Sandra L. Petersen

Estrogen Receptor-β Immunoreactivity in Luteinizing Hormone-Releasing Hormone Neurons of the Rat Brain

Abstract 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-β (ER-β) mRNA, whereas, they seemed to lack ER-α mRNA expression. In addition, we observed nuclear uptake of 125I-estrogen by a subset of these cells. These data suggest that ER-β is the chief receptor isoform mediating direct estrogen effects upon LHRH neurons. To verify the translation of ER-β 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-β-immunoreactivity in the majority of LHRH cells. The incidence of ER-β expression was similarly high in LHRH neurons of ovariectomized female (87.8 ± 2.3%, mean ± SEM),...

Detection of Estrogen Receptor-β 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 “β” form of ER (ER-β). 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-tre...

Direct and Indirect Regulation of Gonadotropin-Releasing Hormone Neurons by Estradiol

Abstract Estrogen signaling to GnRH neurons is critical for coordinating the preovulatory surge release of LH with follicular maturation. Until recently it was thought that estrogen signaled GnRH neurons only indirectly through numerous afferent systems. This minireview presents new evidence indicating that GnRH neurons are directly regulated by estradiol (E2), primarily through estrogen receptor (ER)-β, and indirectly through E2-sensitive neurons in the anteroventral periventricular (AVPV) region. The data described suggest that E2 generally represses GnRH gene expression but that this repression is transiently overcome by indirect E2-dependent signals relayed by AVPV neurons. We also present evidence that the AVPV neurons responsible for relaying E2 signals to GnRH neurons are multifunctional gamma aminobutyric acid-ergic/glutamatergic/neuropeptidergic neurons.

Dual-Phenotype GABA/Glutamate Neurons in Adult Preoptic Area: Sexual Dimorphism and Function

It is generally assumed that the inhibitory neurotransmitter GABA and the stimulatory neurotransmitter glutamate are released from different neurons in adults. However, this tenet has made it difficult to explain how the same afferent signals can cause opposite changes in GABA and glutamate release. Such reciprocal release is a central mechanism in the neural control of many physiological processes including activation of gonadotropin-releasing hormone (GnRH) neurons, the neural signal for ovulation. Activation of GnRH neurons requires simultaneous suppression of GABA and stimulation of glutamate release, each of which occurs in response to a daily photoperiodic signal, but only in the presence of estradiol (E2). In rodents, E2 and photoperiodic signals converge in the anteroventral periventricular nucleus (AVPV), but it is unclear how these signals differentially regulate GABA and glutamate secretion. We now report that nearly all neurons in the AVPV of female rats express both vesicular glutamate transporter 2 (VGLUT2), a marker of hypothalamic glutamatergic neurons, as well as glutamic acid decarboxylase and vesicular GABA transporter (VGAT), markers of GABAergic neurons. These dual-phenotype neurons are the main targets of E2 in the region and are more than twice as numerous in females as in males. Moreover, dual-phenotype synaptic terminals contact GnRH neurons, and at the time of the surge, VGAT-containing vesicles decrease and VGLUT2-containing vesicles increase in these terminals. Thus, we propose a new model for ovulation that includes dual-phenotype GABA/glutamate neurons as central transducers of hormonal and neural signals to GnRH neurons.

Suppression of spontaneous LH surges in estrogen-treated ovariectomized rats by microimplants of antiestrogens into the preoptic brain

Studies by others have shown that parenteral administration of antiestrogens blocks the positive feedback effect of estrogen on the luteinizing hormone (LH) surge mechanism. Since all estrogen-accumulating cells could be affected by this treatment, it is difficult to identify the site(s) at which this steroid acts to affect LH surges. In the present study we attempted to deprive specific hypothalamic neurons of estrogen by stereotaxically implanting antiestrogen-containing microcannulae into the brains of ovariectomized (OVX) rats which, otherwise, were completely estrogenized. The animal model used in these studies was the 14-day OVX rat into which 2 estradiol-containing Silastic capsules were inserted s.c. on day 14 (day 0). Microcannulae were placed into either the medial or lateral preoptic nuclei (MPN, LPN) on day 0 and the effects on LH release were examined 2 days later (day 2). When empty cannulae were placed into the MPN or LPN, 6 of 7 and 8 of 8 rats, respectively, had normal spontaneous LH surges. In contrast, when cannulae containing either CI-628, LY 10074 or Keoxifene were implanted into MPN only 33.3, 0, and 14.3% of the rats, respectively, had LH surges by 16.00 h on day 2 (time of LH peak). When antiestrogen-containing cannulae were placed into the LPN, all rats displayed normal LH patterns of release and concentrations. The antiestrogens did not prevent estrogen from suppressing elevated high post-ovariectomy plasma LH concentrations (negative feedback). To evaluate whether Keoxifene affected releasable luteinizing hormone-releasing hormone (LH-RH), we examined the effects of MPN-Keoxifene implants on LH secretion evoked by electrochemical stimulation (ECS) of the MPN or the medial basal hypothalamus (MBH). In ketamine-anesthetized rats with empty cannulae, plasma LH increased significantly to reach peak concentrations 30-45 min after ECS. Similar LH concentrations and release patterns occurred in rats with the antiestrogen implant. Other studies examined the effects of MPN-Keoxifene implants on norepinephrine (NE) concentrations and rate constants following administration of alpha-methyl-p-tyrosine. NE concentrations and rate constants in the MPN and median eminence did not differ significantly in rats which had received empty versus Keoxifene-containing microcannulae. In the final series of studies we examined the response of LH-RH neurons to an intracerebroventricular (i.c.v.) infusion of norepinephrine (20 micrograms). Plasma LH peaked within 10 min after i.c.v. NE and, thereafter, declined towards baseline. Keoxifene did not affect LH-RH neuronal responsiveness to i.c.v. NE.(ABSTRACT TRUNCATED AT 400 WORDS)

Frequency-Dependent Recruitment of Fast Amino Acid and Slow Neuropeptide Neurotransmitter Release Controls Gonadotropin-Releasing Hormone Neuron Excitability

The anteroventral periventricular nucleus (AVPV) is thought to play a key role in regulating the excitability of gonadotropin-releasing hormone (GnRH) neurons that control fertility. Using an angled, parahorizontal brain slice preparation we have undertaken a series of electrophysiological experiments to examine how the AVPV controls GnRH neurons in adult male and female mice. More than half (59%) of GnRH neurons located in the rostral preoptic area were found to receive monosynaptic inputs from the AVPV in a sex-dependent manner. AVPV stimulation frequencies <1 Hz generated short-latency action potentials in GnRH neurons with GABA and glutamate mediating >90% of the evoked fast synaptic currents. The AVPV GABA input was dominant and found to excite or inhibit GnRH neurons in a cell-dependent manner. Increasing the AVPV stimulation frequency to 5–10 Hz resulted in the appearance of additional poststimulus inhibitory as well as delayed excitatory responses in GnRH neurons that were independent of ionotropic amino acid receptors. The inhibition observed immediately following the end of the stimulation period was mediated partly by GABAB receptors, while the delayed activation was mediated by the neuropeptide kisspeptin. The latter response was essentially absent in Gpr54 knock-out mice and abolished by a Gpr54 antagonist. Together, these studies show that AVPV neurons provide direct amino acid and neuropeptidergic inputs to GnRH neurons. Low-frequency activation generates predominant GABA/glutamate release with higher frequency activation recruiting release of kisspeptin. This frequency-dependent release of amino acid and neuropeptide neurotransmitters greatly expands the range of AVPV control of GnRH neuron excitability.

Distribution of mRNAs encoding the arylhydrocarbon receptor, arylhydrocarbon receptor nuclear translocator, and arylhydrocarbon receptor nuclear translocator‐2 in the rat brain and brainstem

Dioxin exposure alters a variety of neural functions, most likely through activation of the arylhydrocarbon receptor (AhR) pathway. Many of the adverse effects, including disruption of circadian changes in hormone release and depressed appetite, seem to be mediated by hypothalamic and/or brainstem neurons. However, it is unclear whether these effects are direct or indirect, because there have been no comprehensive studies mapping the expression of components of the AhR pathway in the brain. Therefore, we used a sensitive in situ hybridization histochemical (ISHH) method to map the neural expression of AhR mRNA, as well as those of the mRNAs encoding the AhR dimerization partners, arylhydrocarbon receptor nuclear translocator (ARNT) and ARNT2. We found that AhR, ARNT, and ARNT2 mRNAs were widely distributed throughout the brain and brainstem. There was no neuroanatomic evidence that AhR is preferentially colocalized with ARNT or ARNT2. However, ARNT2, unlike ARNT expression, was relatively high in most regions. The most noteworthy regions in which we found AhR, ARNT, and ARNT2 mRNA were several hypothalamic and brainstem regions involved in the regulation of appetite and circadian rhythms, functions that are disrupted by dioxin exposure. These regions included the arcuate nucleus (Arc), ventromedial hypothalamus (VMH), paraventricular nucleus (PVN), suprachiasmatic nucleus (SCN), nucleus of the solitary tract (NTS), and the dorsal and median raphe nuclei. This neuroanatomic information provides important clues as to the sites and mechanisms underlying the previously unexplained effects of dioxins in the central nervous system. J. Comp. Neurol. 427:428–439, 2000.

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

Topographical distribution of estrogen receptor‐β (ER‐β)‐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‐β immunoreactivity that was confined to cell nuclei. Neuronal populations differed markedly with respect to the intensity of the ER‐β signal. Magnocellular OT neurons in the PVH, SO, and accessory cell groups typically contained low levels of the ER‐β 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‐β 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‐β 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‐β in the human. These neuroanatomical studies provide detailed information about the topographical distribution and cellular abundance of ER‐β 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. J. Comp. Neurol. 473:315–333, 2004.

Dual Label in Situ Hybridization Studies Provide Evidence that Luteinizing Hormone-Releasing Hormone Neurons Do Not Synthesize Messenger Ribonucleic Acid for μ, κ, or δ Opiate Receptors1

Abundant evidence suggests that opiatergic neurons play an important intermediary role in the regulation of LHRH release by ovarian steroids; however, it is unclear whether opiates communicate directly or indirectly with LHRH neurons. To investigate this issue, we used dual label in situ hybridization histochemistry to determine whether LHRH neurons synthesize messenger RNA (mRNA) for mu, kappa, and/or delta opiate receptors. For these studies, we examined both intact (n = 3) and ovariectomized, steroid-treated rats. Ten of the ovariectomized rats were implanted 1 week later (day 0) with SILASTIC brand (Dow Corning) capsules of estradiol. On the morning of day 2, half of the estradiol-treated rats were injected with 5 mg progesterone. All animals were killed at approximately 1530 h on day 2. We found that cells expressing mu, kappa, and delta opiate receptor mRNAs were in all sections that also contained LHRH neurons. In every case, LHRH neurons were seen to be surrounded by or in close proximity to cells containing mu, kappa, or delta mRNAs. However, regardless of steroid treatment, we found no neurons containing both LHRH mRNA and mRNAs encoding any of the three receptor subtypes. These results support the hypothesis that LHRH neurons are regulated indirectly by opiatergic neurons.

Identification of Prolactin-Sensitive GABA and Kisspeptin Neurons in Regions of the Rat Hypothalamus Involved in the Control of Fertility

High levels of circulating prolactin are known to cause infertility, but the precise mechanisms by which prolactin influences the neuroendocrine axis are yet to be determined. We used dual-label in situ hybridization to investigate whether prolactin-receptor (PRLR) mRNA is expressed in GnRH neurons. In addition, because γ-aminobutyric acidergic and kisspeptin neurons in the rostral hypothalamus are known to regulate GnRH neurons and, hence, might mediate the actions of prolactin, we investigated whether these neurons coexpress PRLR mRNA. (35)S-labeled RNA probes to detect PRLR mRNA were hybridized together with digoxigenin-labeled probes to detect either GnRH, Gad1/Gad2, or Kiss1 mRNA in the rostral hypothalamus of ovariectomized (OVX), estradiol-treated rats. Additional sets of serial sections were cut through the arcuate nucleus of OVX rats, without estradiol replacement, to examine coexpression of PRLR mRNA in the arcuate population of kisspeptin neurons. PRLR mRNA was highly expressed throughout the rostral preoptic area, particularly in periventricular regions surrounding the third ventricle, and there was a high degree of colocalization of PRLR mRNA in both Gad1/Gad2 and Kiss1 mRNA-containing cells (86 and 85.5%, respectively). In contrast, only a small number of GnRH neurons (<5%) was found to coexpress PRLR mRNA. In the arcuate nucleus of OVX rats, the majority of Kiss1 mRNA-containing cells also coexpressed PRLR mRNA. These data are consistent with the hypothesis that, in addition to a direct action on a small subpopulation of GnRH neurons, prolactin actions on GnRH neurons are predominantly mediated indirectly, through known afferent pathways.