Morphology and distribution of hypothalamic peptidergic systems

Neuropeptides participate in the regulation of numerous hypothalamic functions that are aimed for sustaining the homeostasis of the organism. These neuropeptides can act in two different levels. They can influence the release of hormones from the adenohypophysis via the portal circulation; in addition, they can act as neurotransmitters/neuromodulators modulating the functioning of numerous hypothalamic neurotransmitter systems. Indeed, most of these peptidergic systems form a complex network in the infundibular and periventricular nuclei of the human hypothalamus, communicating with each other by synaptic connections that may control fundamental physiologic functions. In the present chapter, we provide an overview of the distribution of neuropeptides in the human hypothalamus using immunohistochemistry and high-resolution, three-dimensional mapping.

Activin Decoy Receptor ActRIIB:Fc Lowers FSH and Therapeutically Restores Oocyte Yield, Prevents Oocyte Chromosome Misalignments and Spindle Aberrations, and Increases Fertility in Midlife Female SAMP8 Mice

Women of advanced maternal age (AMA) (age ≥ 35) have increased rates of infertility, miscarriages, and trisomic pregnancies. Collectively these conditions are called "egg infertility." A root cause of egg infertility is increased rates of oocyte aneuploidy with age. AMA women often have elevated endogenous FSH. Female senescence-accelerated mouse-prone-8 (SAMP8) has increased rates of oocyte spindle aberrations, diminished fertility, and rising endogenous FSH with age. We hypothesize that elevated FSH during the oocyte's FSH-responsive growth period is a cause of abnormalities in the meiotic spindle. We report that eggs from SAMP8 mice treated with equine chorionic gonadotropin (eCG) for the period of oocyte growth have increased chromosome and spindle misalignments. Activin is a molecule that raises FSH, and ActRIIB:Fc is an activin decoy receptor that binds and sequesters activin. We report that ActRIIB:Fc treatment of midlife SAMP8 mice for the duration of oocyte growth lowers FSH, prevents egg chromosome and spindle misalignments, and increases litter sizes. AMA patients can also have poor responsiveness to FSH stimulation. We report that although eCG lowers yields of viable oocytes, ActRIIB:Fc increases yields of viable oocytes. ActRIIB:Fc and eCG cotreatment markedly reduces yields of viable oocytes. These data are consistent with the hypothesis that elevated FSH contributes to egg aneuploidy, declining fertility, and poor ovarian response and that ActRIIB:Fc can prevent egg aneuploidy, increase fertility, and improve ovarian response. Future studies will continue to examine whether ActRIIB:Fc works via FSH and/or other pathways and whether ActRIIB:Fc can prevent aneuploidy, increase fertility, and improve stimulation responsiveness in AMA women.

Shortened estrous cycle length, increased FSH levels, FSH variance, oocyte spindle aberrations, and early declining fertility in aging senescence-accelerated mouse prone-8 (SAMP8) mice: concomitant characteristics of human midlife female reproductive aging

Women experience a series of specific transitions in their reproductive function with age. Shortening of the menstrual cycle begins in the mid to late 30s and is regarded as the first sign of reproductive aging. Other early changes include elevation and increased variance of serum FSH levels, increased incidences of oocyte spindle aberrations and aneuploidy, and declining fertility. The goal of this study was to investigate whether the mouse strain senescence-accelerated mouse-prone-8 (SAMP8) is a suitable model for the study of these midlife reproductive aging characteristics. Midlife SAMP8 mice aged 6.5-7.85 months (midlife SAMP8) exhibited shortened estrous cycles compared with SAMP8 mice aged 2-3 months (young SAMP8, P = .0040). Midlife SAMP8 mice had high FSH levels compared with young SAMP8 mice, and mice with a single day of high FSH exhibited statistically elevated FSH throughout the cycle, ranging from 1.8- to 3.6-fold elevation on the days of proestrus, estrus, metestrus, and diestrus (P < .05). Midlife SAMP8 mice displayed more variance in FSH than young SAMP8 mice (P = .01). Midlife SAMP8 ovulated fewer oocytes (P = .0155). SAMP8 oocytes stained with fluorescently labeled antitubulin antibodies and scored in fluorescence microscopy exhibited increased incidence of meiotic spindle aberrations with age, from 2/126 (1.59%) in young SAMP8 to 38/139 (27.3%) in midlife SAMP8 (17.2-fold increase, P < .0001). Finally, SAMP8 exhibited declining fertility from 8.9 pups/litter in young SAMP8 to 3.5 pups/litter in midlife SAMP8 mice (P < .0001). The age at which these changes occur is younger than for most mouse strains, and their simultaneous occurrence within a single strain has not been described previously. We propose that SAMP8 mice are a model of midlife human female reproductive aging.

Intimate associations between the endogenous opiate systems and the growth hormone-releasing hormone system in the human hypothalamus

Although it is a general consensus that opioids modulate growth, the mechanism of this phenomenon is largely unknown. Since endogenous opiates use the same receptor family as morphine, these peptides may be one of the key regulators of growth in humans by impacting growth hormone (GH) secretion, either directly, or indirectly, via growth hormone-releasing hormone (GHRH) release. However, the exact mechanism of this regulation has not been elucidated yet. In the present study we identified close juxtapositions between the enkephalinergic/endorphinergic/dynorphinergic axonal varicosities and GHRH-immunoreactive (IR) perikarya in the human hypothalamus. Due to the long post mortem period electron microscopy could not be utilized to detect the presence of synapses between the enkephalinergic/endorphinergic/dynorphinergic and GHRH neurons. Therefore, we used light microscopic double-label immunocytochemistry to identify putative juxtapositions between these systems. Our findings revealed that the majority of the GHRH-IR perikarya formed intimate associations with enkephalinergic axonal varicosities in the infundibular nucleus/median eminence, while endorphinergic-GHRH juxtapositions were much less frequent. In contrast, no significant dynorphinergic-GHRH associations were detected. The density of the abutting enkephalinergic fibers on the surface of the GHRH perikarya suggests that these juxtapositions may be functional synapses and may represent the morphological substrate of the impact of enkephalin on growth. The small number of GHRH neurons innervated by the endorphin and dynorphin systems indicates significant differences between the regulatory roles of endogenous opiates on growth in humans.

Carboxypeptidase E protects hippocampal neurons during stress in male mice by up-regulating prosurvival BCL2 protein expression

Prolonged chronic stress causing elevated plasma glucocorticoids leads to neurodegeneration. Adaptation to stress (allostasis) through neuroprotective mechanisms can delay this process. Studies on hippocampal neurons have identified carboxypeptidase E (CPE) as a novel neuroprotective protein that acts extracellularly, independent of its enzymatic activity, although the mechanism of action is unclear. Here, we aim to determine if CPE plays a neuroprotective role in allostasis in mouse hippocampus during chronic restraint stress (CRS), and the molecular mechanisms involved. Quantitative RT-PCR/in situ hybridization and Western blots were used to assay for mRNA and protein. After mild CRS (1 h/d for 7 d), CPE protein and mRNA were significantly elevated in the hippocampal CA3 region, compared to naïve littermates. In addition, luciferase reporter assays identified a functional glucocorticoid regulatory element within the cpe promoter that mediated the up-regulation of CPE expression in primary hippocampal neurons following dexamethasone treatment, suggesting that circulating plasma glucocorticoids could evoke a similar effect on CPE in the hippocampus in vivo. Overexpression of CPE in hippocampal neurons, or CRS in mice, resulted in elevated prosurvival BCL2 protein/mRNA and p-AKT levels in the hippocampus; however, CPE(-/-) mice showed a decrease. Thus, during mild CRS, CPE expression is up-regulated, possibly contributed by glucocorticoids, to mediate neuroprotection of the hippocampus by enhancing BCL2 expression through AKT signaling, and thereby maintaining allostasis.

Distribution and morphology of the catecholaminergic neural elements in the human hypothalamus

Previous studies have demonstrated that catecholaminergic, tyrosine hydroxylase (TH)-immunoreactive (IR) perikarya and fibers are widely distributed in the human hypothalamus. Since TH is the key and rate-limiting enzyme for catecholaminergic synthesis, these IR neurons may represent dopaminergic, noradrenergic or adrenergic neural elements. However, the distribution and morphology of these neurotransmitter systems in the human hypothalamus is not entirely known. Since the different catecholaminergic systems can be detected by identifying the neurons containing the specific key enzymes of catecholaminergic synthesis, in the present study we mapped the catecholaminergic elements in the human hypothalamus using immunohistochemistry against the catecholaminergic enzymes, TH, dopamine beta-hydroxylase (DBH) and phenylethanolamine-N-methyltransferase (PNMT). Only a few, PNMT-IR, adrenergic neuronal elements were found mainly in the infundibulum and the periventricular zone. DBH-IR structures were more widely distributed in the human hypothalamus occupying chiefly the infundibulum/infundibular nucleus, periventricular area, supraoptic and paraventricular nuclei. Dopaminergic elements were detected by utilizing double label immunohistochemistry. First, the DBH-IR elements were visualized; then the TH-IR structures, that lack DBH, were detected with a different chromogen. In our study, we conclude that all of the catecholaminergic perikarya and the majority of the catecholaminergic fibers represent dopaminergic neurons in the human hypothalamus. Due to the extremely small number of PNMT-IR, adrenergic structures in the human hypothalamus, the DBH-IR fibers represent almost exclusively noradrenergic neuronal processes. These findings suggest that the juxtapositions between the TH-IR and numerous peptidergic systems revealed by previous reports indicate mostly dopaminergic synapses.

Gonadotropin-releasing hormone neurons express estrogen receptor-beta

CONTEXT

Recent identification of the second estrogen receptor (ER) isoform (ER-beta) within GnRH neurons of the rodent brain has generated much enthusiasm in the field of neuroendocrine research by questioning the dogma that GnRH cells do not directly sense changes in circulating estrogens.

OBJECTIVE

To address the issue of whether GnRH neurons of the human hypothalamus also contain ER-beta, we have performed dual-label immunocytochemical studies.

DESIGN

Tissue sections were prepared from autopsy samples of male human individuals (n = 8; age < 50 yr), with sudden causes of death. Technical efforts were made to minimize postmortem interval (<24 h), optimize tissue fixation (use of a mixture of 2% paraformaldehyde and 4% acrolein for four tissue samples), and sensitize the immunocytochemical detection of ER-beta (application of silver-intensified nickel-diaminobenzidine chromogen).

MAIN OUTCOME MEASURE

Distribution and percent ratio of GnRH neurons that also contained ER-beta immunoreactivity were analyzed under the light microscope.

RESULTS

With acrolein in tissue fixative, nuclear ER-beta immunoreactivity was observed in 10.8-28.0% of GnRH neurons of the four different individuals. ER-beta-containing GnRH neurons were widely distributed in the hypothalamus, without showing a noticeable preference in regional location.

CONCLUSIONS

The demonstration of ER-beta and the previous lack of detection of ER-alpha in human GnRH cells indicate that estrogens may exert direct actions upon GnRH neurons exclusively through ER-beta. In the light of differing ligand-binding characteristics of ER-beta from those of ER-alpha, this discovery offers a potential new approach to influence estrogen feedback to GnRH neurons through ER-beta-selective receptor ligands.

Morphological substrate of the catecholaminergic input of the vasopressin neuronal system in humans

It has been postulated that the stress response is associated with water balance via regulating vasopressin release. Nausea, surgical stress and insulin-induced hypoglycaemia were shown to stimulate vasopressin secretion in humans. Increased vasopressin release in turn induces water resorption through the kidneys. Although the mechanism of the stress-mediated vasopressin release is not entirely understood, it is generally accepted that catecholamines play a crucial role in influencing water balance by modulating the secretion of vasopressin. However, the morphological substrate of this modulation has not yet been established. The present study utilised double-label immunohistochemistry to reveal putative juxtapositions between tyrosine hydroxylase (TH)-immunoreactive (IR) catecholaminergic system and the vasopressin systems in the human hypothalamus. In the paraventricular and supraoptic nuclei, numerous vasopressin-IR neurones received TH-IR axon varicosities. Analysis of these juxtapositions with high magnification combined with oil immersion did not reveal any gaps between the contacted elements. In conclusion, the intimate associations between the TH-IR and vasopressin-IR elements may be functional synapses and may represent the morphological basis of vasopressin release modulated by stressors. Because certain vasopressin-IR perikarya receive no detectable TH innervations, it is possible that additional mechanisms may participate in the stress-influenced vasopressin release.

Three-dimensional representation of the neurotransmitter systems of the human hypothalamus: inputs of the gonadotrophin hormone-releasing hormone neuronal system

The gonadotrophin-releasing hormone (GnRH) represents the final common pathway of a neuronal network that integrates multiple external and internal factors to control fertility. Among the many inputs GnRH neurones receive, oestrogens play the most important role. In females, oestrogen, in addition to the negative feedback, also exhibits a positive feedback influence upon the activity and output of GnRH neurones to generate the preovulatory luteinising hormone surge and ovulation. Until recently, the belief has been that the GnRH neurones do not contain oestrogen receptors and that the action of oestrogen upon GnRH neurones is indirect, involving several, oestrogen-sensitive neurotransmitter and neuromodulator systems that trans-synaptically regulate the activity of the GnRH neurones. Although this concept still holds for humans, recent studies indicate that oestrogen receptor-beta is expressed in GnRH neurones of the rat. This review provides three dimensional stereoscopic images of GnRH-immunoreactive (IR) and some peptidergic (neuropeptide Y-, substance P-, beta-endorphin-, leu-enkaphalin-, corticotrophin hormone-releasing- and galanin-IR) and catecholaminergic neurones and the communication of these potential oestrogen-sensitive neuronal systems with GnRH neurones in the human hypothalamus. Because the post-mortem human tissue does not allow the electron microscopic identification of synapses on GnRH neurones, the data presented here are based on light microscopic immunocytochemical experiments using high magnification with oil immersion, semithin sections or confocal microscopy.

Estrogen stimulates galanin expression within luteinizing hormone-releasing hormone-immunoreactive (LHRH-i) neurons via estrogen receptor-beta (ERbeta) in the female rat brain

Among the many factors that integrate the activity of the luteinizing hormone-releasing hormone (LHRH) neuronal system, estrogens play the most important role. Until recently, the belief has been that the LHRH neurons do not contain estrogen receptors and that the action of estrogen upon LHRH neurons is indirect involving several, estrogen-sensitive neurotransmitter and neuromodulator systems that regulate the activity of the LHRH neurons. Based on our recent findings that LHRH neurons of the female rat co-express galanin, that galanin is a potent LHRH releasing peptide, and that estrogen receptor-beta (ERbeta) is present in LHRH neurons, we have evaluated the effect of 17beta-estradiol on the expression of galanin within LHRH neurons. By combining immunocytochemistry for LHRH and in situ hybridization histochemistry for galanin, we demonstrate that 17beta-estradiol stimulates galanin expression within 2h following their administration to ovariectomized rats. Maximal expression, however, required a longer treatment regimen (3 days). These observations strongly suggest that estrogens stimulate galanin expression within LHRH neurons directly, via ERbeta. Moreover, ERbeta may mediate, at least in part, the positive feedback effect of estrogens during the preovulatory LHRH and subsequent LH surges.

Estrogen receptor-β in oxytocin and vasopressin neurons of the rat and human hypothalamus: Immunocytochemical and in situ hybridization studies

Topographical distribution of estrogen receptor-beta (ER-beta)-synthesizing oxytocin (OT) and vasopressin (VP) neurons was studied in the hypothalamic paraventricular and supraoptic nuclei (PVH; SO) of ovariectomized rats. In distinct subregions, 45-98% of OT neurons and 88-99% of VP neurons exhibited ER-beta immunoreactivity that was confined to cell nuclei. Neuronal populations differed markedly with respect to the intensity of the ER-beta signal. Magnocellular OT neurons in the PVH, SO, and accessory cell groups typically contained low levels of the ER-beta signal; in contrast, robust receptor labeling was displayed by OT cells in the ventral subdivision of medial parvicellular subnucleus and in the caudal PVH (dorsal subdivision of medial parvicellular subnucleus and lateral parvicellular subnucleus). Estrogen receptor-beta signal was generally more intense and present in higher proportions of magnocellular and parvicellular VP vs. OT neurons of similar topography. Immunocytochemical observations were confirmed via triple-label in situ hybridization, an approach combining use of digoxigenin-, fluorescein-, and 35S-labeled cRNA hybridization probes. Further, ER-beta mRNA was also detectable in corticotropin-releasing hormone neurons in the parvicellular PVH. Finally, double-label immunocytochemical analysis of human autopsy samples showed that subsets of OT and VP neurons also express ER-beta in the human. These neuroanatomical studies provide detailed information about the topographical distribution and cellular abundance of ER-beta within subsets of hypothalamic OT and VP neurons in the rat. The variable receptor content may indicate the differential responsiveness to estrogen in distinct OT and VP neuronal populations. In addition, a relevance of these findings to the human hypothalamus is suggested.

Close anatomical associations between β-endorphin and luteinizing hormone-releasing hormone neuronal systems in the human diencephalon

Endogenous opiates, such as beta-endorphin, inhibit the release of luteinizing hormone (LH) release in the pituitary gland of several species including rat, pig, sheep, and human. Although it is generally believed that beta-endorphin influences gonadal functions via the regulation of hypothalamic LH-releasing hormone (LHRH) release, the morphological substrate underlying this regulation in humans remains elusive. In the present series of experiments the beta-endorphin-immunoreactive (IR) and LHRH-IR neural elements, utilizing single label immunohistochemistry, were mapped. Following the superimposition of the maps of these systems, the overlapping sites were identified and examined in order to verify the putative juxtapositions between the beta-endorphin-IR and LHRH-IR structures. LHRH-IR elements were detected mainly in the medial basal hypothalamus, in the medial preoptic area and along the diagonal band of Broca. Beta-endorphin-IR perikarya were observed in the infundibular region/median eminence, whereas beta-endorphin-IR axon varicosities were detected periventricularly in the preoptic and tuberal regions, in the medial basal hypothalamus and around the mamillary bodies. Careful examination of the immunoreactive elements in the overlapping areas revealed close contacts between beta-endorphin-IR and LHRH-IR structures, which have been verified in semithin plastic sections. These putative beta-endorphin-LHRH juxtapositions were most numerous in the medial preoptic area and in the infundibulum/median eminence of the human diencephalon. In conclusion, the present paper is the first study that revealed close juxtapositions between the beta-endorphin-IR and LHRH-IR neural elements in the human diencephalon. These beta-endorphin-LHRH contacts may be functional synapses, and they may be the morphological substrate of the beta-endorphin control on gonadal functions in man.

Bi-directional associations between galanin and luteinizing hormone-releasing hormone neuronal systems in the human diencephalon

Evidence suggests that galanin plays an important role in the regulation of reproduction in the rat. Galanin is colocalized with luteinizing hormone (LH)-releasing hormone (LHRH) in a subset of LHRH neurons in female rats and galanin-immunoreactive (galanin-IR) nerve terminals innervate LHRH neurons. Recent studies indicate that galanin may control gonadal functions in rats at two different levels: (i) via direct modulation of pituitary LH secretion and/or (ii) indirectly via the regulation of the hypothalamic LHRH release. However, the morphological substrate of any similar modulation is not known in human. In the present series of experiments we first mapped the galanin-IR and LHRH-IR neural elements in human brain, utilizing single label immunohistochemistry. Then, following the superimposition of the maps of these systems, the overlapping sites were identified with double labeling immunocytochemistry and examined in order to verify the putative juxtapositions between galanin-IR and LHRH-IR structures. LHRH and galanin immunoreactivity were detected mainly in the medial basal hypothalamus, in the medial preoptic area and along the diagonal band of Broca. Careful examination of the IR elements in the overlapping areas revealed close, bi-directional contacts between galanin-IR and LHRH-IR structures, which have been verified in semithin plastic sections. These galanin-LHRH and LHRH-galanin juxtapositions were most numerous in the medial preoptic area and in the infundibulum/median eminence of the human diencephalon. In conclusion, the present study is the first to reveal bi-directional juxtapositions between galanin- and LHRH-IR neural elements in the human diencephalon. These galanin-LHRH and LHRH-galanin contacts may be functional synapses, and they may be the morphological substrate of the galanin-controlled gonadal functions in humans.

Estrogen prevents the loss of CA1 hippocampal neurons in gerbils after ischemic injury

Estrogen replacement therapy is thought to attenuate the incidence of Alzheimer's disease in women and enhance cognitive functions. In rodents, estrogen protects cerebral cortical neurons from ischemic injury and cultured neurons from a variety of perturbations. Because few nuclear estrogen receptors have been detected in the dorsal hippocampus, the present studies used a global ischemia model to evaluate the neuroprotective actions of estrogen in this region. Ovariectomized gerbils were treated with placebo, 0.5 mg or 1 mg pellets of estradiol for 13 days. On day 7, the common carotid arteries were occluded for 5 min and on day 13 the animals were killed. Analysis of neurogranin mRNA, a marker of hippocampal neurons, with in situ hybridization revealed a dramatic and selective loss of CA1 neurons in the placebo-treated ovariectomized gerbils, whereas both 0.5 mg and 1 mg pellets of 17beta-estradiol prevented cell loss. Subsequent studies showed that a variety of estrogens, including diethylstilbestrol, estrone and 17alpha-estradiol as well as vitamin E, also protected CA1 neurons from ischemic injury in ovariectomized gerbils, whereas treatment with the estrogen antagonist tamoxifen was ineffective. The results of in vivo binding studies with 17alpha-iodovinyl-11beta-methoxyestradiol revealed a concentration of nuclear estrogen binding sites in the CA1 region of the ovariectomized gerbil brain, whereas binding in other hippocampal regions was limited. Moreover, the binding studies revealed that the regional pattern of binding was not altered after ischemic injury, with the exception of the hippocampus, where the binding sites were attenuated in ovariectomized animals with time after ischemic injury. Together, these data demonstrate that a variety of steroidal and non-steroidal estrogens are potent neuroprotective agents in an animal model of global ischemia, agents that protect neurons critical for learning and memory and susceptible to neurodegenerative diseases.

Topography and associations of leu-enkephalin and luteinizing hormone-releasing hormone neuronal systems in the human diencephalon

Although several studies indicated that leu-enkephalin controls gonadal function, the morphological substrate of this modulation is unknown. To reveal potential interaction sites between leu-enkephalin and LH-releasing hormone (LHRH) in the hypothalamus, the distribution and connections of leu-enkephalin-immunoreactive (IR) and LHRH-IR systems were examined in the human diencephalon using double-label immunohistochemistry. First the leu-enkephalin-IR and LHRH-IR neural elements were mapped, then the maps of the two different neurotransmitter systems were superimposed unveiling the overlapping areas. The putative juxtapositions between leu-enkephalin-IR and LHRH-IR structures were revealed with double label immunocytochemistry. Close contacts were detected in the medial preoptic area and in the infundibulum/median eminence. In these areas, diaminobenzidine-silver-intensified, black leu-enkephalin-IR fibers abutted fusiform, brown, diaminobenzidine-labeled LHRH neurons often forming multiple contacts. Examination of semithin sections of these close associations with the aid of oil immersion revealed no cleft between the contacting LHRH-IR and leu-enkephalin-IR elements. Our findings indicate that the juxtapositions between LHRH-IR and leu enkephalin-IR neurons may be functional synapses forming the morphological substrate of the leu-enkephalin-modulated LHRH secretion in the human diencephalon. Moreover, the wide distribution of leu-enkephalin-IR elements suggests leu-enkephalin control of other diencephalic functions as well.

Estrogen modulates oxytocin gene expression in regions of the rat supraoptic and paraventricular nuclei that contain estrogen receptor-beta

Oxytocin is an important modulator of female reproductive functions including parturition, lactation and maternal behavior, while vasopressin regulates water balance and acts as a neurotransmitter. For decades, it has been suggested that estrogen regulates the production and/or release of oxytocin and vasopressin in the rodent brain. Although several studies demonstrated that estrogen can modulate vasopressin mRNA levels in regions known to contain estrogen receptor (ER), such as the bed nucleus of the stria terminalis and medial amygdala, data from the paraventricular and supraoptic nuclei were inconclusive. Since early immunohistochemical and in situ hybridization studies revealed few, if any, ER containing cells in these hypothalamic nuclei, it was thought that oxytocin and vasopressin were not directly regulated by estrogen. The discovery of a second ER (ER-beta) in the late 1990s suggested that estrogen could act in many brain regions heretofore not considered targets for estrogen action. Initial in situ hybridization studies revealed a wide distribution of ER-beta mRNA in the rat brain including neurons of the supraoptic nucleus and the parvocellular and magnocellular divisions of the paraventricular nucleus. Subsequent double-label in situ hybridization/immunocytochemistry studies showed that ER-beta mRNA was present in oxytocin and vasopressin neurons, with the degree of colocalization being both neuropeptide and region specific. In an attempt to demonstrate that ER-beta mRNA was translated into a biologically active protein, a series of in vivo binding studies were conducted in rats with 125I-estrogen. These data revealed the presence of nuclear estrogen binding sites in neurons of the magnocellular system indicating that ER-beta mRNA was translated into protein. Concurrent studies in mice found that the distribution of ER-beta mRNA and 125I-estrogen binding was similar to rats, although there were some notable differences. For example, ER-beta mRNA and binding were not detected in the mouse supraoptic nucleus and although ER-beta was the principle ER in the paraventricular nucleus, ER-alpha was also present. The prevalence of ERs in the mouse paraventricular nucleus was further investigated using ER-alpha and ER-beta knockout mice for in vivo binding studies with 125I-estrogen. The results of these studies showed that ER-beta was the predominant ER in the paraventricular nucleus and confirmed the presence of ER-beta in other brain regions. Moreover, our group recently generated and characterized several polyclonal antisera raised against the C-terminus of ER-beta. Through the use of these antisera, we have confirmed the presence of ER-beta in the rat paraventricular and supraoptic nuclei and shown that ER-beta is colocalized, in part, with oxytocin and vasopressin. To assess the ability of estrogen to modulate the expression of oxytocin mRNA, ovariectomized rats were treated with vehicle or estradiol and the brains processed for in situ hybridization. The results of these studies revealed that estradiol down-regulated oxytocin mRNA in the rat paraventricular nucleus within 6 h of treatment. Together these data and the observation that some of the oxytocin and vasopressin neurons contain ER-beta suggest that estrogen, acting through ER-beta, may directly regulate oxytocin gene expression. However, since the paraventricular nucleus has many subdivisions with different projections and the degree of colocalization of ER-beta with oxytocin/vasopressin varies among subdivisions, the effects of estrogen treatment on gene expression requires further study to ascertain the role of estrogen action in this neuronal systems.

Close juxtapositions between luteinizing hormone-releasing hormone-immunoreactive neurons and corticotropin-releasing factor-immunoreactive axons in the human diencephalon

Gonadal functions are modulated by corticotropin-releasing factor (CRF) in the rat via direct suppression of LH-releasing hormone (LHRH) release. Although there is evidence of direct morphological contacts between the LHRH and CRF-immunoreactive (-IR) structures in the rat hypothalamus, little is known about the morphological base of CRF-influenced LHRH release in man. Thus, we studied the distribution of the CRF-IR and LHRH-IR systems in the human diencephalon and revealed putative CRF-LHRH juxtapositions using double label immunohistochemistry. LHRH-IR cells were present mainly in the infundibular region and the medial preoptic area. CRF-IR neuronal structures were observed in the periventricular area, paraventricular nucleus, infundibular region, and median eminence. CRF-LHRH juxtapositions were found mainly in the infundibulum and median eminence. Few juxtapositions were detected in the medial preoptic area. In these regions, black diaminobenzidine/silver-labeled CRF-IR fibers abutted fusiform brown diaminobenzidine-labeled LHRH neurons, usually forming multiple contacts. Examination of semithin sections of these close associations with the aid of oil immersion revealed no cleft between CRF-IR nerve terminals contacting LHRH-IR structures. These findings suggest that the juxtapositions between the LHRH-IR and CRF-IR neurons may be functional synapses forming the morphological substrate of the CRF-controlled LHRH secretion. Moreover, the wide distribution of CRF-IR elements suggests that CRF controls other diencephalic functions as well.

Close juxtapositions between LHRH immunoreactive neurons and substance P immunoreactive axons in the human diencephalon

LHRH release is induced by substance P (SP) in the rat hypothalamus. Recent immunocytochemical studies indicate that SP-immunoreactive axons synapse on LHRH neurons in the diencephalon of the rat, but this phenomenon has not yet been demonstrated in human. Therefore, in the present study we visualized the SP- and LHRH-immunoreactive (IR) elements in the human diencephalon and evaluated the close juxtapositions between them. The distribution of LHRH- and SP-IR sites were investigated in diencephalic sections of six, postmortem human brains by means of double-labeling immunocytochemistry. The LHRH-containing perikarya were located in the diagonal band of Broca, lamina terminalis cinerea, preopticoseptal, medial preoptic, and infundibular areas of the brain. The SP-IR fibers formed a network in the periventricular zone in the infundibular region, median eminence, and corpus striatum. The SP-IR cell bodies were located mainly in the infundibular region, median eminence, basal part of the periventricular area, dorsomedial subdivision of the ventromedial nucleus, and basal perifornical area of the tuberal region. The juxtapositions between LHRH-IR cell bodies and SP-IR varicosities were detected in the infundibular and periventricular regions. In these sites black, silver-intensified, SP-IR fiber varicosities abutted on brown, DAB-labeled, LHRH-IR cell bodies. Similar structures were detected between the SP-IR fibers and SP-IR perikarya. These findings suggest that the juxtapositions between the SP and LHRH systems may be the morphological basis of SP-controlled LHRH release in the human diencephalon. Moreover, the intimate contacts between SP-IR fiber varicosities and SP-IR cell bodies or axons indicate direct control of SP on the diencephalic SP release.

Catecholaminergic axons innervate LH-releasing hormone immunoreactive neurons of the human diencephalon

Catecholamines have been shown to modulate gonadal functions via interactions with hypothalamic LH-releasing hormone (LHRH)-synthesizing neurons. To reveal the morphological background of this phenomenon, the distribution of LHRH neurons and tyrosine hydroxylase (TH)-immunoreactive (IR), catecholaminergic structures were mapped in the human diencephalon. First, the location of LHRH and TH-IR neuronal elements was analyzed, and then the relationship between the two different systems was examined. The LHRH-IR cell bodies were mainly present in the medial preoptic and infundibular areas. The TH-IR perikarya were located in the periventricular, paraventricular, and supraoptic hypothalamic nuclei and also in the median eminence. The TH-IR fibers were numerous in septal, infundibular, periventricular, and lateral hypothalamic regions. The brown, diaminobenzidine-labeled LHRH-containing perikarya were found to receive black, silver-intensified, TH-positive axon terminals in the infundibular and medial preoptic areas. However, in the preoptic and caudal parts of the diencephalon, only a few juxtapositions were noted. The present results indicate that hormone released from diencephalic LHRH-IR neurons in humans may be influenced by the central catecholaminergic system via direct synaptic mechanisms.

Distribution of estrogen receptor beta immunoreactivity in the rat central nervous system

The discovery of estrogen receptor beta (ER beta) and subsequent localization of its mRNA in the rat central nervous system (CNS) has provided new insights about estrogen action in brain. A critical step in understanding the role of ER beta is demonstrating that the mRNA is translated into functional protein. The present study used a new ER beta-specific polyclonal antiserum (Z8P) and immunocytochemistry (ICC) to investigate the distribution of ER beta in the rat CNS. Ovariectomized female rats were perfusion fixed, and free-floating sections were incubated with Z8P. After visualization with a standard ABC method, nuclear immunoreactivity was seen in neurons throughout the brain, including the olfactory nuclei, laminae IV-VI of the cerebral cortex, medial septum, preoptic area, bed nucleus of the stria terminalis, supraoptic nucleus, paraventricular nucleus, zona incerta, medial and cortical amygdaloid nuclei, cerebellum, nucleus of the solitary tract, ventral tegmental area, and spinal trigeminal nucleus. Moreover, the results of a double-label ICC/ in situ hybridization study revealed that ER beta mRNA and immunoreactivity were colocalized in neurons of the brain, thus confirming the specificity of the antiserum. Through the use of Western blot analysis, Z8P was shown to recognize in vitro translated ER beta, but not ER alpha, as well as a 60-kDa protein from rat granulosa cells and ovary extracts. The results of these studies have demonstrated that (1) ER beta mRNA is translated into immunoreactive protein throughout the rat brain, and (2) ER beta resides in the cell nucleus. Together, these data provide an anatomic foundation for future studies and advance our understanding of estrogen action in hypothalamic and extrahypothalamic brain regions.

Estrogen receptor-beta immunoreactivity in luteinizing hormone-releasing hormone neurons of the rat brain

Feedback regulation of luteinizing hormone-releasing hormone (LHRH) neurons by estradiol plays important roles in the neuroendocrine control of reproduction. Recently, we found that the majority of LHRH neurons in the rat contain estrogen receptor-beta (ER-beta) mRNA, whereas, they seemed to lack ER-alpha mRNA expression. In addition, we observed nuclear uptake of (125)I-estrogen by a subset of these cells. These data suggest that ER-beta is the chief receptor isoform mediating direct estrogen effects upon LHRH neurons. To verify the translation of ER-beta protein within LHRH cells, the present studies applied dual-label immunocytochemistry (ICC) to free-floating sections obtained from the preoptic area of rats. The improved ICC method using the silver-gold intensification of nickel-diaminobenzidine chromogen, enabled the observation of nuclear ER-beta-immunoreactivity in the majority of LHRH cells. The incidence of ER-beta expression was similarly high in LHRH neurons of ovariectomized female (87.8 +/- 2.3%, mean +/- SEM), estradiol-primed female (74.9 +/- 3.2%) and intact male (85.0 +/- 4.7%) rats. The presence of ER-beta mRNA, ER-beta immunoreactivity and (125)I-estrogen binding sites in LHRH neurons of the rat provide strong support for the notion that these cells are directly regulated by estradiol, through ER-beta. The gene targets and molecular mechanisms of this regulation remain unknown.

Estrogen receptor-alpha and beta- immunoreactivity and mRNA in neurons of sensory and autonomic ganglia and spinal cord

Estrogen receptor-alpha immunoreactivity and mRNAs are present in neurons in locales that innervate genital organs, e.g., parasympathetic pelvic autonomic ganglia, sensory dorsal root and nodose ganglia, and autonomic areas of the lumbosacral spinal cord. With the availability of probes for the beta-isoform of the estrogen receptor, we studied this receptor in autonomic, sensory, and spinal cord neurons and compared it with the distribution of the alpha-receptor. Estrogen receptor-alpha and -beta immunoreactivity were located in the nuclei of neurons, were in subpopulations of parasympathetic neurons in pelvic ganglia, and sensory neurons of dorsal root and nodose ganglia. Both receptor subtypes were present in the lumbosacral spinal cord: in neurons of the outer laminae of the dorsal horn, lateral collateral and medial collateral pathways, sacral parasympathetic nucleus, dorsal intermediate gray, and lamina X. Similar numbers of spinal cord neurons were immunoreactive for estrogen receptor-beta and estrogen receptor-alpha. However, estrogen receptor-beta-immunoreactive neurons appeared less numerous in the outer dorsal horn, but more numerous in the deeper layers of the spinal cord than estrogen receptor-alpha neurons. Retrograde tracing from the uterus revealed "uterine-related" neurons in dorsal root and pelvic ganglia that contained estrogen receptor-alpha and -beta. In situ hybridization revealed both estrogen receptor-alpha and -beta mRNA transcripts in sensory neurons of the dorsal root and nodose ganglia, parasympathetic neurons of pelvic ganglia, and spinal cord neurons in the dorsal horn, sacral parasympathetic nucleus, and dorsal intermediate gray of L6-S1 segments. These studies show that both estrogen receptor-alpha and -beta are synthesized by autonomic and sensory neurons in parts of the nervous system that have connections with the female reproductive system. Such neurons contain neurotransmitters that have important functions in the female reproductive organs; thus, it is likely that estrogen can influence the activity of such neurons and consequently, through them, the activities of the reproductive organs.

Evidence for novel estrogen binding sites in the rat hippocampus

Estrogen modulates the morphology and physiology of the rat hippocampus and enhances cognitive function. While estrogen receptor (alpha and beta) messenger RNAs have been detected in the hippocampus, the presence of functional protein remains uncertain. The present study used a new radiolabeled estrogen, [125I]estrogen, and in vivo autoradiography to address this question. Nuclear uptake and retention of [125I]estrogen was detected in the pyramidal cells of CA1-CA3, with the majority of cells in the ventral horn of CA2 and CA3 being labeled. Additional labeled cells were scattered throughout the strata oriens and radiatum and the hilus of the dentate gyrus. Since the number and distribution of labeled cells in the hippocampus was more than expected, in situ hybridization was used to assess the localization of estrogen receptor (alpha and beta) messenger RNAs in this brain region. The results revealed that both estrogen receptors are expressed in regions where [125I]estrogen binding was seen, although the intensity of estrogen receptor-alpha hybridization signal appears to be stronger when compared with estrogen receptor-beta.The results of these studies have demonstrated the presence of estrogen receptors in rat hippocampus and shown that the distribution of binding sites was much greater than expected, particularly in the pyramidal cells of the ventral hippocampus. These observations challenge our current thinking about steroid hormones and their mechanism(s) of action in a region associated with learning and memory and affected by the neurodegenerative conditions of aging.

Estrogen receptor , not , is a critical link in estradiol-mediated protection against brain injury

Estradiol protects against brain injury, neurodegeneration, and cognitive decline. Our previous work demonstrates that physiological levels of estradiol protect against stroke injury and that this protection may be mediated through receptor-dependent alterations of gene expression. In this report, we tested the hypothesis that estrogen receptors play a pivotal role in mediating neuroprotective actions of estradiol and dissected the potential biological roles of each estrogen receptor (ER) subtype, ER alpha and ER beta, in the injured brain. To investigate and delineate these mechanisms, we used ER alpha-knockout (ER alpha KO) and ER beta-knockout (ER beta KO) mice in an animal model of stroke. We performed our studies by using a controlled endocrine paradigm, because endogenous levels of estradiol differ dramatically among ER alpha KO, ER beta KO, and wild-type mice. We ovariectomized ER alpha KO, ER beta KO, and the respective wild-type mice and implanted them with capsules filled with oil (vehicle) or a dose of 17 beta-estradiol that produces physiological hormone levels in serum. One week later, mice underwent ischemia. Our results demonstrate that deletion of ER alpha completely abolishes the protective actions of estradiol in all regions of the brain; whereas the ability of estradiol to protect against brain injury is totally preserved in the absence of ER beta. Thus, our results clearly establish that the ER alpha subtype is a critical mechanistic link in mediating the protective effects of physiological levels of estradiol in brain injury. Our discovery that ER alpha mediates protection of the brain carries far-reaching implications for the selective targeting of ERs in the treatment and prevention of neural dysfunction associated with normal aging or brain injury.

Topography and associations of luteinizing hormone-releasing hormone and neuropeptide Y-immunoreactive neuronal systems in the human diencephalon

Neuropeptide Y (NPY) potentiates the effect of luteinizing hormone-releasing hormone (LHRH) on luteinizing hormone secretion in several species, including human. In addition to the pituitary sites, the interactions of the NPY and LHRH systems may involve diencephalic loci. However, the morphologic basis of this putative communication has not yet been elucidated in the human brain. To discover interaction sites, the distribution and connections of LHRH and NPY-immunoreactive (IR) neuronal elements in the human hypothalamus were investigated by means of light microscopic single- and double-label immunocytochemistry. NPY-IR perikarya and fibers were found to be widely distributed in the ventral diencephalon, with high densities in the preopticoseptal, periventricular, and tuberal regions. Small neuronal cell groups were infiltrated with a dense network of varicose NPY-IR fibers in the lateral preoptic area. The LHRH-IR perikarya were located mainly in the preopticoseptal region, diagonal band of Broca, lamina terminalis, and periventricular and infundibular nuclei. A few LHRH-IR neurons and fibers were scattered in the mamillary region. The overlap between the NPY and LHRH systems was apparent in the periventricular, paraventricular, and infundibular nuclei. Double-labeling immunohistochemistry showed NPY-IR axon varicosities in contact with LHRH-IR perikarya and main dendrites. The putative innervation of LHRH neurons by NPY-IR fibers was also seen in 1-microm-thick plastic sections and with confocal laser scanning microscope, thus further supporting the functional impact of NPY-IR terminals on LHRH-IR neurons. The present findings suggest that the hypophysiotropic LHRH-synthesizing neurons may be innervated by intrahypothalamic NPY-IR fibers. Confirmation by ultrastructural analysis would demonstrate that the LHRH system in the human hypothalamus is regulated by NPY, as has been demonstrated in nonhuman species.

Detection of estrogen receptor-beta messenger ribonucleic acid and 125I-estrogen binding sites in luteinizing hormone-releasing hormone neurons of the rat brain

Luteinizing hormone-releasing hormone (LHRH) neurons of the forebrain play a pivotal role in the neuroendocrine control of reproduction. Although serum estrogen levels influence many aspects of LHRH neuronal activity in the female, earlier studies were unable to detect estrogen receptors (ERs) within LHRH neurons, thus shaping a consensus view that the effects of estradiol on the LHRH neuronal system are mediated by interneurons and/or the glial matrix. The present studies used dual-label in situ hybridization histochemistry (ISHH) and combined LHRH-immunocytochemistry/125I-estrogen binding to readdress the estrogen-receptivity of LHRH neurons in the female rat. In ISHH experiments we found that the majority of LHRH neurons exhibited hybridization signal for the "beta" form of ER (ER-beta). The degree of colocalization was similar in topographically distinct populations of LHRH neurons and was not significantly altered by estradiol (67.2+/-1.8% in ovariectomized and 73.8+/-4.2% in ovariectomized and estradiol-treated rats). In contrast, the mRNA encoding the classical ER-alpha could not be detected within LHRH neurons. In addition, in vivo binding studies using 125I-estrogen revealed a subset of LHRH-immunoreactive neurons (8.8%) which accumulated the radioligand thus providing evidence for the translation of ER protein(s) within these cells. The findings that most LHRH neurons in the female rat express ER-beta mRNA and at least some are capable of binding 125I-estrogen challenge the current opinion that estrogen does not exert direct effects upon the LHRH neuronal system.

Estrogen binding and estrogen receptor characterization (ERalpha and ERbeta) in the cholinergic neurons of the rat basal forebrain

Estrogen is thought to enhance cognitive functions by modulating the production of acetylcholine in basal forebrain neurons; a system that projects to the cerebral cortex and hippocampus and plays a central role in learning and memory. To elucidate the mechanism of estrogen action in the cholinergic system, we utilized a combined in vivo autoradiography/immunocytochemistry technique to evaluate the distribution of estrogen binding sites in cholinergic neurons of the rat basal forebrain. The results of these studies revealed that a portion of the cholinergic neurons in the medial septum (41%), vertical (32%) and horizontal (29%) limbs of the diagonal band and in the substantia innominata/nucleus basalis (4%) contained estrogen receptors. Through the use of a double-label in situ hybridization/immunocytochemistry technique we have shown that estrogen receptor-alpha is the predominant estrogen receptor in the cholinergic neurons, with only a few cells containing estrogen receptor-beta. The results of these studies provide evidence that biologically active estrogen receptors are present in the basal forebrain cholinergic neurons of the adult rat brain, with estrogen receptor-alpha being the predominant receptor subtype. The demonstration that cholinergic neurons contain estrogen receptors is consistent with the possibility that estrogen directly modulates the activity of cholinergic neurons in rats and may provide insight as to how estrogen improves cognitive functions in women.

Estrogen is more than just a "sex hormone": novel sites for estrogen action in the hippocampus and cerebral cortex

For decades estrogen was thought of only as a "sex hormone," as it plays a fundamental role in regulating behavioral and physiological events essential for successful procreation. In recent years, estrogen has been shown to exert effects on the structure and function of the hippocampus and cortex. The discovery of a new estrogen receptor (ER-beta) and localization of ER-alpha and ER-beta mRNAs in the pyramidal cells of the rat hippocampus and ER-beta mRNA in rat cortex have provided new insight into how estrogen may directly modulate the structure and function of these neurons. Moreover, recent in vivo (125)I-estrogen binding studies have shown that nuclear estrogen binding sites are widely distributed in the pyramidal cells throughout CA1-3 of the hippocampus and laminae II-VI of the isocortex, demonstrating that ER mRNAs are translated into biologically active protein. The functional impact of estrogen receptor localization in the cortex and hippocampus may prove relevant to the emerging role for estrogen as a protective factor in neurodegenerative injury. This potential role is further highlighted by the recent findings that the expression of ER-alpha and ER-beta changes following ischemic brain injury and that these changes correlate with the hormonal modulation of protective factors. These data provide the first evidence that the expression of ERs in the adult cortex is not static, but instead, responsive to neuronal injury and perhaps additional factors that influence the cortical environment and status of these neurons. Together, these data indicate that estrogen has a far greater effect on the hippocampus and isocortex than previously thought. Furthermore, these new findings challenge our current thinking about steroid hormones and their mechanism(s) of action in regions associated with learning and memory and affected by the neurodegenerative conditions of aging.

Estrogen receptor beta and progesterone receptor mRNA in the intergeniculate leaflet of the female rat

The present study was undertaken to explore the possibility that the integration of hormonal cues in the regulation of neuroendocrine mechanisms may occur outside of the hypothalamus at the level of the lateral geniculate body. In situ hybridization for mRNA encoding estrogen receptor beta and progesterone receptor was carried out on sections containing the lateral geniculate body using [35S]-labeled antisense riboprobes. Labeled cells were present in different limbic and hypothalamic sites as described previously. Populations of cells distributed homogeneously in the ventral lateral geniculate nucleus and intergeniculate leaflet were also found to express mRNA for estrogen receptor beta and progesterone receptor. The dorsal lateral geniculate nucleus lacked specific labeling for either type of gonadal steroid hormone receptor mRNA. The present observation together with the recent demonstration of a direct pathway between the intergeniculate leaflet and hypothalamic neuroendocrine cells indicate that integration of hormonal and photic stimuli in the central regulation of endocrine mechanisms occurs outside of the hypothalamus in the lateral geniculate body.

Estrogen receptor immunoreactivity is present in the majority of central histaminergic neurons: evidence for a new neuroendocrine pathway associated with luteinizing hormone-releasing hormone-synthesizing neurons in rats and humans

The central regulation of the preovulatory LH surge requires a complex sequence of interactions between neuronal systems that impinge on LH-releasing hormone (LHRH)-synthesizing neurons. The reported absence of estrogen receptors (ERs) in LHRH neurons indicates that estrogen-receptive neurons that are afferent to LHRH neurons are involved in mediating the effects of this steroid. We now present evidence indicating that central histaminergic neurons, exclusively located in the tuberomammillary complex of the caudal diencephalon, serve as an important relay in this system. Evaluation of this system revealed that 76% of histamine-synthesising neurons display ERalpha-immunoreactivity in their nucleus; furthermore histaminergic axons exhibit axo-dendritic and axo-somatic appositions onto LHRH neurons in both the rodent and the human brain. Our in vivo studies show that the intracerebroventricular administration of the histamine-1 (H1) receptor antagonist, mepyramine, but not the H2 receptor antagonist, ranitidine, can block the LH surge in ovariectomized estrogen-treated rats. These data are consistent with the hypothesis that the positive feedback effect of estrogen in the induction of the LH surge involves estrogen-receptive histamine-containing neurons in the tuberomammillary nucleus that relay the steroid signal to LHRH neurons via H1 receptors.

Estradiol modulates bcl-2 in cerebral ischemia: a potential role for estrogen receptors

We have shown that physiological levels of estradiol exert profound protective effects on the cerebral cortex in ischemia induced by permanent middle cerebral artery occlusion. The major goal of this study was to begin to elucidate potential mechanisms of estradiol action in injury. Bcl-2 is a proto-oncogene that promotes cell survival in a variety of tissues including the brain. Because estradiol is known to promote cell survival via Bcl-2 in non-neural tissues, we tested the hypothesis that estradiol decreases cell death by influencing bcl-2 expression in ischemic brain injury. Furthermore, because estradiol may protect the brain through estrogen receptor-mediated mechanisms, we examined expression of both receptor subtypes ERalpha and ERbeta in the normal and injured brain. We analyzed gene expression by RT-PCR in microdissected regions of the cerebral cortex obtained from injured and sham female rats treated with estradiol or oil. We found that estradiol prevented the injury-induced downregulation of bcl-2 expression. This effect was specific to bcl-2, as expression of other members of the bcl-2 family (bax, bcl-x(L), bcl-x(S), and bad) was unaffected by estradiol treatment. We also found that estrogen receptors were differentially modulated in injury, with ERbeta expression paralleling bcl-2 expression. Finally, we provide the first evidence of functional ERbeta protein that is capable of binding ligand within the region of the cortex where estradiol-mediated neuroprotection was observed in cerebral ischemia. These findings indicate that estradiol modulates the expression of bcl-2 in ischemic injury. Furthermore, our data suggest that estrogen receptors may be involved in hormone-mediated neuroprotection.

Estradiol induces galanin gene expression in the pituitary of the mouse in an estrogen receptor alpha-dependent manner

Estradiol imprinting plays an important role in the regulation of galanin (GAL) gene expression in the rat. In the anterior pituitary gland, GAL gene expression is greatly induced by estrogen. The relative involvement that the two estrogen receptor subtypes, alpha and beta, have in regulating this induction is not known. We have utilized ER alpha-knock-out (ER alphaKO) mice to discriminate the roles of ER alpha and ER beta in the regulation of GAL gene expression in the anterior pituitary gland. Our goals were to measure the effects of estradiol on GAL gene expression by solution hybridization ribonuclease protection assay in wild-type mice and to determine the roles of ER alpha and, indirectly, ER beta by measuring the same response in the ER alphaKO mice. Estradiol treatment for one week elevated GAL gene expression 30-40 fold in the wild-type mouse pituitary. Evaluation of estrogen effects on GAL gene expression in the anterior pituitary of ER alphaKO animals revealed that ER alpha is essential, because no response to estrogen was observed in these animals. Since ER beta mRNA was identified in the anterior pituitary by RT-PCR, but estrogen had no effects on GAL gene expression in the ER alphaKO mice, the beta subtype of ER does not appear to participate in estrogen-evoked GAL gene expression in the mouse anterior pituitary.

Expression of estrogen receptor-beta protein in rodent ovary

Estrogen is an essential hormone for the LH surge and ovulation. The primary source of estrogen is from ovarian granulosa cells and in rats, estrogen, in turn, increases granulosa cell number and enhances FSH-stimulated gene expression in these cells. Thus, rat granulosa cells both respond to and synthesize estrogen. To further elucidate the mechanisms mediating the actions of estrogen in granulosa cells, we have identified and characterized the estrogen receptor-beta (ER-beta) subtype in rodent granulosa cells. ER-beta protein was localized to the nuclei of rat granulosa cells in preantral and antral follicles by immunocytochemistry, coincident with the location of ER-beta messenger RNA (mRNA). Immunoprecipitation and Western blot analysis using ER-beta specific antisera demonstrated a protein of approximately 60 kDa in granulosa cells prepared from PMSG-primed immature mice and estrogen-treated immature rats. Extracts from granulosa cells specifically bound an estrogen response element and the complex was recognized by antisera to ER-beta. A synthetic steroid estrogen radioligand, [125I]-17alpha-iodovinyl-11beta-methoxyestradiol ([125I]-VME2), bound to cytosolic granulosa cell preparations with high affinity (estimated K(D) value of 401 +/- 83 pM, and Bmax value of 102 +/- 9 fmol/mg protein). ER-beta protein levels rapidly declined following hCG treatment consistent with the reported decrease in binding activity and ER-beta mRNA levels by high levels of gonadotropins. Overall, we have demonstrated that 1) ER-beta protein is the dominant estrogen receptor subtype present in rodent granulosa cells, 2) this receptor is functional, and 3) it is regulated by ovulatory doses of gonadotropins. Thus, ER-beta is likely to be a mediator of estrogen action in rodent granulosa cells during follicular development.

Biologically active estrogen receptor-beta: evidence from in vivo autoradiographic studies with estrogen receptor alpha-knockout mice

Estrogen receptor-1 (ER beta) messenger RNA (mRNA) has been detected in the brain of wild-type and estrogen receptor-alpha knockout (ER alphaKO) mice. The present study used in vivo autoradiography to evaluate the binding of 125I-estrogen, a compound with a similar affinity for both ERs to ascertain whether ER beta mRNA is translated into biologically active receptor. Mice were injected with 125I-estrogen, and sections were mounted on slides and opposed to emulsion. After exposure, labeled cells were seen in ER alphaKO brain regions where ER beta is expressed (preoptic and paraventricular nuclei of the hypothalamus; bed nucleus of the stria terminalis; amygdala; entorhinal cortex; and dorsal raphe). Competition studies with 17beta-estradiol eliminated binding in the ER alphaKO brain, whereas 16alphaIE2, an ER alpha selective agonist and dihydrotestosterone had no effect. In contrast, competition studies with 16alphaIE2 in wild-type mice eliminated 125I-estrogen binding to ER alpha and resulted in a pattern of residual binding comparable to that seen in the ER alphaKO brain. The results demonstrate that residual estrogen binding sites are present in regions of the ER alphaKO brain where ER beta is expressed, brain regions that were also seen after eliminating binding to ER alpha in wild-type mice. These data provide the first evidence that ER beta mRNA is translated into a biologically active protein in the rodent brain.

The effects of progesterone on oxytocin mRNA levels in the paraventricular nucleus of the female rat can be altered by the administration of diazepam or RU486

Oxytocin (OT) facilitates the onset of maternal behaviour in the late pregnant rat, enhances uterine contractility at parturition, and elicits milk ejection during lactation. If the rising estradiol (E2 and declining progesterone (P) of late pregnancy is reproduced in a virgin ovariectomized rat by implanting E2- and P-filled capsules for 2 weeks followed by removal of P-containing implants 36-48 h prior to death, OT messenger ribonucleic acid (mRNA) levels increase in the paraventricular and supraoptic nuclei (PVN and SON) of the rat. Both E2 administration and P withdrawal are necessary to increase OT mRNA, but the mechanisms of these effects are not understood. P may work within the PVN although P receptors are reported to be sparse or non-existent in the PVN or outside the PVN on PR-containing neurones that project to OT-containing neurones or via membrane bound receptors that are known to bind neurosteroids and gamma aminobutyric acid (GABA). To determine the mechanism through which P may inhibit or P withdrawal may increase OT mRNA levels, virgin ovariectomized (OVX) rats received sequential E2 and P via Silastic implants for 14 days. On day 13, prior to removal of P capsules on day 14, the rats were given the benzodiazepine agonist, diazepam, or saline injections subcutaneously (s.c.) twice daily until death on day 16. OT mRNA levels were increased in the steroid-treated group that received saline but not diazepam. In experiment 2, P capsules were removed on day 14 or pharmacological P withdrawal was induced by injecting RU486 injections s.c. twice daily until death 48 h later. OT mRNA levels were increased in the steroid-treated group that received RU486. Subsequent studies demonstrated the expression of PR mRNA within the rat PVN. The data suggest that gonadal steroids may influence PVN OT mRNA levels by modulating the GABA(A) receptor or by directly altering gene transcription via the PR.

Distribution of pre-pro-glucagon and glucagon-like peptide-1 receptor messenger RNAs in the rat central nervous system

Glucagon-like peptide-1 (GLP-1) is derived from the peptide precursor pre-pro-glucagon (PPG) by enzymatic cleavage and acts via its receptor, glucagon-like peptide-1 receptor (GLP-1R). By using riboprobes complementary to PPG and GLP-1R, we described the distribution of PPG and GLP-1R messenger RNAs (mRNAs) in the central nervous system of the rat. PPG mRNA-expressing perikarya were restricted to the nucleus of the solitary tact or to the dorsal and ventral medulla and olfactory bulb. GLP-1R mRNA was detected in numerous brain regions, including the mitral cell layer of the olfactory bulb; temporal cortex; caudal hippocampus; lateral septum; amygdala; nucleus accumbens; ventral pallium; nucleus basalis Meynert; bed nucleus of the stria terminalis; preoptic area; paraventricular, supraoptic, arcuate, and dorsomedial nuclei of the hypothalamus; lateral habenula; zona incerta; substantia innominata; posterior thalamic nuclei; ventral tegmental area; dorsal tegmental, posterodorsal tegmental, and interpeduncular nuclei; substantia nigra, central gray; raphe nuclei; parabrachial nuclei; locus ceruleus, nucleus of the solitary tract; area postrema; dorsal nucleus of the vagus; lateral reticular nucleus; and spinal cord. These studies, in addition to describing the sites of GLP-1 and GLP-1R synthesis, suggest that the efferent connections from the nucleus of the solitary tract are more widespread than previously reported. Although the current role of GLP-1 in regulating neuronal physiology is not known, these studies provide detailed information about the sites of GLP-1 synthesis and potential sites of action, an important first step in evaluating the function of GLP-1 in the brain. The widespread distribution of GLP-1R mRNA-containing cells strongly suggests that GLP-1 not only functions as a satiety factor but also acts as a neurotransmitter or neuromodulator in anatomically and functionally distinct areas of the central nervous system.

LHRH and sexual dimorphism

An increasing amount of evidences suggests that galanin plays an important role in the regulation of reproduction in the rat. Galanin is colocalized with luteinizing hormone-releasing hormone (LHRH) in a subset of LHRH neurons, and the pattern of coexpression is sexually dimorphic, with a higher incidence of colocalization and level of galanin mRNA and peptide expression in females than in males. Therefore, the role of galanin may be unique to females, as are the LH surge and ovulation. The colocalization of LHRH and galanin is neonatally determined by an epigenetic mechanism involving the testis, whereas the expression of galanin in adult LHRH neurons is upregulated by estrogen and modulated by progesterone. The action of these sex steroids requires intact neurotransmission towards LHRH neurons, indicating that their action is mediated by interneurons.

Evidence for the colocalization of estrogen receptor-beta mRNA and estrogen receptor-alpha immunoreactivity in neurons of the rat forebrain

Estrogen receptor beta (ER beta) mRNA is expressed in several rat brain regions where ER alpha is abundant. In vitro studies have shown that ER alpha and ER beta can heterodimerize and that the activity of this complex may be different than an ER alpha or ER beta homodimer complex. The purpose of the present study was to ascertain if ER alpha and ER beta are co-expressed by certain neuronal populations using a double label in situ hybridization/immunocytochemistry method. The results revealed that neurons in the bed nucleus of the stria terminalis, medial amygdala and preoptic area contain both ERs, with the vast majority of the neurons being double labeled. In other brain regions including the arcuate nucleus, cortical amygdaloid nuclei and ventromedial nucleus, only a few double-labeled cells were detected, while neurons in the paraventricular nucleus, supraoptic nucleus, and cerebral cortex expressed only ER beta mRNA. The results of these double label experiments provide the first evidence that ER alpha and ER beta coexist in neurons under in vivo conditions and suggest that estrogens may differentially modulate the activity of certain neuronal populations depending on whether the cells expresses ER alpha, ER beta or both ERs.

The effect of estrogens and antiestrogens in a rat model for hot flush

The present studies evaluated the effect of estrogens and the selective estrogen receptor modulator (SERM) tamoxifen and raloxifene in a rat model for hot flush. In this model, ovariectomized rats were treated for 8 or 9 days either sc or po. Rats were dependent to morphine by implanting a morphine pellet (75 mg each) sc on days 3 and 5 of treatment. On the last day of treatment, a thermistor, connected to a data acquisition system, was placed on the tail of each animal and morphine addiction was withdrawn by naloxone injection (1.0 mg/kg, sc). Temperature measurements were taken for 1 h under ketamine (80 mg/kg, im) anesthesia. In general, vehicle treated rats showed a 5-6 degrees C elevation of their tail skin temperature with the peak occurring about 15 min after naloxone injection. 17 alpha-Ethinyl estradiol (EE) was evaluated both sc and po using a broad range of doses. The IC50 for inhibition of tail skin temperature rise was approximately 0.1 mg/kg, sc and 0.2 mg/kg, po. 17 beta-Estradiol and 17 alpha-estradiol were also active in this model whereas non-estrogenic steroids were inactive. Raloxifene and tamoxifen were tested for estrogen agonist and antagonist activity administered sc and po. Raloxifene did not demonstrate reproducible estrogen agonist activity at doses up to 10 mg/kg, whereas it demonstrated significant antagonistic activity at the 10 mg/kg dose regardless of the route of administration. Tamoxifen exhibited significant estrogen agonist activity at all doses tested (0.1-10.0 mg/kg) and was a significant antagonist of EE at the 1.0 mg/kg dose. Our results demonstrate the potential utility of this model to evaluate and discriminate among classes of compounds with varying degrees of estrogen agonist and antagonist activity.

Comparative distribution of estrogen receptor-alpha (ER-alpha) and beta (ER-beta) mRNA in the rat pituitary, gonad, and reproductive tract

The present study used in situ hybridization histochemistry to compare the distribution of estrogen receptor (ER)-alpha and ER-beta mRNA-containing cells in rat pituitary, gonads, uterus, and prostate of intact animals or after hormonal manipulations. Cryostat tissue sections were hybridized with 35S-labeled antisense riboprobes complimentary to ER-alpha or ER-beta mRNA, stringently washed and apposed to emulsion. The results of these studies indicate that the expression of the two receptors is tissue and region specific, with estrogen target tissues specifically expressing ER-alpha, ER-beta, or both forms of ER. In the intact rat, ER-alpha and ER-beta mRNA were both seen in the pituitary, although more cells expressed ER-alpha than ER-beta mRNA. The distribution of the two transcripts in the ovary was qualitatively different, with ER-alpha being primarily localized in the stromal cells, while ER-beta mRNA was concentrated in the granulosa cells of developing follicles. In the uterus, ER-alpha mRNA was abundant in the stromal and epithelial cells of the endometrium, while only very weak ER-beta hybridization signal was detected in these cells. ER-beta mRNA-expressing cells, but not ER-alpha, were also detected in the prostate and in the Sertoli cells, and the large, round spermatocytes of the testis. Gonadectomy markedly attenuated the expression of ER-beta mRNA in the peripheral tissues, with the level of ER-beta mRNA in the uterus and prostate reduced to non-detectable levels. The results of these in situ hybridization studies demonstrate that the distribution and regulation of ER-beta mRNA expression is tissue specific and different from ER-alpha mRNA. The differential expression of ERs in these tissues may explain in part the tissue selective activity of estrogenic compounds.

The estrogen receptor beta subtype: a novel mediator of estrogen action in neuroendocrine systems

The recent discovery that an additional estrogen receptor (ERbeta) subtype is present in many rat, mouse, and human tissues has advanced our understanding of the mechanisms underlying estrogen signalling. Ligand-binding experiments have shown specific binding of 17beta-estradiol by ERbeta with an affinity similar to that of ERalpha. The rat tissue distribution and/or the relative level of ERalpha and ERbeta expression seems to be quite different, i.e., moderate to high expression in uterus, testis, pituitary, ovary, kidney, epididymis, and adrenal for ERalpha and prostate, ovary, lung, bladder, brain, bone, uterus, and testis for ERbeta. Within the same organ it often appears that the ER subtypes are expressed in different cell types, supporting the hypothesis that the ER's may have different biological functions. The cell type-specific expression of ERalpha and ERbeta in rat prostate, testis, uterus, ovary, and brain and the distribution of ERbeta mRNA in the ERalpha knock-out mouse brain are discussed. The discovery of ERbeta suggests the existence of two previously unrecognized pathways of estrogen signalling; via the ERbeta subtype in tissues exclusively expressing this subtype and via the formation of heterodimers in tissues expressing both ER subtypes. The existence of two ER subtypes, their differential expression pattern, and different actions on certain response elements could provide explanations for the striking species-, cell-, and promoter-specific actions of estrogens and antiestrogens. The challenge for the future is to unravel the detailed physiological role of each subtype and to use this knowledge to develop the next generation of ER-targeted drugs with improved therapeutic profiles in the treatment or prevention of osteoporosis, cardiovascular system disorders, Alzheimer's disease, breast cancer, and disorders of the urogenital tract.

Expression of estrogen receptor-beta messenger ribonucleic acid in oxytocin and vasopressin neurons of the rat supraoptic and paraventricular nuclei

The regulatory actions of estrogen on magnocellular oxytocin (OT) and vasopressin (VP) neurons of the paraventricular (PVN) and supraoptic (SON) nuclei are well documented. To date it is still debated whether the effect of estrogens is exerted directly or mediated by estrogen-sensitive interneurons. Previous immunocytochemical (ICC) and in situ hybridization (ISH) studies detected either low levels or absence of the classical estrogen receptor (ER-alpha) in the PVN and the SON of the rat. The present experiments using a combined ICC and ISH method were undertaken to examine the expression of the recently cloned beta form of ER (ER-beta) in OT- and VP-immunoreactive (IR) neuronal systems of the rat hypothalamus. The results demonstrate that the highest cellular levels of ER-beta messenger RNA (mRNA) in OT-IR neurons can be visualized in the caudal portion of the PVN and in an area ventro-medial to the central core of VP-IR cells. These neurons were previously shown to project caudally to the brain stem and the spinal cord to regulate autonomic functions. In addition, the whole rostro-caudal extent of the PVN and the SON contained OT-IR neurons that coexpressed variable levels of ER-beta mRNA. Similarly, the presence of ER-beta mRNA was seen in a large population of VP-IR paraventricular and supraoptic neurons. In the SON, somewhat stronger hybridization signal was detected in VP-IR neurons as compared with OT-IR neurons. Together, these findings provide strong support for the concept that the functions of OT- and VP-IR neurons in the PVN and the SON are regulated directly by estrogen and that the genomic effects of estrogens are mediated by ER-beta.

Comparative distribution of estrogen receptor-alpha and -beta mRNA in the rat central nervous system

Estrogen plays a profound role in regulating the structure and function of many neuronal systems in the adult rat brain. The actions of estrogen were thought to be mediated by a single nuclear estrogen receptor (ER) until the recent cloning of a novel ER (ER-beta). To ascertain which ER is involved in the regulation of different brain regions, the present study compared the distribution of the classical (ER-alpha) and novel (ER-beta) forms of ER mRNA-expressing neurons in the central nervous system (CNS) of the rat with in situ hybridization histochemistry. Female rat brain, spinal cord, and eyes were frozen, and cryostat sections were collected on slides, hybridized with [35S]-labeled antisense riboprobes complimentary to ER-alpha or ER-beta mRNA, stringently washed, and opposed to emulsion. The results of these studies revealed the presence of ER-alpha and ER-beta mRNA throughout the rostral-caudal extent of the brain and spinal cord. Neurons of the olfactory bulb, supraoptic, paraventricular, suprachiasmatic, and tuberal hypothalamic nuclei, zona incerta, ventral tegmental area, cerebellum (Purkinje cells), laminae III-V, VIII, and IX of the spinal cord, and pineal gland contained exclusively ER-beta mRNA. In contrast, only ER-alpha hybridization signal was seen in the ventromedial hypothalamic nucleus and subfornical organ. Perikarya in other brain regions, including the bed nucleus of the stria terminalis, medial and cortical amygdaloid nuclei, preoptic area, lateral habenula, periaqueductal gray, parabrachial nucleus, locus ceruleus, nucleus of the solitary tract, spinal trigeminal nucleus and superficial laminae of the spinal cord, contained both forms of ER mRNA. Although the cerebral cortex and hippocampus contained both ER mRNAs, the hybridization signal for ER-alpha mRNA was very weak compared with ER-beta mRNA. The results of these in situ hybridization studies provide detailed information about the distribution of ER-alpha and ER-beta mRNAs in the rat CNS. In addition, this comparative study provides evidence that the region-specific expression of ER-alpha, ER-beta, or both may be important in determining the physiological responses of neuronal populations to estrogen action.

Regulation of progesterone receptor messenger ribonucleic acid in the rat medial preoptic nucleus by estrogenic and antiestrogenic compounds: an in situ hybridization study

Progesterone receptor (PR) messenger RNA (mRNA) is concentrated in neurons of the preoptic area and other regions of the rat hypothalamus where it is colocalized with the estrogen receptor and regulated by changes in the steroid hormonal milieu. To date, little is known about the regulation of PR mRNA by estrogens and whether antiestrogenic compounds are capable of modulating its expression. The present studies used in situ hybridization to ascertain the time course of PR mRNA regulation in the medial preoptic nucleus by 17beta-estradiol, determine the effective dose required to elicit a response, and compare the efficacy of 17beta-estradiol with a variety of estrogenic or antiestrogenic compounds. The first series of studies revealed that the treatment of ovariectomized rats with 17beta-estradiol resulted in an increase in PR expression within 2 h, after which it remained elevated until 10 h postinjection and then returned to baseline levels. When ovariectomized rats were injected with 25-1000 ng/kg of 17beta-estradiol and euthanized 6 h later, a dose-dependent increase in the level of PR mRNA was observed, with a maximal response at 1000 ng/kg and an EC50 of 93.5 ng/kg. Subsequent studies evaluated the efficacy of a variety of estrogenic and antiestrogenic compounds in the rat preoptic nucleus. 17Beta-estradiol, diethylstilbestrol, and 17alpha-estradiol all significantly increased the level of PR mRNA, although the degree of induction varied with each compound. The injection of tamoxifen, raloxifene, toremifene, droloxifene, clomiphene, GW 5638, or ICI 182,780 had no significant estrogenic effect on PR gene expression at the dose evaluated. In contrast, when tamoxifen or raloxifene, but not ICI 182,780, was administered in the antagonist mode, a significant dose-related decrease in the estradiol-induced level of PR mRNA was seen in the preoptic area. The results of these studies clearly demonstrate that PR mRNA expression in the rat preoptic area is rapidly stimulated by a small dose of 17beta-estradiol. Moreover, the present report has also shown that the estrogenic nature of compounds such as tamoxifen, raloxifene, toremifene, droloxifene, clomiphene, and GW 5638 cannot be predicted by their activity in peripheral tissues. Together, the results of these studies provide important information about the central activity of estrogens and provide evidence for their tissue-specifc actions in the rat.