G protein-coupled inwardly rectifying potassium channels), (2) NPFF-like fibers in the vicinity of GnRH neurons coexpress neuropeptide Y, (3) the majority of NPFF-like cell bodies in the NTS also coexpress neuropeptide Y, and (4) acute fasting increased NPFF-like immunoreactivity in the NTS. Together these data indicate that NPFF neurons within the NTS inhibit GnRH neurons, and thus reproduction, during fasting but prior to the energy deficit.

GnRH Neurons Provide Direct Input to Hypothalamic Tyrosine Hydroxylase Immunoreactive Neurons Which Is Maintained During Lactation

Gonadotropin releasing hormone (GnRH) neurons provide neuronal input to the preoptic area (POA) and the arcuate nucleus (Arc), two regions involved critically in the regulation of neuroendocrine functions and associated behaviors. These areas contain tyrosine hydroxylase immunoreactive (TH-IR) neurons, which play location-specific roles in the neuroendocrine control of both the luteinizing hormone and prolactin secretion, as well as, sexually motivated behaviors. Concerning changes in the activity of GnRH neurons and the secretion pattern of GnRH seen under the influence of rising serum estrogen levels and during lactation, we tested the hypothesis that the functional state of GnRH neurons is mediated via direct synaptic connections to TH-IR neurons in the POA and Arc. In addition, we examined putative changes of these inputs in lactating mice and in mothers separated from their pups. Confocal microscopic and pre-embedding immunohistochemical studies on ovariectomized mice treated with 17β-estradiol (OVX+E2) provided evidence for direct appositions and asymmetric synapses between GnRH-IR fiber varicosities and TH-IR neurons in the POA and the Arc. As TH co-localizes with kisspeptin (KP) in the POA, confocal microscopic analysis was continued on sections additionally labeled for KP. The TH-IR neurons showed a lower level of co-labeling for KP in lactating mice compared to OVX+E2 mice (16.1 ± 5% vs. 57.8 ± 4.3%). Removing the pups for 24 h did not alter significantly the KP production in TH-IR neurons (17.3 ± 4.6%). The mean number of GnRH-IR varicosities on preoptic and arcuate TH cells did not differ in the three animal models investigated. This study shows evidence that GnRH neurons provide direct synaptic inputs to POA and Arc dopaminergic neurons. The scale of anatomical connectivity with these target cells was unaltered during lactation indicating a maintained GnRH input, inspite of the altered hormonal condition.

A confocal microscopic study of gonadotropin-releasing hormone (GnRH) neuron inputs to dopaminergic neurons containing estrogen receptor alpha in the arcuate nucleus of GnRH-green fluorescent protein transgenic mice

The purpose of the present study was to determine whether the septo-preoptico-tuberoinfundibular gonadotropin-releasing hormone (GnRH) pathway comes in close juxtaposition with tyrosine hydroxylase immunoreactive (TH-IR) neurons in the arcuate nucleus of female mice. Immunohistochemical staining with a TH monoclonal antibody coupled with confocal microscopy was employed on vibratome-cut brain sections of female GnRH-green fluorescent protein (GFP) transgenic mice to evaluate possible appositions between GnRH and tuberoinfundibular dopaminergic (TIDA) neurons. TH-IR neurons of the arcuate nucleus received GnRH neuronal appositions in adult female mice at proestrus and estrus stages. In contrast, no GnRH appositions were observed in adult females at diestrus. Subsequently, double immunohistochemical staining for TH and estrogen receptor-alpha (ERalpha) was performed to examine the role of estradiol on this relationship. We found that most TH-IR neurons contacted by GnRH fibers were immunoreactive for ERalpha. Our observations suggest that GnRH neurons communicate directly with TIDA neurons in the adult female. Furthermore, ERalpha activation in TIDA neurons may be involved in the formation of connections between GnRH neurons and TIDA neurons.

Prolactin-releasing peptide-immunoreactivity in A1 and A2 noradrenergic neurons of the rat medulla

Distribution of prolactin-releasing peptide-like immunoreactivity (PrRP-LI) was investigated in the rat medulla with the use of a rabbit polyclonal antiserum against the human PrRP-31 peptide. PrRP-positive neurons were noted mainly in two areas of the caudal medulla: ventrolateral reticular formation and commissural nucleus of the nucleus of the solitary tract (NTS), corresponding to the A1 and A2 areas. PrRP-LI neurons were absent in the medulla rostral to the area postrema. Double-labeling the sections with PrRP antisera and tyrosine hydroxylase (TH) monoclonal antibodies revealed extensive colocalization of PrRP- and TH-like immunoreactivity (TH-LI) in neurons of the A1 and A2 areas. Our results show that PrRP-LI is expressed in a population of A1 and A2 noradrenergic neurons of the rat caudal medulla.

Estrogen, the ovary, and neutotransmitters: factors associated with aging

Our studies in the C57BL/6J mouse have been designed to examine the interactions of aging and the ovary, and their mutual effects on neuroendocrine function. In the pituitary, ovarian status and not age determines responsiveness to gonadotropin hormone releasing hormone (GnRH), but estrogen (E2) is an important mediator in CNS changes, and removal of the ovary (OVX) is deleterious to the neuroendocrine hypothalamus. OVX for just six days in young animals results in synaptic loss between noradrenergic terminals and gonadotropin hormone releasing hormone (GnRH) neurons. Long-term OVX, hypothesized to protect against neuroendocrine aging, fails to guard against any studied age-related changes. Some age-related changes occur as early as midlife. Although neuron number remains constant at middle age, opiatergic neurons undergo significant functional changes by producing opiate antagonist peptides. This change appears to be caused by alterations in the prohormone convertases, which cleave propeptide to peptide. Altered peptides may trigger the loss of reproductive capacity. The midlife shift in opiate peptide production is a component of natural developmental processes that begin in the neonate and continue through old age. In the cholinergic system, E2 mediates numbers of cholinergic receptors, cholinergic neurons, and cholinergic-modulated memory systems in both young and old animals. Regardless of age, ovarian steroids, if present at physiologic levels, are beneficial to the neuroendocrine CNS, and long-term deprivation from ovarian-produced factors is deleterious in the systems we have examined. Our studies have shown that deprivation from ovarian steroid hormones in the female appears to be a major factor in the health of the CNS and in events associated with aging.

Norepinephrine stimulates mitogen-activated protein kinase activity in GT1-1 gonadotropin-releasing hormone neuronal cell lines

The GT1-1 GnRH neuronal cell lines exhibit highly differentiated properties of GnRH neurons. We have used GT1-1 cells to study the roles of norepinephrine (NE), membrane depolarization, calcium influx, and phorbol esters in the regulation of mitogen-activated protein (MAP) kinase. NE, which is known to stimulate the release of GnRH, induced MAP kinase activity, the tyrosine phosphorylation of MAP kinase, and MAP kinase kinase activity. Forskolin led to activation of MAP kinase comparable with that induced by NE, and a selective inhibitor of cAMP-dependent protein kinase, H8, attenuated the NE-induced activation of MAP kinase. On the other hand, elimination of extracellular calcium by EGTA completely blocked NE-induced tyrosine phosphorylation of MAP kinase, and a selective inhibitor of calcium/calmodulin-dependent protein kinase, KN-62, attenuated the NE-induced activation of MAP kinase. Furthermore, depolarization of GT1-1 cells with 75 mM KCl, 10 microM BayK 8644, or 1 microM calcium ionophore (A23187) induced rapid tyrosine phosphorylation of MAP kinase. The omission of calcium from the extracellular medium completely abolished these effects of tyrosine phosphorylation of MAP kinase. Phorbol 12-myristate 13-acetate (PMA) also induced MAP kinase activity, but pretreatment of the cultured cells with PMA to down-regulate protein kinase C did not abolish the activation of MAP kinase by NE. In addition, although phosphorylation of Raf-1 kinase was stimulated by PMA, this phosphorylation was not induced by either NE or A23187. These results demonstrate that NE activates MAP kinase directly in GT1-1 cells, and that the effect of NE is mediated by increase in the cAMP level and by calcium influx, but not by PMA-sensitive protein kinase C or Raf-1 kinase.

Regulation of gonadotropin-releasing hormone gene expression in vivo and in vitro

The pulsatile release of gonadotropin-releasing hormone (GnRH) into the portal vasculature is responsible for the maintenance of reproductive function. Levels of GnRH decapeptide available for this process can be regulated at transcriptional, posttranscriptional, and posttranslational levels. In the immortalized neuronal GT1 cell lines which synthesize and secrete GnRH, regulation of GnRH biosynthesis has been studied using activators of the protein kinase A (PKA), protein kinase C (PKC), and calcium second messenger systems. These substances, while stimulating GnRH release, cause a universal inhibition of all biosynthetic indices measured to date, including decreases in transcription of the proGnRH gene, GnRH mRNA levels, mRNA stability, and translational efficiency. In contrast, in the animal, the mechanism for the regulation of GnRH gene expression appears to be primarily posttranscriptional, since changes in GnRH mRNA levels often occur in the absence of changes in GnRH primary transcript levels an index of GnRH gene transcription. For example, GnRH mRNA levels increase in response to stimulation with glutamate analogs, while GnRH primary transcript levels are unchanged. However, parallel changes in GnRH mRNA and primary transcript have been observed on proestrus prior to the LH/GnRH surge, suggesting that the regulation of GnRH mRNA levels in vivo involves a complex interplay of transcriptional and posttranscriptional processes.

Distribution of catecholamine-synthesizing enzymes and some neuropeptides in the median eminence-arcuate nucleus complex (MEARC) of the immature female pig

The presence of the catecholamine-synthesizing enzymes tyrosine hydroxylase (TH) and dopamine-beta-hydroxylase (D beta H) and some neuropeptides, including neuropeptide Y (NPY), Leu5-enkephalin (LENK), vasoactive intestinal polypeptide (VIP), calcitonin gene-related peptide (CGRP), substance P (SP), galanin (GAL) and somatostatin (SOM) was investigated in nerve fibres and perikarya of the median eminence-arcuate nucleus complex (MEARC) of the sexually immature female pigs by means of the immunohistochemical avidin-biotin complex method. Although immunoreactivities to all the studied substances were found in nerve fibres of the porcine MEARC, there were differences in the distribution and density of particular subsets of nerve fibres within the complex. While loose D beta H-immunoreactive (D beta H-IR) and dense TH-, NPY- and VIP-IR nerve meshworks occurred predominantly in the internal layer of the MEARC, nerve fibres immunoreactive to TH, CGRP, SOM, SP and LENK were more numerous in the external than in the internal layer of the median eminence (ME). Numerous TH-, D beta H-, NPY-, VIP-, SP- and CGRP-IR perivascular nerve fibres were also observed within both layers of the median eminence. There were also differences in the distribution of a particular subset of neurons within the porcine MEARC: NPY-, VIP-, GAL-, SP- and TH-IR (but not D beta H-IR) perikarya were found in the arcuate nucleus, while in the median eminence only subpopulations of NPY-, VIP and GAL-IR neurons were observed.

Nervus terminalis ganglion of the bonnethead shark (Sphyrna tiburo): evidence for cholinergic and catecholaminergic influence on two cell types distinguished by peptide immunocytochemistry

The nervus terminalis is a ganglionated vertebrate cranial nerve of unknown function that connects the brain and the peripheral nasal structures. To investigate its function, we have studied nervus terminalis ganglion morphology and physiology in the bonnethead shark (Sphyrna tiburo), where the nerve is particularly prominent. Immunocytochemistry for gonadotropin-releasing hormone (GnRH) and Leu-Pro-Leu-Arg-Phe-NH2 (LPLRFamide) revealed two distinct populations of cells. Both were acetylcholinesterase positive, but LPLR-Famide-immunoreactive cells consistently stained more darkly for acetylcholinesterase activity. Tyrosine hydroxylase immunocytochemistry revealed fibers and terminal-like puncta in the ganglion, primarily in areas containing GnRH-immunoreactive cells. Consistent with the anatomy, in vitro electrophysiological recordings provided evidence for cholinergic and catecholaminergic actions. In extracellular recordings, acetylcholine had a variable effect on baseline ganglion cell activity, whereas norepinephrine consistently reduced activity. Electrical stimulation of the nerve trunks suppressed ganglion activity, as did impulses from the brain in vivo. During electrical suppression, acetylcholine consistently increased activity, and norepinephrine decreased activity. Muscarinic and, to a lesser extent, alpha-adrenergic antagonists both increased activity during the electrical suppression, suggesting involvement of both systems. Intracellular recordings revealed two types of ganglion cells that were distinguishable pharmacologically and physiologically. Some cells were hyperpolarized by cholinergic agonists and unaffected by norepinephrine; these cells did not depolarize with peripheral nerve trunk stimulation. Another group of cells did depolarize with peripheral trunk stimulation; a representative of this group was depolarized by carbachol and hyperpolarized by norepinephrine. These and other data suggest that the bonnethead nervus terminalis ganglion contains at least two cell populations that respond differently to acetylcholine and norepinephrine. The bonnethead nervus terminalis ganglion appears to differ fundamentally from sensory and autonomic ganglia but does share some features with the neural circuits of forebrain GnRH systems.

An alpha 1 adrenergic mechanism mediates estradiol stimulation of LHRH mRNA synthesis and estradiol inhibition of POMC mRNA synthesis in the hypothalamus of the prepubertal female rat

We showed previously that the surge of luteinizing hormone-releasing hormone (LHRH) induced by estradiol-17 beta (E2) in the female rat can be blocked by an alpha 1 adrenergic antagonist. The aim of the present study was to determine whether this was due to a direct action of E2 on noradrenergic projections to LHRH neurons or whether it also involved other systems such as the arcuate pro-opiomelanocortin (POMC) neurons which are thought to inhibit LHRH biosynthesis and release. The experimental preparation was the prepubertal female rat in which an LHRH surge is induced by pregnant mare serum gonadotropin. Prazosin was used as a specific alpha 1 adrenergic antagonist and LHRH and POMC mRNA concentrations and cell numbers, in the medial preoptic area and rostral arcuate nucleus, respectively, were determined by in situ hybridization. Prazosin significantly reduced the total number of LHRH mRNA expressing cells, and increased the total number of POMC mRNA expressing cells and the concentration of POMC mRNA per cell. These results suggest that the inhibition of E2-stimulated LHRH biosynthesis and release by alpha 1 adrenergic blockade may be mediated by two mechanisms; (i) increased POMC synthesis leading to inhibition of LHRH neurons and (ii) direct inhibition of a stimulatory alpha 1 adrenergic/LHRH mechanism.

Origin of noradrenergic projections to GnRH perikarya-containing areas in the medial septum-diagonal band and preoptic area

The purpose of the present study was to identify the sites of origin of the noradrenergic fibers that project to areas containing gonadotropin-releasing hormone (GnRH) perikarya since norepinephrine (NE) is known to influence the activity of GnRH neurons. Fluorescent retrograde tracers were used in combination with immunohistochemistry for dopamine-beta-hydroxylase (DBH) and GnRH. Small volumes of either Fluoro-gold (FG) or Fluoro-Ruby (FR) were pressure injected into areas that contain the largest number of GnRH cell bodies, i.e., the medical septum-diagonal band complex or preoptic area. Retrogradely labeled neurons were observed ipsilaterally in the following noradrenergic cell groups: A2 (in the nucleus tractus solitarii), A1 (in the ventrolateral medulla) and locus coeruleus. Approximately 8% of all DBH-positive neurons within the A2-cell group were retrogradely labeled, while 12% of DBH-ir neurons in the A1-group were double-labeled. Only a few retrogradely labeled DBH-ir neurons were observed in the locus coeruleus (< 1%). Double-labeled neurons were not organized into discrete cell groups, but were dispersed among other NE-neurons within the A2- and A1-cell groups. The highest concentrations of double-labeled neurons were located in the central one-third of both the A2 and A1 cell groups. The results suggest that most noradrenergic terminals in the region of the GnRH perikarya in the medial septum-diagonal band/rostral preoptic area originate from ipsilateral neurons in areas A1 and A2.(ABSTRACT TRUNCATED AT 250 WORDS)

High-affinity uptake of noradrenaline in postsynaptic neurones

1. Neurotransmitters released from nerve endings are inactivated by re-uptake into the presynaptic nerve terminals and possibly into neighbouring glial cells. While analysing the functional properties of alpha 1-adrenoceptors in the hypothalamus, we observed a high-affinity uptake process for noradrenaline in postsynaptic peptidergic neurones. 2. In primary hypothalamic cell cultures and in a hypothalamic neuronal cell line, [3H]-prazosin bound with high affinity and was displaced by unlabelled prazosin in concentrations of 10(-10) to 10(-7) M. However, at concentrations of unlabelled prazosin above 10(-7) M, there was a paradoxical increase in apparent [3H]-prazosin binding. 3. Methoxamine, an alpha 1-adrenoceptor ligand that is not subject to significant neuronal uptake, displaced [3H]-prazosin but did not cause the paradoxical increase in the apparent binding of [3H]-prazosin. Cooling the cells to 4 degrees C reduced the total amount of prazosin associated with the cells; under these conditions, methoxamine almost completely inhibited [3H]-prazosin binding to the cells. 4. In the presence of desipramine (DMI), unlabelled prazosin displaced [3H]-prazosin as before, but no paradoxical increase in apparent binding was seen above 10(-7) M. 5. The paradoxical increase of [3H]-prazosin binding was not observed in membrane preparations of hypothalamic neurones. These findings indicated that the paradoxical increase in apparent [3H]-prazosin binding was due to a cellular uptake process that becomes evident at high concentrations of the ligand. 6. DMI (10(-5) M) had no effect on the specific binding of [3H]-prazosin. The presence of alpha1-adrenoceptors was confirmed by binding of [125]-HEAT, but [3H]-idazoxan (an alpha2- ligand) did not bind to the cells.7. The uptake of prazosin obeyed the Michaelis-Menten model, with similar Km and Vmax values in both types of cultures.8. Noradrenaline was taken up with high affinity by both types of cultures. (+/-)-[3H]-noradrenaline uptake was reduced by DMI and by excluding sodium from the medium, indicating that this process has some of the properties of uptake 1. (+/-)-[3H]-noradrenaline uptake in the cell line was unaffected by testosterone.9. The measured uptake of (-)-noradrenaline in the cell line was considerably increased by blockade of catechol-omicron-methyl-transferase and monoamine oxidase, suggesting that (-)-noradrenaline is metabolized to lipophilic products that escape across the plasma membrane.10. Studies in rats, in which the noradrenaline isomer 6-hydroxydopamine was used, suggested that the post synaptic uptake process is operative in hypothalamic CRH and vasopressin neurones in vivo.11. The Km for (-)-noradrenaline was within the range for the high affinity uptake, process in noradrenergic neurones. Uptake takes place in concentrations at which noradrenaline activates alpha1-adrenoceptors.Removal of noradrenaline from the vicinity of the receptors may prevent desensitization,thus maintaining the responsiveness of postsynaptic neurones to the actions of the neurotransmitter.

Neuronal projections to the medial preoptic area of the sheep, with special reference to monoaminergic afferents: immunohistochemical and retrograde tract tracing studies

The preoptic area contains most of the luteinizing hormone releasing hormone immunoreactive neurons and numerous monoaminergic afferents whose cell origins are unknown in sheep. Using tract tracing methods with a specific retrograde fluorescent tracer, fluorogold, we examined the cells of origin of afferents to the medial preoptic area in sheep. Among the retrogradely labeled neurons, immunohistochemistry for tyrosine hydroxylase, dopamine-beta-hydroxylase, phenylethanolamine N-methyltransferase, and serotonin was used to characterize catecholamine and serotonin fluorogold labeled neurons. Most of the afferents came from the ipsilateral side to the injection site. It was observed that the medial preoptic area received major inputs from the diagonal band of Broca, the lateral septum, the thalamic paraventricular nucleus, the lateral hypothalamus, the area dorsolateral to the third ventricle, the perimamillary area, the amygdala, and the ventral part of the hippocampus. Other numerous, scattered, retrogradely labeled neurons were observed in the ventral part of the preoptic area, the vascular organ of the lamina terminalis, the ventromedial part of the hypothalamus, the periventricular area, the area lateral to the interpeduncular nucleus, and the dorsal vagal complex. Noradrenergic afferents came from the complex of the locus coeruleus (A6/A7 groups) and from the ventro-lateral medulla (group A1). However, dopaminergic and adrenergic neuronal groups retrogradely labeled with fluorogold were not observed. Serotoninergic fluorogold labeled neurons belonged to the medial raphe nucleus (B8, B5) and to the serotoninergic group situated lateral to the interpeduncular nucleus (S4). In the light of these anatomical data we hypothesize that these afferents have a role in the regulation of several functions of the preoptic area, particularly those related to reproduction. Accordingly these afferents could be involved in the control of luteinizing hormone releasing hormone (LHRH) pulsatility or of preovulatory LHRH surge.

Adrenergic control of the secretion of anterior pituitary hormones

The hypothalamic hypophysiotrophic neurones are densely innervated by adrenergic and noradrenergic nerve terminals. Activation of alpha 1-adrenoceptors located in the brain stimulates the secretion of ACTH, prolactin and TSH. The effects of the alpha 1-adrenoceptors seem to be exerted on hypothalamic neurones that secrete vasopressin, CRH-41 and TRH. These mechanisms are important in the physiological control of the secretion of ACTH and TSH in humans. alpha 2-Adrenoceptors are not involved in the control of secretion of these hormones under basal conditions in humans. However, alpha 2-adrenoceptors exert an inhibitory effect that acts as a negative feedback mechanism, limiting excessive secretion of these hormones. There is no convincing evidence for the involvement of beta-adrenoceptors in the control of the secretion of these three hormones in humans. Studies on cultured anterior pituitary cells suggested that adrenaline and noradrenaline may influence the secretion of ACTH, prolactin and TSH directly at the level of the pituitary. However, these effects are not demonstrable in humans, and are likely to be due to alterations in the pituitary adrenoceptors during culture. In the case of growth hormone, activation of alpha 2-adrenoceptors located in the brain stimulates secretion of this hormone both by increasing the secretion of GHRH and by inhibiting the secretion of somatostatin. Activation of beta-adrenoceptors inhibits the secretion of growth hormone via an increase in the secretion of somatostatin. The effects of the central alpha 2- and beta-adrenoceptors are important in the physiological control of growth hormone secretion in humans. A considerable amount of evidence implicates brain alpha 1-adrenoceptors in the control of secretion of the gonadotrophins in experimental animals, but, despite intensive study, no convincing evidence has been found in humans of reproductive age.

Alpha 1 adrenergic regulation of estrogen-induced increases in luteinizing hormone-releasing hormone mRNA levels and release

Prazosin, an alpha 1 adrenergic antagonist, was used to examine the relationship between adrenergic inputs and the stimulatory effects of estrogen on LHRH mRNA and release. Bilateral cannulae were implanted just dorsal to the preoptic area (POA). Estrous cycles were monitored daily by vaginal smears. On the morning of diestrus, each rat was ovariectomized and assigned to one of three treatment groups: Control--injected with sesame oil (n = 5); Surge--injected with estradiol benzoate (EB, 10 micrograms) to produce an LH surge (n = 5); or, Surge+Prazosin--injected with EB and a prazosin-filled inner cannula was put into the POA (n = 6). Between 4-6 pm of the following day, rats were anesthetized, decapitated, trunk blood collected, and brains were stored in liquid nitrogen. In situ hybridization was performed using a 32P end-labelled 59-mer complementary to LHRH mRNA. Reduced silver grains, proportional to LHRH mRNA content, were quantified. Treatment with estrogen alone resulted in an LH surge and a 50% increase (P < 0.05) in numbers of cells expressing LHRH. This estrogen-induced increase and the LH surge were completely blocked (P < 0.01) by prazosin. Prazosin also decreased (P < 0.01) the median number of grains per cell from 81 (Surge) to 65 grains per cell (Surge+Prazosin). When the number of grains in LHRH-expressing neurons were totalled, EB increased (P < 0.05) LHRH gene expression by 53%, and local administration of prazosin completely blocked (P < 0.01) this increase.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of administration of an analog of LHRH on appetitive learning in young and middle-aged female rats

Hypothalamic luteinizing hormone-releasing hormone (LH-RH) had been reported to induce changes in defensive learning. In middle age, females exhibit a decline in their reproductive axis. Several studies in rodents suggested that hypothalamic LHRH function deteriorated in middle-aged females. Our experiments compare T-maze learning in young and middle-aged female rats and study the effect of administration of an analog of LHRH, D-Trp6-LHRH. The ovarian action of the analog was studied and a gonadectomized control group was added. No differences were observed between young and middle-aged females in acquisition, retention, and reversal of a simple discrimination in the T-maze. However, after removal of motor and spatial cues acquisition of the discrimination on visual cues was impaired in middle-aged females compared to young mature ones. Administration of D-Trp6-LHRH enhanced performance during the visual discrimination in younger females and had no action in middle-aged ones, whereas it inhibited ovary function in both groups. Ovariectomy had no effect. These results suggest a direct effect of the analog of LHRH on the CNS and show that this peptide fails to counteract the deleterious effect of age on performance.

Proteoglycan synthesis in normotensive and spontaneously hypertensive rat arteries in vitro

Proteoglycans (PGs) were analyzed and compared in the media of the thoracic aorta, abdominal aorta, left carotid artery and superior mesenteric artery of age-matched Wistar-Kyoto (WKY) and spontaneously hypertensive (SHR) rats. Two ages were examined; 10 week old, during the development of hypertension and 28 week old, when hypertension is well established in the SHR. Large chondroitin sulfate PG, large heparan sulfate PG and biglycan (PGI) and decorin (PGII) small PGs were identified. Biglycan was the predominant small PG found in all arteries. Newly synthesized PGs were labelled in vitro with 35SO4 for quantitation. The synthesis of large and small PGs was similar in the media of the thoracic aorta, abdominal aorta, left carotid artery, and superior mesenteric artery. The large to small ratio value, a measure of the artery PG composition, was also similar among the four arteries but was highest in the mesenteric artery. In both WKY and SHR arteries there was significantly decreased PG synthesis in the 28-week old compared to 10-week old animals. This was especially true for large PG. Hypertensive changes in PG synthesis were seen mainly in the carotid artery. In this artery, synthesis of both large and small PG was increased in the SHR, at both ages. The ratio of large to small PG was not significantly different between SHR and WKY arteries. We conclude that 28-week old WKY and SHR rat arteries synthesize less large and small PG than 10-week old arteries. The most prominent change seen in hypertensive rats is an increase in PG synthesis in the carotid artery.

cFos Activity Identifies Recruitment of Luteinizing Hormone-Releasing Hormone Neurons During the Ascending Phase of the Proestrous Luteinizing Hormone Surge

The proto-oncogene product of the c-fos gene, cFos, is a useful marker for luteinizing hormone-releasing hormone (LHRH) neuronal activation. While recent data indicate that in the rat, an LHRH surge plays an active role in stimulating the proestrous luteinizing hormone (LH) surge, the mechanics of the LHRH surge remain unknown. The aim of this study was to determine whether LHRH neuronal activation occurs entirely at the beginning of the LH surge or whether the number of LHRH neurons activated increases during the ascending phase of the surge. To accomplish this aim, we determined the relationship between the number of LHRH neurons expressing cFos and LH concentrations during the ascending limb of the proestrous LH surge. During the estrous cycle in the rat, on the afternoon of proestrus, the number of LHRH neurons expressing cFos increased as plasma LH levels increased to reach peak concentrations. The regression line describing these two variables had a very highly significant correlation coefficient, indicating a linear relationship. Treatment with RU486 to block progesterone's action on the afternoon of proestrus significantly reduced both the number of LHRH neurons expressing cFos and the magnitude of LH secretion during the entire ascending phase of the LH surge. An analysis of covariance with comparison of regression lines from untreated and RU486-treated animals revealed that while both sets of data established significant linear relationships between the degree of activation of LHRH neurons and plasma LH values, the slopes of the two lines were different (P = 0.031) with no statistical difference in the two intercepts. These data, together with the demonstration of an overall reduction of cFos intensity following removal of progesterone's actions, suggest progesterone alters the dynamics of LHRH neuronal activation by significantly reducing the recruitment of LHRH neurons and suppressing the level of activation of individual LHRH neurons. The results of our study support the hypothesis that the ascending phase of the LH surge results from the gradual recruitment of LHRH neurons into the active state.

Neuroendocrine regulation of the luteinizing hormone-releasing hormone pulse generator in the rat

We have analyzed the mechanisms by which several known regulators of the LHRH release process may exert their effects. For each, we have attempted to determine how and where the regulatory input is manifest and, according to our working premise, we have attempted to identify factors which specifically regulate the LHRH pulse generator. Of the five regulatory factors examined, we have identified two inputs whose primary locus of action is on the pulse-generating mechanism--one endocrine (gonadal negative feedback), and one synaptic (alpha 1-adrenergic inputs) (see Fig. 29). Other factors which regulate LHRH and LH release appear to do so in different ways. The endogenous opioid peptides, for example, primarily regulate LHRH pulse amplitude (Karahalios and Levine, 1988), a finding that is consistent with the idea that these peptides exert direct postsynaptic or presynaptic inhibition (Drouva et al., 1981). Gonadal steroids exert positive feedback actions which also result in an increase in the amplitude of LHRH release, and this action may be exerted through a combination of cellular mechanisms which culminate in the production of a unique, punctuated set of synaptic signals. Gonadal hormones and neurohormones such as NPY also exert complementary actions at the level of the pituitary gland, by modifying the responsiveness of the pituitary to the stimulatory actions of LHRH. The LHRH neurosecretory system thus appears to be regulated at many levels, and by a variety of neural and endocrine factors. We have found examples of (1) neural regulation of the pulse generator, (2) hormonal regulation of the pulse generator, (3) hormonal regulation of a neural circuit which produces a unique, punctuated synaptic signal, (4) hormonal regulation of pituitary responsiveness to LHRH, and (5) neuropeptidergic regulation of pituitary responsiveness to LHRH. While an attempt has been made to place some of these regulatory inputs into a physiological context, it is certainly recognized that the physiological significance of these mechanisms remains to be clarified. We also stress that these represent only a small subset of the neural and endocrine factors which regulate the secretion or actions of LHRH. A more comprehensive list would also include CRF, GABA, serotonin, and a variety of other important regulators. Through a combination of design and chance, however, we have been able to identify at least one major example of each type of regulatory mechanism.

Metabolic regulation by alpha 1- and alpha 2-adrenoceptors

The role of alpha-adrenoceptors in the mediation of autonomic function, particularly in the control of the cardiovascular system, is widely known. However, alpha-adrenoceptors are also important in the regulation of a variety of metabolic processes that occur in the body either through direct action or by stimulation of the release of other mediators that control metabolic function. Thus, alpha 2-adrenoceptor activation by circulating or neuronally released catecholamines inhibits the release of insulin from pancreatic islet beta-cells and, by inhibiting this response, alpha 2-adrenoceptor antagonists have been shown to have an antihyperglycemic effect. The alpha-adrenoceptor-mediated regulation of the release of pituitary hormones is indirect, with alpha-adrenoceptors being located on peptidergic neurons in the hypothalamus that secrete releasing hormones into the hypophysial portal system to regulate the secretion of hormones from the anterior pituitary gland. Thus, the increase in cortisol secretion from the adrenal glands following a meal is produced, at least in part, by an alpha 1-adrenoceptor-mediated increase in vasopressin and CRF-41 secretion from neurons on the hypothalamus that stimulate the release of adrenocorticotrophic hormone secretion from the pituitary gland, which subsequently stimulates the synthesis and release of cortisol from the adrenal medulla. In addition to metabolic regulation by alpha 1- and alpha 2-adrenoceptors within the endocrine system, alpha-adrenoceptors are also a component of the system that regulates certain aspects of metabolism within autonomic effector cells, such as the control of smooth muscle cell division and growth during periods of continued alpha-adrenoceptor activation as a result of activation of second messenger systems.

Interactions between opioid peptides and adrenaline-containing neurons modulate luteinizing hormone secretion in male rats

Abstract There is increasing evidence that the opioid inhibition of luteinizing hormone (LH) secretion is mediated, at least in part, by catecholaminergic mechanisms. This study determined the effects of selective manipulation of noradrenergic and adrenergic systems on the ability of opiate receptor blockade to induce the release of LH in adult male rats. Selective depletion of hypothalamic noradrenaline levels by 80% following 6-hydroxydopamine infusions into the central tegmental tract did not alter the 2- to 3-fold increase in serum LH levels following opiate receptor blockade with naloxone (2.5 mg/kg). In contrast, both selective depletion of hypothalamic adrenaline by prior treatment with the phenylethanolamine N-methyltransferase inhibitor, LY134046 (2 x 50 mg/kg) and non-selective depletion of all three catecholamines with alpha-methyl-p-tyrosine (250 mg/kg), abolished the naloxone-induced increase in LH. These results suggest that the inhibition of LH secretion by endogenous opioid peptides is influenced by catecholaminergic neurotransmission and further support the view that adrenaline rather than noradrenaline or dopamine is of importance in this context.

Ontogenesis of tyrosine hydroxylase-immunopositive structures in the rat hypothalamus. An atlas of neuronal cell bodies

The development of the catecholaminergic system in the hypothalamus and in the septal region was studied in rats from the 12th fetal day until the 9th postnatal day. Catecholaminergic structures were visualized with pre-embedding immunocytochemistry using antiserum to tyrosine hydroxylase. An intensification of diaminobenzidine product with silver and gold was additionally applied to make the immunocytochemical technique more sensitive. In this paper only the data on the appearance and distribution of the tyrosine hydroxylase-immunopositive neurons (cell bodies) are presented, whereas the catecholaminergic innervation of the hypothalamus with the tyrosine hydroxylase-immunopositive fibers is the topic of an accompanying paper. Sparse tyrosine hydroxylase-immunopositive neurons were first observed in the anlage of the hypothalamus and septal region on the 13th fetal day. Their number increased progressively with age and by the 15th fetal day they already gave rise to a large dorsal accumulation. From the 18th fetal day on, tyrosine hydroxylase immunopositive neurons began to occupy their definitive positions, mainly concentrating within the hypothalamus: in the zona incerta, periventricular and arcuate nuclei. To a lesser extent, they were concentrated in the medial preoptic area, suprachiasmatic, supraoptic, paraventricular, dorsomedial, and anterior hypothalamic nuclei. The data on the distribution of the tyrosine hydroxylase-immunopositive neurons both in the hypothalamus and in the septal region during ontogenesis are summarized in the precise atlas. Primarily small bi- and unipolar catecholaminergic neurons first observed in the youngest fetuses undergo cytodifferentiation during ontogenesis, giving rise to at least two different populations localized ventrally, mainly in the arcuate nucleus, and dorsally, in the zona incerta. The neurons of the former population remain similar to those of the youngest fetuses, whereas the neurons of the latter increase significantly in size, forming several long, highly ramified processes.

Ontogenesis of tyrosine hydroxylase-immunopositive structures in the rat hypothalamus. Fiber pathways and terminal fields

The innervation of the hypothalamus and septal region by catecholaminergic fibers was studied in rats from the 12th fetal day until the 9th postnatal day. Catecholaminergic fibers were visualized with preembedding immunocytochemistry using antibodies to tyrosine hydroxylase. An intensification of diaminobenzidine product with silver and gold was additionally applied to increase the sensitivity and resolution power of the routine immunocytochemical technique. It has been demonstrated that, from the 13th fetal day, the hypothalamus and the septal region receive catecholaminergic fibers either belonging to the hypothalamic neurons or coming with the medial forebrain bundle from the outside of the hypothalamus. As the development of the hypothalamus proceeds, these fibers form the extensive networks within some neurosecretory centers either containing (the zona incerta, periventricular nucleus, etc.) or almost lacking (suprachiasmatic and paraventricular nuclei) the catecholaminergic neurons. In the former case, they terminate on the processes or perikarya of catecholaminergic neurons, while in the latter case their varicosities surround the immunonegative presumptive neurons in a basket-like manner. Moreover, from the 18th fetal day catecholaminergic fibers penetrate between the ependymal cells towards the 3rd ventricle and the primary capillary plexus of the hypophysial portal circulation, apparently providing the release of catecholamines to the cerebrospinal fluid and portal blood, respectively. The data obtained in this study are considered as the morphological basis for the involvement of the hypothalamic catecholamines in neuroendocrine regulations during ontogenesis.

Blockade of LHRH-induced lordosis by alpha- and beta-adrenergic antagonists in ovariectomized, estrogen primed rats

The participation of a noradrenergic mechanism in the facilitation of lordosis by luteinizing hormone-releasing hormone (LHRH) was studied in two groups of ovariectomized estrogen primed rats, with or without sexual experience. The administration of 5 micrograms estradiol benzoate (EB) alone to sexually inexperienced subjects (Ss) induced weak lordosis behavior in some of them (mean lordosis quotient, LQ = 12 +/- 19). The SC injection of 5 micrograms LHRH significantly increased this response four hours later (LQ = 38 +/- 41), though great variability was observed (59% of Ss showing LQs below 30). The systemic administration of either prazosin, an alpha-adrenergic antagonist (0.2 or 1 mg/kg), or propranolol, a beta-adrenergic antagonist (20 mg/kg), totally suppressed LHRH-induced lordosis in sexually inexperienced Ss (mean LQs = 8 +/- 11; 5 +/- 10; 18 +/- 31, respectively). In sexually experienced Ss (tested on two previous occasions with EB and LHRH) the administration of EB alone on a third test induced significant levels of lordosis (mean LQ = 51 +/- 41). The administration of 5 micrograms LHRH to sexually experienced, estrogen primed Ss induced near maximal levels of lordosis (LQ = 94 +/- 18). In these Ss, prazosin (0.2 and 1 mg/kg) and, to a lesser extent, propranolol (20 mg/kg) significantly depressed lordosis to values that were not significantly different from those obtained after EB alone (mean LQs = 59 +/- 38; 63 +/- 20; 74 +/- 32, respectively). These results indicate that blockade of noradrenergic transmission by either alpha- or beta-antagonists counteracts the stimulatory effect of LHRH on lordosis in ovariectomized estrogen primed rats with or without sexual experience.(ABSTRACT TRUNCATED AT 250 WORDS)

Slice cultures of LHRH neurons in the presence and absence of brainstem and pituitary

Luteinizing hormone releasing hormone (LHRH) neurons from the preoptic area (POA)/hypothalamus of the postnatal rat were cultured for up to 7 weeks using a slice explant roller culture technique. The slices thinned to quasi-monolayers, but maintained organotypic distributions of large numbers of immunocytochemically identifiable LHRH, neurotensin, tyrosine hydroxylase, neurophysin and corticotropin releasing hormone-containing neurons. The distribution, survival and morphology of LHRH cells in co-cultures with brainstem and anterior pituitary was quantitated, and found to be similar to that observed in single cultures. LHRH fibers grew into either pituitary or brainstem tissue, however when all three tissues were co-cultured, LHRH fibers preferentially invaded the pituitary. LH immunoreactive anterior pituitary gonadotropes were maintained only in co-cultures containing POA/hypothalamic slices, and addition of an LHRH antagonist in such cultures, inhibited LH immunoreactivity in the gonadotropes. This slice explant roller culture method effectively maintains the cyto- and chemoarchitecture and functional properties of the LHRH system for long periods in vitro and should provide excellent models for studying the interactive and molecular characteristics of postnatal LHRH neurons.

Ultrastructure and synaptic organization of luteinizing hormone-releasing hormone (LHRH) neurons in the anestrous ewe

Electron microscopic immunocytochemistry was employed to examine the ultrastructure of luteinizing hormone-releasing hormone (LHRH) neurons and their projections to the median eminence in the sheep brain. LHRH perikarya in the preoptic area of anestrous ewes are less innervated than nonimmunoreactive cells in the same sections, but still receive numerous synaptic inputs, primarily onto distal dendrites and small somatic protuberances. Axon terminals synapsing upon LHRH cells contain a combination of clear spherical vesicles and larger dense-core vesicles. Interestingly, LHRH cell bodies and dendrites are almost entirely surrounded by glial processes. These processes intervene between immunoreactive elements that at a light microscopic level appear to be in contact with each other. Thus no evidence was obtained at the ultrastructural level for contacts among adjacent LHRH cells or dendrites in the preoptic area. Synaptic inputs onto LHRH cell bodies and dendrites appear to penetrate this glial sheath. In contrast to the absence of contacts among LHRH cells in the preoptic area, individual LHRH terminals in the median eminence are often clustered in direct plasma membrane contact. Comparisons between animals of differing reproductive status are needed to determine whether alterations in synaptic inputs, glial ensheathment, or LHRH-LHRH appositions, may underlie seasonal changes in the activity of LHRH neurons.

Peripubertal development of noradrenergic stimulation of luteinizing hormone-releasing hormone neurosecretion in vitro

The effect of age on norepinephrine (NE) stimulation of luteinizing hormone-releasing hormone (LH-RH) secretion from preoptic area-mediobasal hypothalamic (POA-MBH) explants was examined in the present study. Explants were obtained from juvenile (9-day-old), prepubertal (29-day-old) and adult female rats. Following decapitation and surgical isolation, POA-MBH explants were individually perifused with culture medium which was collected for radioimmunoassay of LH-RH. Explants were exposed to two pulses of medium containing NE (5 x 10(-4) M, peak concentration) and a terminal pulse of medium containing KCl (45 mM, peak concentration) for assessment of viability. POA-MBH explants obtained from prepubertal female rats exhibited increased LH-RH release in response to the two pulses of NE and subsequent KCl pulse (P less than 0.05). NE was without effect in stimulating LH-RH neurosecretion from POA-MBH explants obtained from 9-day-old female rats although these explants were responsive to KCl (P less than 0.01). Two-day pretreatment of 9-day-old, and prepubertal rats with estradiol benzoate (EB) did not alter the LH-RH response to this dose of NE or KCl (no group or interaction effects) in prepubertal female rat explants and did not render the explants from 9-day-old rats responsive to NE. Furthermore, NE was equally effective in stimulating LH-RH release from explants obtained from estradiol-treated or control ovariectomized adult rats. These observations demonstrate a peripubertal activation of the stimulatory effect of NE on LH-RH release from POA-MBH explants in vitro. Although these data also suggest that estrogen is not obligatory for NE stimulation of LH-RH release from POA-MBH explants, further investigation is required to determine the developmental time course and estrogen dependency of the noradrenergic stimulation of LH-RH neurosecretion and to evaluate whether estrogen alters the sensitivity of POA-MBH explants to lower concentrations of NE as has been previously reported for median eminence fragments.

Potential sites of interaction between catecholamines and LHRH in the sheep brain

A combined immunoperoxidase/immunofluorescence procedure was used to examine potential sites of overlap between catecholamine and LHRH systems in the brains of ewes sacrificed during either anestrous or the breeding season. Cells and fibers immunoreactive for either tyrosine hydroxylase (TH) or dopamine-beta-hydroxylase (DBH) were visualized in the same sections as immunopositive LHRH perikarya and fibers. TH- and DBH-positive varicosities in the preoptic area and anterior hypothalamus appeared to contact both LHRH cell bodies and their dendrites. Clusters of TH-positive cells and fibers were found in the organum vasculosum of the lamina terminalis, and partially overlapped the location of immunoreactive LHRH fibers in that structure. Immunoreactive TH and LHRH fibers were densely interspersed within the zona externa of the median eminence, particularly within its lateral portion. No obvious qualitative differences were apparent in either the distribution of catecholamine cells and fibers or their overlap with LHRH elements between the brains of anestrous and breeding season ewes. These observations suggest the possibility of catecholaminergic synaptic inputs onto LHRH neurons in the ewe, as well as the potential for interaction between catecholamines and LHRH at the level of the median eminence.

Aging changes in synaptology of luteinizing hormone-releasing hormone neurons in male rat preoptic area

This study was undertaken to examine some aspects of the anatomical substrate for reproductive senescence. Immunocytochemically identified luteinizing hormone-releasing hormone neurons and their processes in the male rat brain preoptic area were compared in young adult (2-4 months), middle-aged (12-14 months) and old (20-23 months) animals. At the light microscopic level there were no age-dependent differences in total numbers or sizes of LHRH neurons nor in their distribution in the brain. Examination of these neurons at the electron microscopic level did reveal significant differences in certain organelles and in the degree and kind of synaptic input. Random sections of middle-aged luteinizing hormone-releasing hormone neurons more frequently passed through the nucleolus and the incidence of nematosomes was higher than in luteinizing hormone-releasing hormone neurons from the young and old animals. Quantitative measures of synaptic input to luteinizing hormone-releasing hormone soma and dendrites as well as to unidentified neurons in the same thin section were made. These are reported as percent of membrane that showed synaptic structure. Dendrites of both luteinizing hormone-releasing hormone and nonidentified neurons were more densely innervated than perikarya. The density of synaptic input to luteinizing hormone-releasing hormone neurons was significantly greater than that to nonidentified neurons in young and middle-aged animals, but was equal to that of nonidentified neurons by old age. Age-related changes were noted in synaptic organization with the most significant change being an increased input to luteinizing hormone-releasing hormone perikarya. Indeed, synaptic input to luteinizing hormone-releasing hormone perikaryal membrane was increased three-fold by middle age and ten-fold by old age. Density of synaptic input to luteinizing hormone-releasing hormone dendritic membrane did not change with age. There were no aging changes in percentage of membrane with synaptic structure in nonidentified elements. Synapses were also classified on the basis of their synaptic vesicle content. There were proportionately more synaptic boutons containing round clear than pleomorphic vesicles in the young sample. The proportion of synapses with pleomorphic vesicles increased with age onto both luteinizing hormone-releasing hormone perikarya and their dendrites. The proportion of boutons containing some electron dense-core vesicles along with clear vesicles decreased with age onto both luteinizing hormone-releasing hormone and nonidentified neurons and their processes.

Distribution of luteinizing hormone-releasing hormone in the nervus terminalis and brain of the mouse detected by immunocytochemistry

Immunoreactive luteinizing hormone-releasing hormone (LHRH) was localized in a relatively large number of ganglion cells and fibers of the nervus terminalis of neonatal and adult mice, indicating that this nerve is a substantial source of LHRH in the mouse brain. Whole-head specimens of neonatal mice, prior to calcification of the cranium, revealed an extensive distribution of LHRH neurons and fine fibers throughout the peripheral, intracranial, and central parts of the nervus terminalis. The most striking difference between the neonatal and adult animals, in the nervus terminalis, was the increase in immunoreactive axons that made up the fiber bundles of this nerve. In the adult mouse, the intracranial and central projections were composed of thick fascicles of immunoreactive axons, ensheathed by glial cells and accompanied by ganglia that contained both LHRH-reactive and nonimmunoreactive neurons. LHRH-immunoreactive cells and axons were seen in a branch of the nervus terminalis that coursed along the medial, posterodorsal aspect of the olfactory bulb and in branches of this nerve that accompany the vomeronasal nerves to the accessory olfactory bulb. A few LHRH neurons and many immunoreactive processes were seen in the accessory and main olfactory bulbs. LHRH-reactive neurons were seen in the hypothalamus and extrahypothalamic structures. Examination of adult mouse brains revealed a pattern of distribution and number of immunoreactive neurons similar to that seen in the neonate. However, many more LHRH-reactive axons were seen in all areas of the brain of the mature animal.

Catecholamine innervation of LH-RH neurons: a developmental study

Catecholamine innervation of luteinizing hormone-releasing hormone (LH-RH) cell subtypes in rats was investigated over development using double label, light microscopic immunocytochemistry. Similar results were observed in both sexes. The number of catecholamine-apposed sLH-RH cells remained constant, while the number of catecholamine-apposed iLH-RH cells increased as a function of age. These results suggest that LH-RH cell subtypes are differentially innervated and support the hypothesis that the development of iLH-RH cells represent newly innervated surfaces which are related to changes in the processing of incoming information relevant to reproductive maturation.

Estrogen-dependent effects of norepinephrine on hypothalamic gonadotropin-releasing hormone release in the rabbit

In the rabbit, either coitus or intraventricular administration of norepinephrine (NE) induces gonadotropin release and ovulation. It is hypothesized that ovulation induced with these manipulations involves activation of neuronal pathways that include catecholaminergic and peptidergic neurons. The aim of this study was to examine if perfusion of NE directly through the mediobasal hypothalamus (MBH) stimulates gonadotropin-releasing hormone (GnRH) release from the MBH in ovariectomized (OVEX) and estradiol-treated OVEX does (OVEX/E2). All does were fitted with push-pull (PP) cannulae directed to the MBH and subsequently subjected to PP perfusion at a flow rate of 20 microliters/min for 6 h to measure hypothalamic GnRH release. Five OVEX/E2 and 7 OVEX does received NE that was added to the PP system (intrahypothalamic NE perfusion) at the rate of 2.5 micrograms/min for 2 h during 6 h of PP perfusion. In addition, 6 OVEX/E2 does were given intrahypothalamic perfusion of homovanillic acid (HVA), a metabolite of the adrenergic system, to serve as controls. All PP samples were collected on ice at 10-min intervals, and jugular vein blood samples were obtained at 20-min intervals. The GnRH, luteinizing hormone (LH), and follicle-stimulating hormone (FSH) were measured by specific radioimmunoassays. In OVEX/E2 does, intrahypothalamic perfusion of NE, but not HVA, stimulated a 10-fold increase in peak values of hypothalamic GnRH within 30 min, and a 3-fold increase in peak values of plasma LH within 40 min. Thereafter, both GnRH and LH levels returned to basal values by the end of the NE perfusion.(ABSTRACT TRUNCATED AT 250 WORDS)

A developmental study of the quantitative distribution of LHRH neurons within the central nervous system of postnatal male and female rats

The quantitative distribution of LHRH neurons within the central nervous system of male and female rats during postnatal development was investigated with light microscopic immunocytochemistry. Approximately 1,300 immunoreactive LHRH cells were found within the forebrain at all ages. The topographic distribution of LHRH neurons was adultlike in the earliest neonatal stage examined (2 days postnatal) and remained similar throughout development. Two LHRH cell subtypes, smooth LHRH cells and LHRH cells with spinelike processes (irregular LHRH cells), were found throughout the entire extent of the LHRH neuronal field in both sexes. A sex difference in the number of LHRH cells anterior to the organum vasculosum lamina terminalis/preoptic area (a 20% greater number in this region in females) was observed. This sex difference was present throughout development and was not limited to one specific LHRH cell subtype. These data are consistent with the hypothesis that the LHRH system is established early in postnatal development, and that the signal for reproductive maturation is related to the development of synaptic inputs to the LHRH cells.

Use of cryoprotectant to maintain long-term peptide immunoreactivity and tissue morphology

Use of an ethylene glycol based cryoprotectant solution has been found to be effective for the long-term storage of brain tissue either in block form or as freely floating sections prior to immunocytochemical processing. Storage of tissue in the solution at -20 degrees C or 4 degrees C for up to 3 months produced no adverse effects upon tissue morphology, nor was LHRH immunoreactivity diminished or accompanied by elevated non-specific staining. Furthermore, ultrastructural analysis of cryoprotected tissue revealed excellent preservation of cellular morphology. It is anticipated that this method can find use when it is necessary or desirable for the investigator to retain tissue for later immunocytochemical or electron microscopic processing.

Electron microscopic analysis of tyrosine hydroxylase, dopamine-beta-hydroxylase and phenylethanolamine-N-methyltransferase immunoreactive innervation of the hypothalamic paraventricular nucleus in the rat

The catecholaminergic innervation of the hypothalamic paraventricular nucleus (PVN) of the rat was studied by preembedding immunocytochemical methods utilizing specific antibodies which were generated against catecholamine synthesizing enzymes. Phenylethanolamine-N-methyltransferase (PNMT)-immunoreactive terminals contained 80-120 nm dense core granules and 30-50 nm clear synaptic vesicles. The labeled boutons terminated on cell bodies and dendrites of both parvo- and magnocellular neurons of PVN via asymmetric synapses. The parvocellular subnuclei received a more intense adrenergic innervation than did the magnocellular regions of the nucleus. Dopamine-beta-hydroxylase (DBH)-immunopositive axons were most numerous in the periventricular zone and the medial parvocellular subnucleus of PVN. Labeled terminal boutons contained 70-100 nm dense granules and clusters of spherical, electron lucent vesicles. Dendrites, perikarya and spinous structures of paraventricular neurons were observed to be the postsynaptic targets of DBH axon terminals. These asymmetric synapses frequently exhibited subsynaptic dense bodies. Paraventricular neurons did not demonstrate either PNMT or DBH immunoreactivity. The fibers present within the nucleus which contained these enzymes are considered to represent extrinsic afferent connections to neurons of the PVN. Tyrosine hydroxylase (TH)-immunoreactivity was found both in neurons and neuronal processes within the PVN. In TH-cells, the immunolabel was associated with rough endoplasmic reticulum, free ribosomes and 70-120 nm dense granules. Occasionally, nematosome-like bodies and cilia were observed in the TH-perikarya. Unlabeled axons established en passant and bouton terminaux type synapses with these TH-immunopositive cells. TH-immunoreactive axons terminated on cell bodies as well as somatic and dendritic spines of paraventricular parvocellular neurons. TH-containing axons were observed to deeply invaginate into both dendrites and perikarya of magnocellular neurons. These observations provide ultrastructural evidence for the participation of central catecholaminergic neuronal systems in the regulation of the different neuronal and neuroendocrine functions which have been related to hypothalamic paraventricular neurons.

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.

Luteinizing-hormone-releasing hormone modifies retention of passive and active avoidance responses in rats

The influence of posttraining subcutaneous administration of luteinizing-hormone-releasing hormone (LHRH) was tested on the retention of either active or passive avoidance conditioning in male rats. Injection of LHRH (200 micrograms/kg) immediately after the acquisition of an active avoidance response (two-way shuttle behavior) enhanced retention of the response, assessed 7 days later. When the neuropeptide was injected immediately after a passive avoidance conditioning training, the effects varied with the intensity of the footshock applied. LHRH enhanced retention of avoidance training with weak footshock (0.20 and 0.35 mA) but impaired retention of training with strong footshock (0.70 and 1.0 mA). The effects of LHRH seem to be unspecific since they are similar to those observed after treatment with several hormones. The results are discussed based on the interactions between peripherally injected hormones and endogenous substances released following footshock. A modulatory effect on the monoaminergic pathway involved in memory storage processes is postulated.

Tyrosine hydroxylase-immunoreactive neurons of the hypothalamus: a light and electron microscopic study

The localization and morphology of neurons, processes, and neuronal groups in the rat hypothalamus containing tyrosine hydroxylase-like immunoreactivity were studied using an antiserum to bovine tyrosine hydroxylase. This antiserum was thoroughly characterized by precipitation of enzyme activity, immunoblotting, and precipitation of cell-free translation products; a single molecular weight band was recognized by the antiserum. Absorption of the antiserum with purified tyrosine hydroxylase abolished immunocytochemical staining, while addition of bovine dopamine beta-hydroxylase had no effect on immunostaining. Immunoreactive cells were found throughout the hypothalamus. Significant numbers of cells were found in the arcuate, periventricular, dorsomedial hypothalamus/zona incerta, posterior hypothalamic regions (A11-A14), and paraventricular nucleus, as previously described, and in addition, in the preoptic area, adjacent to the anterior commissure, medial and lateral to the suprachiasmatic nucleus, dorsal to and in the supraoptic nucleus, at the lateral borders of the ventromedial nucleus, and in the dorsal and ventral lateral hypothalamus. None of the immunoreactive cell groups are totally separated from adjacent cell groups. Dendritic overlap occurs between any two adjacent groups. From cell counts of 30 micron coronal sections, we estimate the hypothalamus has about 12,000 cells based on raw counts, or 8000 immunoreactive cells after correction for possible split cells. Mean soma size varied considerably from one immunoreactive group to another. Cells in the caudal part of the dorsomedial hypothalamus/zona incerta region were the largest, with a mean diameter of 25 micron, while cells in the anterior commissural and posterior hypothalamic group were among the smallest, with mean diameters of 10 micron. The largest immunoreactive cells in the hypothalamus had volumes in excess of ten times greater than the smallest immunoreactive cells. Tyrosine hydroxylase immunoreactivity was found in dendrites in every region of the hypothalamus, sometimes extending hundreds of micrometers from the perikaryon of origin. Although adjacent cell groups were not distinctly separated, the dendritic arbors of the different cell groups differed greatly. Dendritic and somatic appendages were found on some cells, particularly in the paraventricular nucleus. Immunoreactive dendritic arbors were particularly large in cells seen on horizontal sections through the caudal dorsomedial hypothalamic group and through the anterior hypothalamus. Only slight dendritic trees were observed in the rostral dorsomedial hypothalamus/zona incerta region, and in the pericommissural group.(ABSTRACT TRUNCATED AT 400 WORDS)

Ultrastructural relationships between serotonin and dopamine neurons in the rat arcuate nucleus and medial zona incerta: a combined radioautographic and immunocytochemical study

Combined radioautographic and immunocytochemical detection of [3H]serotonin-labeled axon terminals and tyrosine hydroxylase-immunoreactive processes in the same thin sections allowed for electron microscopic demonstration of direct appositions between serotoninergic axonal varicosities and dopaminergic nerve cell bodies and/or dendrites in the anterior part of the arcuate nucleus and in the medial zona incerta. Although no junctional specializations were apparent at the sites of contacts, it is proposed that the observed appositions may represent a serotonin input onto tubero-infundibular and incerto-hypothalamic dopaminergic neurons. This innervation could account for some of the central neuroendocrine effects of serotonin, particularly its regulatory role on prolactin and gonadotropin secretion.

Distribution of neurotensin-immunoreactivity within baroreceptive portions of the nucleus of the tractus solitarius and the dorsal vagal nucleus of the rat

We have examined the distribution of neurotensin immunoreactivity within subnuclear regions of the nucleus of the tractus solitarius (NTS) and the dorsal motor nucleus of the vagus nerve (DVN) in the rat. In order to determine which regions of the NTS were involved in the regulation of baroreceptor reflexes, we mapped the central distribution of the aortic branch of the vagus nerve using transganglionic transport of horseradish peroxidase. Comparison of the pattern of aortic nerve innervation with that of the distribution of neurotensin-immunoreactive cells and fibers shows the dorsomedial nucleus of the NTS both to be the primary site of aortic baroreceptor termination and to contain the highest concentration of neurotensin-immunoreactive elements within the NTS. Neurotensin-immunoreactive fibers are also present in medial regions of the NTS adjacent to the area postrema where they may be involved in the modulation of vagal gastric afferents. Double-label experiments, in which, on the same tissue sections, neurotensin immunohistochemistry was combined with retrograde horseradish peroxidase labeling of DVN neurons, reveal a topographic innervation of vagal preganglionic motoneurons by neurotensin-immunoreactive fibers. The heaviest innervation is of lateral portions of the DVN and adjacent ventral portions of the NTS at the level of the obex, an area which may contain cardiac motoneurons. In this region neurotensin-immunoreactive fibers can be observed in close proximity to retrogradely labeled cells. The concentration of neurotensin elements in a region of the NTS which is involved in the control of baroreceptor reflexes provides a morphological basis for the cardiovascular effects produced by central administration of the peptide. Additional control may be exerted at the level of the motoneuron, as evidenced by apparent neurotensin fiber innervation of presumptive cardiac preganglionic neurons. Similarly, the distribution of neurotensin fibers suggests that the peptide may be acting in gastric regulatory areas of the NTS or on vagal secretomotor neurons to regulate gastric acid secretion.

Organization and interrelationship of neuropeptides in the central amygdaloid nucleus of the rat

The organization and interactions of neuropeptides in the central nucleus of the amygdala (Ce) were studied using single and double label immunocytochemical techniques. Immunocytochemical localization of substance P (SP), neurotensin (NT), met-enkephalin (m-ENK), somatostatin (SS) and vasoactive intestinal polypeptide (VIP) revealed all of these peptides within discrete regions of the Ce. The regions differed from the classical medial and lateral anatomical divisions reported for the Ce. Instead, three easily recognizable neuropeptidergic subdivisions were evident: a medial zone, a central zone and a lateral capsular zone. Two types of interrelationships between peptides were noted. The first involved a peptidergic fiber in apposition to a peptidergic perikarya. The most prevalent peptidergic interaction of this type occurred between SP and NT. The second interrelationship involved two different peptidergic fibers in apposition to an immunonegative cell. Two interactions of this type were commonly observed. The first involved NT and m-ENK fibers simultaneously apposed to an unstained cell. The second involved SP and m-ENK fibers adjacent to the same immunonegative cell. The interactions between peptidergic systems may suggest a role of these substances in the regulation of autonomic functions in the Ce.