Direct regulation of postnatal GnRH neurons by the progesterone derivative allopregnanolone in the mouse

The mechanisms through which gonadal steroids exert critical feedback actions upon the activity of the GnRH neurons are not understood. We have examined here whether progesterone may modulate the electrical activity of the GnRH neurons following its rapid metabolism to the neuroactive steroid allopregnanolone within the brain. Using an acute brain slice preparation, whole-cell, patch-clamp recordings were made from GnRH neurons of juvenile (postnatal d 15-20) and adult (postnatal d 60-70) female mice in the presence of tetrodotoxin. Progesterone (1 microM) was not observed to have any actions (up to 5 min exposure) upon GnRH neurons. However, allopregnanolone (500 nM-1 microM) exerted rapid (<1 min) effects upon the baseline membrane potential of all GnRH neurons and also significantly (P < 0.01) enhanced their GABA responses by up to 4-fold. All GABA and allopregnanolone responses were abolished by the GABA(A) receptor antagonist bicuculline. No differences were detected in the allopregnanolone sensitivity of GnRH neurons recorded from juvenile and adult GnRH neurons. These results provide the first evidence for a direct action of the neurosteroid allopregnanolone on postnatal GnRH neurons and suggest a new mechanism through which fluctuating progesterone levels may influence the secretory activity of these important neurons in the female mouse.

New evidence for estrogen receptors in gonadotropin-releasing hormone neurons

Estrogen exerts a critical regulatory influence upon the biosynthetic and secretory activity of the gonadotropin-releasing hormone (GnRH) neurons. It seems likely that estrogen regulates the behavior of the GnRH neuron through multiple transsynaptic, neuronal-glial, and direct membrane modes of action. Advances in our understanding of these mechanisms over the last 3 years are highlighted. In addition, very recent studies have begun to provide evidence for the expression of estrogen receptors (ERs) in GnRH neurons in the rodent. Although not yet firmly established, the current consensus supports the hypothesis that GnRH neurons express ERbeta. Evidence exists for ERbeta mRNA expression by GnRH neurons throughout development and ERbeta immunoreactivity has now also been detected in these cells. Murine GnRH neurons have further been shown to express estrogen receptor-related receptor-alpha, an orphan receptor thought to constitutively activate estrogen response elements. Together, these findings provide a cornerstone for the reassessment of the role of ERs and related receptors in the direct genomic and potential nontranscriptional actions of estrogen upon the GnRH neuron.

Sexually dimorphic effects of testosterone on preoptic area calcitonin gene-related peptide mRNA expression depend upon neuron location and differential estrogen and androgen receptor activation

Experiments examined activational roles of gonadal steroids on the sexually dimorphic, calcitonin gene-related peptide-expressing neurons of the rat preoptic area. Gonadectomy of male rats followed by treatment with testosterone, dihydrotestosterone, or estrogen demonstrated that the tonic suppressive influence of testosterone on cellular levels of calcitonin gene-related peptide mRNA expression in the medial preoptic nucleus and anteroventral periventricular nucleus occurred through either ER- or AR-mediated mechanisms (P < 0.05). The gonadectomy of adult female rats demonstrated little tonic influence of ovarian steroids upon calcitonin gene-related peptide mRNA levels. However, the administration of male levels of testosterone to ovariectomized rats resulted in reduced calcitonin gene-related peptide mRNA expression within the medial preoptic nucleus (P < 0.05) and, strikingly, a 3-fold induction in calcitonin gene-related peptide mRNA expression in the anteroventral periventricular nucleus (P < 0.01). Testosterone's effects in the medial preoptic nucleus and anteroventral periventricular nucleus of the female required both ER and AR activation. Dual labeling immunocytochemical studies revealed that less than 10% of calcitonin gene-related peptide neurons in the male expressed ARs compared with approximately 50% in the female. These investigations reveal that sexually differentiated region- and steroid receptor-specific mechanisms function in association with the sex differences in circulating gonadal steroids to maintain the sexually dimorphic nature of calcitonin gene-related peptide expression in the preoptic area of the adult rat.

Regulation of gonadotropin-releasing hormone (GnRH) gene expression during GnRH neuron migration in the mouse

The mechanisms underlying the migration of the gonadotropin-releasing hormone (GnRH) neurons from the nose into the forebrain are not resolved. In an attempt to characterize further the migrating GnRH neurons, we have employed in situ hybridization techniques and transgenic mouse models to examine levels of GnRH mRNA and GnRH gene transcription in GnRH neurons during migration in the mouse. In the first experiment, cellular levels of GnRH mRNA in neurons located throughout the nose and forebrain were examined in embryonic day (E) 12.5, 14.5, 16.5 and 19.5 mice using in situ hybridization. The GnRH mRNA content of cells located in both the nose (p < 0.01) and forebrain (p < 0.05) was found to increase significantly from E12.5 to E19.5 and from E14.5 to E19.5, respectively. However, cellular levels of GnRH mRNA were not significantly different in neurons located in the nose compared with the brain at each developmental age. In the second experiment, levels of GnRH gene transcription were investigated at E14.5 using two different GNLZ transgenic mouse lines in which 13.5 kb of GnRH gene sequences direct the expression of the LacZ reporter to the nucleus of GnRH neurons. Migrating GnRH neurons displayed up to a 3-fold increase (p < 0.01) in transgene expression, an index of GnRH transcription, precisely as they approached and entered the forebrain. These results indicate that GnRH gene expression in migrating GnRH neurons is likely regulated by temporal as well as spatial factors and that, as found postnatally, this may involve both transcriptional and post-transcriptional regulatory mechanisms.

Oestrogen modulation of noradrenaline neurotransmission

Noradrenaline (NA) exerts an important neuromodulatory role within diverse neuronal networks and is also likely to be a target for oestrogen in the brain. Distinct, highly organized sub-populations of brainstem NA neurons express oestrogen receptors (ERs) and some of these display species differences. A number of genes expressed by NA neurons, ranging from transcription factors to co-released neuropeptides, are influenced by oestrogen and may have roles in the predominant enhancement in NA activity in response to oestrogen. The effects of oestrogen on genes involved directly in NA biosynthesis are less clear, although promoter transgenic work suggests oestrogen to have a powerful influence upon tyrosine hydroxylase gene transcription. In addition to direct actions on NA neurons, evidence suggests that oestrogen also regulates adrenergic receptor expression and function within the ER-rich hypothalamus as well as the cerebral cortex. Together, these investigations point to a multifaceted pre- and postsynaptic regulation of NA transmission by oestrogen. While the hypothalamic neuronal networks controlling reproduction remain the principal site of investigation of oestrogen regulated NA transmission, the role of oestrogen and NA and their potential interactions in cortical functioning are becoming of equal interest.

Heterogeneity in the basic membrane properties of postnatal gonadotropin-releasing hormone neurons in the mouse

The electrophysiological characteristics of unmodified, postnatal gonadotropin-releasing hormone (GnRH) neurons in the female mouse were studied using whole-cell recordings and single-cell RT-PCR methodology. The GnRH neurons of adult animals fired action potentials and exhibited distinguishable voltage-current relationships in response to hyperpolarizing and depolarizing current injections. On the basis of their patterns of inward rectification, rebound depolarization, and ability to fire repetitively, GnRH neurons in intact adult females were categorized into four cell types (type I, 48%; type II, 36%; type III, 11%; type IV, 5%). The GnRH neurons of juvenile animals (15-22 d) exhibited passive membrane properties similar to those of adult GnRH neurons, although only type I (61%) and type II (7%) cells were encountered, in addition to a group of "silent-type" GnRH neurons (32%) that were unable to fire action potentials. A massive, action potential-independent tonic GABA input, signaling through the GABA(A) receptor, was present at all ages. Afterdepolarization and afterhyperpolarization potentials (AHPs) were observed after single action potentials in subpopulations of each GnRH neuron type. Tetrodotoxin (TTX)-independent calcium spikes, as well as AHPs, were encountered more frequently in juvenile GnRH neurons compared with adults. These observations demonstrate the existence of multiple layers of functional heterogeneity in the firing properties of GnRH neurons. Together with pharmacological experiments, these findings suggest that potassium and calcium channels are expressed in a differential manner within the GnRH phenotype. This heterogeneity occurs in a development-specific manner and may underlie the functional maturation and diversity of this unique neuronal phenotype.

Differing, spatially restricted roles of ionotropic glutamate receptors in regulating the migration of gnrh neurons during embryogenesis

We have examined here the role of glutamate in regulating the process of tangential neuronal migration during embryogenesis by investigating the roles of AMPA and NMDA receptors in the migration of the gonadotropin-releasing hormone (GnRH) neurons from the nose to the hypothalamus. We first determined that GluR1-4 subunit mRNAs were present from embryonic day (E) 12.5 along the complete nose-brain migratory pathway of the GnRH neurons, whereas that of the obligatory NMDAR1 transcript was present only in brain regions of GnRH migration. In vivo studies revealed that AMPA receptor antagonism between E12.5 and E16.5 resulted in a significant (p < 0.05) accumulation of GnRH neurons in the nose adjacent to the cribiform plate. In contrast, NMDA receptor antagonism over E12.5-E16.5 or E13.5-E16.5 caused a selective increase (p < 0.05) in the number of GnRH neurons located in their final resting place within the diagonal band of Broca and preoptic area. Dual-labeling studies using GnRH promoter-LacZ transgenic mice, which facilitate the identification of receptors in GnRH neurons, identified the presence of NMDAR1 receptors in approximately 6% of embryonic GnRH neurons located throughout the migratory pathway. Postnatally, the percentage of GnRH neurons expressing NMDAR1 increased to 50%. These results indicate that tonic AMPA receptor activation enhances the migration of GnRH neurons from the nose into the brain, whereas that of NMDA receptor activation slows the final phase of GnRH migration within the forebrain. These in vivo observations demonstrate differing, spatially restricted roles for AMPA and NMDA receptor activation in the process of tangential neuronal migration.

Identification of neurokinin B-expressing neurons as an highly estrogen-receptive, sexually dimorphic cell group in the ovine arcuate nucleus

Studies were undertaken to examine the hypothesis that neurons expressing neurokinin B (NKB) may represent an estrogen-receptive input to GnRH neurons in the sheep. Cells immunoreactive for NKB were located almost exclusively within the arcuate nucleus of the ovine hypothalamus. Dual labeling experiments revealed that essentially all NKB neurons (97%) were immunoreactive for estrogen receptor alpha and that NKB-immunoreactive fibers were found in close proximity to approximately 40% of GnRH neurons located in the rostral preoptic area as well as intermingled with GnRH fibers in the median eminence. The analysis of male and female brains revealed a marked female-dominant sex difference in the numbers of NKB neurons, and sections obtained from in utero androgen-treated females indicated that this sex difference resulted from an organizational influence of testosterone during neural development. In adult ovariectomized ewes, in situ hybridization studies failed to detect any significant effect of 8- to 26-h exposure of estrogen on cellular NKB messenger RNA levels. Together, these studies identify the first sexually differentiated neuronal cell population in the ovine hypothalamus and, remarkably, show that essentially all of these female-dominant NKB neurons express estrogen receptors. Although these neurons may be involved in any number of steroid-dependent, sexually differentiated functions in the sheep, the neuroanatomical evidence for potential NKB inputs to GnRH neurons suggests a role for this novel population in the regulation of reproductive function.

Late postnatal reorganization of GABA(A) receptor signalling in native GnRH neurons

The molecular and cellular characteristics of the gonadotropin-releasing hormone (GnRH) neurons have been difficult to ascertain due to their scattered distribution within the basal forebrain. Using morphological criteria coupled with single cell RT-PCR postidentification, we have developed a method for investigating native GnRH neurons in the mouse brain and used it to examine the development of GABA(A) receptor signalling in this phenotype. Following the harvesting of the cytoplasmic contents of individual GnRH neurons, single cell multiplex RT-PCR experiments demonstrated that GABAA receptor alpha1-5, beta1-3 and gamma2 & 3 subunit transcripts were expressed by both neonatal (postnatal day 5) and juvenile (day 15-20) GnRH neurons in a heterogeneous manner. Following puberty, this profile was reduced to a predominant alpha1, alpha5, beta1, gamma2 subunit complement in rostral preoptic area GnRH neurons of the adult female. Whole-cell patch-clamp recordings revealed little difference between juvenile and adult GnRH neurons in their resting membrane potential and spontaneous firing rates. All GnRH neurons were found to be subjected to a tetrodotoxin-insensitive, tonic GABAergic barrage signalling through the GABA(A) receptor. However, marked heterogeneity in the sensitivity of individual juvenile GnRH neurons to GABA was revealed and, in parallel with the change in subunit mRNA profile, this was dramatically reduced in the reproductively competent adult GnRH neurons. These findings provide the first electrical and molecular characterization of the GnRH phenotype and demonstrate a novel pattern of late postnatal reorganization of native GABA(A) receptor gene expression and signalling in the GnRH neuronal population.

Role of the GABA(A) receptor gamma2 subunit in the development of gonadotropin-releasing hormone neurons in vivo

We have employed transgenic mouse models to examine the functional significance of the gamma2 subunit of the GABA(A) (gamma-aminobutyric acid) receptor to the correct development of gonadotropin-releasing hormone (GnRH) neurons in vivo. In the first experiment, the expression of gamma2 subunit protein by the GnRH phenotype was determined using transgenic mice in which GnRH gene sequences direct the expression of the LacZ reporter to the nucleus of the GnRH neurons. This greatly facilitates the immunocytochemical identification of non-nuclear-located antigens within GnRH neurons and revealed that approximately 25% of juvenile GnRH neurons were immunoreactive for the gamma2 subunit and that this increased to 40% in pubertal mice. In the second experiment, GnRH mRNA expression was examined in the brains of gamma2 subunit knockout mice (gamma2(0/0)) and their wild-type (gamma2+/+) littermates at embryonic day 15 and postnatal days (P) 0 and 11-16 using in situ hybridization. The distribution and numbers of cells expressing GnRH mRNA in gamma2+/+ and gamma2(0/0) mice were not found to differ at any age. However, the GnRH mRNA content of medial septal cells was significantly lower in gamma2(0/0) compared with gamma2+/+ mice at P11-16 (P<0.05) and the same trend was observed for preoptic area neurons. These results demonstrate that while the gamma2 subunit of the GABA(A) receptor is expressed by postnatal GnRH neurons, their embryonic development does not require a functional gamma2 subunit. In contrast, postnatal GnRH mRNA expression was found to be dependent upon signalling through the GABA(A) receptor.

Long-term plasticity of postsynaptic GABAA-receptor function in the adult brain: insights from the oxytocin neurone

The subunit switching of ligand-gated receptors is a potentially important mechanism through which synaptic plasticity can be achieved in the nervous system. Although established in an activity-dependent manner for neurotransmission that is mediated by excitatory amino acids, there is much less direct evidence for a role of subunit switching in long-term plasticity of GABAA receptors in the adult. We argue that the hypothalamic oxytocin neurones, which exhibit marked plasticity through each reproductive cycle, provide an excellent model of both presynaptic and postsynaptic long-term plasticity of GABA-mediated transmission in the mature nervous system. The postsynaptic plasticity involves GABAA-receptor-subunit switching in an activity-independent manner. It also has profound effects on the electrical behaviour of the oxytocin neurones and, thus, the neural control of pregnancy and lactation.

Progesterone regulation of GABAA receptor plasticity in adult rat supraoptic nucleus

Marked plasticity in GABAA receptor signalling occurs in adult oxytocin neurons of the supraoptic nucleus (SON) through the modulation of GABAA receptor alpha subunits during pregnancy. The present studies were undertaken to examine the potential mechanisms underlying this plasticity. In vivo microdialysis experiments in conscious rats revealed that no significant changes in extracellular GABA concentrations occurred within the SON over the last two days of pregnancy and the time of parturition itself. In situ hybridization studies examined the effects of gonadal steroid manipulation upon the GABAA receptor subunits expressed by SON neurons (alpha1, alpha2, beta2 and gamma2 subunits) and demonstrated that cellular levels of the alpha1 subunit were increased following 8 days oestrogen and progesterone treatment. Estrogen alone or allopregnanolone, the progesterone derivative, had no effect on alpha1 subunit mRNA expression in the SON. Immunocytochemical experiments demonstrated progesterone receptors in many neural populations but not within the SON of late pregnant rats. These studies indicate that alterations in endogenous GABA release within the SON are unlikely to be responsible for the GABAA receptor plasticity exhibited by oxytocin neurons in late pregnancy. Rather, data demonstrate that the fluctuating concentrations of progesterone during pregnancy act indirectly on SON neurons to modulate alpha1 subunit mRNA expression. Together, these experiments provide evidence for the ligand-independent induction of GABAA receptor plasticity in the adult brain by progesterone.

Transgenics identify distal 5'- and 3'-sequences specifying gonadotropin-releasing hormone expression in adult mice

GnRH neurons play a critical role in regulating gonadotropin secretion, but their scattered distribution has prevented detailed understanding of their molecular and cellular properties in vivo. Using GnRH promoter-driven transgenics we have examined here the role of 5'- and 3'-murine GnRH sequences in specifying GnRH expression in the adult mouse. Transgenic mice bearing a lacZ construct incorporating 5.5 kb of 5'-, all the introns and exons, and 3.5 kb of 3'-murine GnRH sequence were found to express beta-galactosidase (betagal) immunoreactivity in approximately 85% of all GnRH neurons. Deletion of GnRH sequence 3' to exon II had no effect upon transgene expression in the GnRH population (89%) but resulted in the appearance of ectopic betagal immunoreactivity in several regions of the brain. The production of additional mice in which 5'-elements were deleted to leave only -2.1 kb of sequence resulted in an approximately 40% reduction in the number of GnRH neurons expressing betagal. Mice in which further deletion of 400 bp allowed only -1.7 kb of 5'-sequence to remain exhibited a complete absence of betagal immunoreactivity within GnRH and other neurons. These results suggest that elements 3' to exon II of the GnRH gene have little role in enabling GnRH expression within the GnRH phenotype but, instead, are particularly important in repressing the GnRH gene in non-GnRH neurons. In contrast, elements located between -2.1 and -1.7 kb of distal 5'-sequence appear to be critical for the in vivo activation of GnRH expression within GnRH neurons in the adult brain.

Sexually dimorphic ontogeny of GABAergic influences on periventricular somatostatin neurons

The biosynthesis and secretion of somatostatin (SRIH) within the hypothalamic periventricular-median eminence (PeN-ME) pathway follows a sexually differentiated developmental pattern beginning in the early neonatal period. It is generally accepted that testosterone plays a role in these processes, but the mechanisms underlying the age and sex differences are poorly understood. The present study sought to investigate the hypothesis that gamma-aminobutyric acid (GABA) may play a role in determining sex differences in SRIH neuronal activity. Using an in vitro hypothalamic preparation where more than 97% of the immunoreactive SRIH is contained within the PeN-ME pathway, peptide release in response to the GABA(A) receptor antagonist, bicuculline, was followed through development. In the male a stimulatory response, indicative of an inhibitory GABAergic tone on SRIH secretion, was observed as early as postnatal day (P) 5. This persisted throughout juvenile development (P10, P17) and was present also in the adult male (P75), but in the peripubertal period the response to bicuculline was first lost (P25) and then reversed to an inhibition (P40), suggesting a transient switch to an apparent stimulatory GABAergic tone on SRIH release. By contrast, in the female, no bicuculline responsiveness was seen until P25 when it caused a decrease in SRIH release which persisted into adulthood. Using in situ hybridization studies we found no evidence to support the view that these age- and sex-dependent differences were due to changes in the expression of GABA(A) receptor alpha-subunits (alpha(1) and alpha(2)) which are colocalised in the PeN SRIH neurons. Following adult gonadectomy, the bicuculline response was abolished in the male, whereas, in the female it was reversed and identical in magnitude to the response in the intact male. These results demonstrate marked sex differences in GABA(A)-receptor-mediated influences on SRIH release which develop soon after birth and, in the adult, depend on gonadal factors. In the male these factors activate a primarily inhibitory influence, whereas in the female they facilitate an apparently stimulatory tone of GABA on SRIH secretion via the GABA(A) receptor. Our findings thus support the view that GABAergic transmission may play a key role in generating sex differences in the mode of SRIH secretion from the hypothalamus which has been shown to be a major factor in determining the sexually dimorphic patterns of growth hormone secretion.

Detection of estrogen receptor alpha and beta messenger ribonucleic acids in adult gonadotropin-releasing hormone neurons

The behavior of the gonadotropin-releasing hormones (GnRH) neurons controlling fertility is dependent upon cyclic fluctuations in circulating concentrations of estrogen. However, the nature of estrogen action upon these cells has remained controversial due to their dispersed distribution within the brain, and evidence indicating that they do not express nuclear estrogen receptors (ERs) in vivo. We report here an acute brain slice preparation that enables individual living GnRH neurons to be identified within the mouse brain and show, using single cell multiplex RT-PCR, that the greater than 50% of GnRH neurons in adult and prepubertal females contain ERalpha messenger RNA. Approximately 10% of GnRH neurons contained ERbeta transcripts that were always coexistent with ERalpha. Single cell RT-PCR analysis of nonGnRH cells located in the medial preoptic area revealed a similar coexpression pattern of ERalpha and ERbeta transcripts. In contrast, single striatal cells were not found to contain ERbeta despite ERalpha being present in approximately 25% of cells. The analysis of single GnRH neurons in cycling female mice revealed that the detection of ERalpha and ERbeta transcripts was lowest on proestrus (ERalpha, 18% of all GnRH neurons; ERbeta, 0%) compared with diestrus (44% and 6%) and estrus (75% and 19%, respectively). Using a novel approach that enables single cell RT-PCR analysis of GnRH neurons, we present here evidence for the cyclic expression of ERalpha and ERbeta messenger RNAs within prepubertal and adult female GnRH neurons.

Localization of estrogen-receptive neurons projecting to the GnRH neuron-containing rostral preoptic area of the ewe

Estrogen exerts important feedback effects upon the biosynthetic and secretory behavior of gonadotropin-releasing hormone (GnRH) neurons to control reproductive functioning. The mechanism of estrogen action upon these neurons is unclear and seems likely to involve the transsynaptic regulation of GnRH neurons. The objective of the present study was to identify the estrogen-receptive neural populations which project to the general vicinity of the GnRH perikarya in the rostral preoptic area and diagonal band of Broca (rPOA/DBB) of the ewe. Intact breeding-season ewes received an injection of the retrograde tracer fluorogold (FG) into the rPOA/DBB, and their hypothalami and brainstems examined for the presence of FG and estrogen receptor alpha (ERalpha) immunocytochemistry. Retrogradely labeled neurons were identified principally within the lateral septum (LS), lamina terminalis, bed nucleus of the stria terminalis, POA, arcuate nucleus (ARN), ventromedial nucleus (VMN) and median eminence. Smaller numbers of FG-immonoreactive cells were found in the caudal brainstem where they resided mostly in the ventrolateral medulla (VLM). Dual-labeled cells exhibiting both FG and ERalpha staining were prominent in the POA, LS and at all rostrocaudal levels of the VMN and ARN. Small numbers of dual-labeled cells were found in the VLM. These observations indicate that a number of distinct ERalpha-expressing neural populations project to the rPOA/DBB where the majority of the GnRH perikarya are found in the ewe. Although it is not possible to determine the direct connectivity of these projections with GnRH neurons, the findings provide an initial neuroanatomical framework through which the transsynaptic actions of estrogen on ovine GnRH neurons may be tested.

Identification and characterization of estrogen receptor alpha-containing neurons projecting to the vicinity of the gonadotropin-releasing hormone perikarya in the rostral preoptic area of the rat

Gonadal steroids exert a powerful regulatory influence upon the functioning of gonadotropin-releasing hormone (GnRH) neurons despite the apparent absence of gonadal steroid receptors in these cells. By using retrograde-tracing techniques combined with dual-labeling immunocytochemistry, we show here that distinct populations of estrogen receptor alpha (ERalpha)-containing neurons located in the hypothalamus and caudal brainstem project to the vicinity of the GnRH perikarya located in the rostral preoptic area (rPOA). The strongest estrogen-receptive afferent projection to this area originated from neurons located in the anteroventral periventricular and medial preoptic nuclei of the preoptic area. Approximately 50% of arcuate nucleus neurons projecting to the rPOA were demonstrated to synthesize either neuropeptide Y or beta-endorphin, but little evidence was found for ERalpha immunoreactivity in either of these specific subpopulations. Over 80% of all tyrosine hydroxylase-expressing neurons in the arcuate nucleus expressed ERalpha, but none projected to the rPOA. In the caudal brainstem, the A1 and A2 norepinephrine neurons comprised nearly all of the retrogradely labeled neurons. However, only the A2 afferents expressed ERalpha immunoreactivity, whereas the A1 afferents coexpressed neuropeptide Y. These observations, combined with the anterograde labeling data of others, provide neuroanatomical evidence for the existence of specific estrogen-receptive neuronal cell populations that project to the rPOA and may be involved in the estrogen-dependent transsynaptic regulation of GnRH neurons in the rat.

Promoter transgenics reveal multiple gonadotropin-releasing hormone-I-expressing cell populations of different embryological origin in mouse brain

Gonadotropin-releasing hormone-I (GnRH-I) is thought to be expressed by a single, highly spatially restricted group of neurons, which originate in the olfactory placode and migrate through the nose into the medial septum and hypothalamus from where they control fertility. Transgenic mice bearing a 13.5 kb GnRH-I-lacZ reporter construct were derived and found to express high levels of beta-galactosidase mRNA and protein within the septohypothalamic GnRH neurons in a correct temporal and spatial manner. Unexpectedly, low levels of beta-galactosidase were also present in three further populations of cells within the lateral septum, bed nucleus of the stria terminalis, and tectum. Analysis of wild-type mice with three different GnRH-I antibodies revealed distinct and transient patterns of GnRH-I peptide expression during development in all three of these populations revealed by transgenics. The synthesis of GnRH by cells of the lateral septum was the most persistent and remained until the third postnatal week. Embryonic "small eye" Pax-6 null mice, which fail to develop an olfactory placode, were also examined and shown to have equivalent populations of GnRH-I-immunoreactive cells in the lateral septum, tectum, and bed nucleus of the stria terminalis but none of the migrating cells that form the septohypothalamic GnRH population. These results prove that so-called "ectopic" expression in promoter transgenic lines can reflect authentic developmental patterns of gene expression. They further provide the first demonstration in mammalian brain that multiple neuronal populations of different embryological origin express GnRH-I peptide during embryonic and postnatal development.

Fluctuating estrogen and progesterone receptor expression in brainstem norepinephrine neurons through the rat estrous cycle

Norepinephrine (NE) neurons within the nucleus tractus solitarii (NTS; A2 neurons) and ventrolateral medulla (A1 neurons) represent gonadal steroid-dependent components of several neural networks regulating reproduction. Previous studies have shown that both A1 and A2 neurons express estrogen receptors (ERs). Using double labeling immunocytochemistry we report here that substantial numbers of NE neurons located within the NTS express progesterone receptor (PR) immunoreactivity, whereas few PRs are found in ventrolateral medulla. The evaluation of ERa and PR immunoreactivity in NE neurons through the estrous cycle revealed a fluctuating pattern of expression for both receptors within the NTS. The percentage of A2 neurons expressing PR immunoreactivity was low on metestrus and diestrus (3-7%), but increased significantly to approximately 24% on proestrous morning and remained at intermediate levels until estrus. The pattern of ERalpha immunoreactivity in A2 neurons was more variable, but a similar increment from 11% to 40% of NE neurons expressing ERa was found from diestrus to proestrus. Experiments in ovariectomized, estrogen-treated and estrogen-plus progesterone-treated rats revealed that PR immunoreactivity in A2 neurons was induced strongly by estrogen treatment, whereas progesterone had no significant effect. The numbers of ERalpha-positive NE neurons were not influenced by steroid treatment. These observations provide direct evidence for PRs in NE neurons of the brainstem and show that cyclical patterns of gonadal steroid receptor expression exist in A2, but not A1, neurons through the rat estrous cycle. The expression of PR in A2 neurons appears to be driven principally by circulating estrogen concentrations. The fluctuating levels of ERalpha and PR expression in these brainstem NE neurons may help generate cyclical patterns of biosynthetic and electrical activity within reproductive neural networks.

Developmental sex differences in amino acid neurotransmitter levels in hypothalamic and limbic areas of rat brain

GABA, glutamate and aspartate are the predominant amino acid neurotransmitters in the mammalian brain. We have previously reported a developmental sex difference in messenger RNA levels of glutamate decarboxylase, the rate-limiting enzyme in GABA synthesis [Davis A. M. et al. (1996) Horm. Behav. 30, 538-552]. Males were found to have significantly higher levels of messenger RNA in many steroid-concentrating regions of the hypothalamus and limbic system on day 1 of life. Therefore, in this study, we have examined levels of amino acid neurotransmitters during early postnatal development in many of the same or related brain areas. We found that levels of all three transmitters change as animals age. While both GABA and aspartate concentrations increase, glutamate levels decrease. In addition, there are sex differences in neurotransmitter levels in several areas examined, including the ventromedial and arcuate nuclei of the hypothalamus, and the CA1 region of the hippocampus. Sex differences for GABA occur only on postnatal days 1 and 5. However, sex differences in aspartate occur later in development (postnatal day 20). The CA1 region of males has a significantly greater concentration of GABA, glutamate and aspartate than females on postnatal day 1. In addition, treatment of females with testosterone propionate on the day of birth results in increased GABA levels, suggesting that these sex differences may be the result of hormone exposure during development. We hypothesize that these hormonally mediated sex differences in amino acid transmitters early in development contribute to the establishment of sexually dimorphic neuronal architecture in the adult.

Correlation of hypothalamic somatostatin mRNA expression and peptide content with secretion: sexual dimorphism and differential regulation by gonadal factors

Sex differences in growth hormone (GH) secretion in the rat are thought to be determined, to a large extent, by gonadal steroid-dependent sex differences in somatostatin (SRIH) secretion from neurones in the periventricular nucleus (PeN) which project to the median eminence (ME). The present study aimed to obtain direct evidence for sex differences and gonadal regulation of SRIH release within this pathway and to determine the relationships between SRIH mRNA expression, SRIH peptide content and SRIH secretion in the adult rat. Somatostatin mRNA expression in the PeN and peptide content in both PeN and ME were higher in males than females (P<0.05). However, both basal and 56 mM K+-stimulated SRIH release in vitro from hypothalamic explants incorporating the PeN-ME pathway were higher (P<0.01) in females. The gonadectomy of female rats resulted in significantly reduced basal levels of SRIH release equivalent to that of males but had no effect on SRIH mRNA/peptide content or K+-stimulated release. In contrast, gonadectomy of male rats reduced SRIH mRNA and peptide contents and elevated K+-stimulated secretion (P<0.01) to levels similar to that seen in intact females, without affecting basal release. In summary, these results demonstrate that in the PeN-ME of the adult rat: (1) SRIH mRNA and peptide content is well correlated and sexually dimorphic but dependent on gonadal factors in the male only; (2) SRIH secretion is sexually dimorphic and dependent on gonadal factors; but (3) differences in mRNA/peptide content do not reflect secretory capacity; and (4) gonadal factors differentially modulate SRIH secretory dynamics in males and females.

Ontogeny and sexual differentiation of somatostatin biosynthesis and secretion in the hypothalamic periventricular-median eminence pathway

The biosynthesis of somatostatin (SRIH) in the hypothalamic periventricular nucleus (PeN) is sexually differentiated in neonatal and adult rats by virtue of the organizational and activational actions, respectively, of sex steroid hormones. Little information exists, however, on the normal pattern of maturation of these neurones or on how the sexually differentiated biosynthesis may relate to ontogenetic changes in somatostatin secretion during the neonatal and pubertal periods of development. Hence in the present study we determined the postnatal developmental profile of SRIH mRNA and peptide levels in the PeN-median eminence (ME) pathway as well as SRIH secretion, using an acute explant preparation, from the day of birth, through puberty and into adulthood in male and female rats. The results demonstrate that: (1) developmental sex differences in SRIH biosynthesis in PeN neurones occurred in an orderly cascade with differences observed for mRNA expression at postnatal day 5, for peptide content in the perikarya at postnatal day 10 and for peptide content in the nerve terminal (ME) by postnatal day 25; (2) sex differences in SRIH release were not evident prior to postnatal day 40; and (3) the developmental profile of SRIH biosynthesis in PeN neurones is unique compared with other hypothalamic (ventromedial nucleus) and extrahypothalamic (parietal cortex) populations. Specific developmental changes in the biosynthetic and secretory activity of the hypothalamic SRIH PeN-ME pathway may have a functional importance in the maturation of hypothalamic SRIH pathways involved in the regulation of GH secretion.

Estrogen receptor expression in brainstem noradrenergic neurons of the sheep

Noradrenergic neurons are implicated in the estrogen-dependent neural regulation of luteinizing hormone secretion in a variety of mammalian species. The current study has used immunocytochemical methods to determine whether estrogen receptors (ER) are expressed within the brainstem of the ewe and to establish their relationship to noradrenergic neurons. Using a monoclonal mouse antiserum directed against the N-terminal of ERa, four distinct populations of ER alpha-immunoreactive cells were identified in ovine medulla and pons. The largest population was found in the superficial laminae of the spinal nucleus of the trigeminal nerve, followed by the nucleus tractus solitarius, lateral area postrema, and ventrolateral medulla. Double-labelling immunocytochemistry using antisera directed against the ER alpha and dopamine-beta-hydroxylase revealed that noradrenergic neurons expressing ER immunoreactivity were only found in ventrolateral medulla (A1 cell group) and nucleus tractus solitarius (A2 cell group). No double-labelled cells were identified in the A5, A6, or A7 noradrenergic cell groups. ERs were expressed with a clear rostrocaudal topography within the A1 and A2 populations, with 80-90% of noradrenergic neurons expressing ERA alpha in the caudalmost medulla as compared with less than 5% rostral to the obex. Our findings demonstrate that, as in the rat, the ovine A1 and A2 neurons express ERs in a defined topographical manner, while, dissimilar to the rat, ER alpha is not synthesized by noradrenergic neurons in the other cell groups. These observations indicate that A1 and A2 noradrenergic neurons in the ovine brainstem are likely to be influenced by circulating estrogens and lay the neuroanatomical foundations for investigating the functional role of these cell populations within the gonadotropin-releasing hormone neuron network of the sheep.

Estrogen-dependent ontogeny of sex differences in somatostatin neurons of the hypothalamic periventricular nucleus

The sexually dimorphic profile of GH secretion is thought to be engendered by gonadal steroids acting in part on hypothalamic periventricular somatostatin (SOM) neurons. The present study set out to examine and characterize the development of sex differences in these SOM neurons. In the first series of experiments, we used in situ hybridization to examine SOM messenger RNA (mRNA) expression within the periventricular nucleus (PeN) of male and female rats on postnatal day 1 (P1), P5, and P10. Cellular SOM mRNA content was found to increase from P1 to P10 in both sexes (P < 0.01), but was 24% (P < 0.05) and 38% (P < 0.01) higher in males on P5 and P10, respectively. A second series of experiments examined the SOM peptide content of the PeN in developing rats and found increasing levels from P1 to P10, with a 44% higher SOM content in males compared with females on P10 (P < 0.05). The third series of experiments questioned the role of gonadal steroids in engendering sex differences in SOM mRNA expression by determining the effects of neonatal gonadectomy (GDX) and replacement of dihydrotestosterone or estradiol benzoate. The SOM mRNA content of PeN neurons in P5 males gonadectomized on the day of birth was the same as that in P5 females and was significantly reduced compared with that in sham-operated P5 males (P < 0.05). Male rats GDX on P1 and treated with estradiol benzoate from P1 to P5 had cellular SOM mRNA levels similar to those in intact males on P5, whereas dihydrotestosterone treatment had no effect. Treatment of intact males with an androgen receptor antagonist, cyproterone acetate, on P1 had no effect on cellular SOM mRNA on P5, whereas male rats given the aromatase inhibitor 1,4,6-androstatriene-3,17-dione from P1 to P5 had lower (P < 0.05) SOM mRNA levels than controls. In the final set of experiments, dual labeling immunocytochemistry showed that SOM neurons in the PeN of P5 rats did not contain estrogen receptor-alpha, but expressed androgen receptors in a sexually dimorphic manner. These results demonstrate that a sex difference in SOM biosynthesis, which persists into adulthood, develops between P1 and P5 in PeN neurons. Despite the absence of estrogen receptor-alpha in these neurons, the organizational influence of testosterone only occurs after its aromatization to estrogen.