Inhibition of sexual receptivity by anesthesia during estrogen priming

Analyses of rapid estrogen actions on rat ventromedial hypothalamic neurons

Rapid estrogen actions are widely diverse across many cell types. We conducted a series of electrophysiological studies on single rat hypothalamic neurons and found that estradiol (E2) could rapidly and independently potentiate neuronal excitation/depolarizations induced by histamine (HA) and N-Methyl-d-Aspartate (NMDA). Now, the present whole-cell patch study was designed to determine whether E2 potentiates HA and NMDA depolarizations - mediated by distinctly different types of receptors - by the same or by different mechanisms. For this, the actions of HA, NMDA, as well as E2, were investigated first using various ion channel blockers and then by analyzing and comparing their channel activating characteristics. Results indicate that: first, both HA and NMDA depolarize neurons by inhibiting K(+) currents. Second, E2 potentiates both HA and NMDA depolarizations by enhancing the inhibition of K(+) currents, an inhibition caused by the two transmitters. Third, E2 employs the very same mechanism, the enhancement of K(+) current inhibition, thus to rapidly potentiate HA and NMDA depolarizations. These data are of behavioral importance, since the rapid E2 potentiation of depolarization synergizes with nuclear genomic actions of E2 to facilitate lordosis behavior, the primary female-typical reproductive behavior.

Impact of generalized brain arousal on sexual behavior

Although there is an extensive amount known about specific sensory and motor functions of the vertebrate brain, less is understood about the regulation of global brain states. We have recently proposed that a function termed generalized arousal (Ag) serves as the most elemental driving force in the nervous system, responsible for the initial activation of all behavioral responses. An animal with increased generalized CNS arousal is characterized by greater motor activity, increased responsivity to sensory stimuli, and greater emotional lability. Implicit in this theory was the prediction that increases in generalized arousal would augment specific motivated behaviors that depend on arousal. Here, we address the idea directly by testing two lines of mice bred for high or low levels of generalized arousal and assessing their responses in tests of specific forms of behavioral arousal, sex and anxiety/exploration. We report that animals selected for differential generalized arousal exhibit marked increases in sensory, motor, and emotional reactivity in our arousal assay. Furthermore, male mice selected for high levels of generalized arousal were excitable and showed more incomplete mounts before the first intromission (IN), but having achieved that IN, they exhibited far fewer IN before ejaculating, as well as ejaculating much sooner after the first IN, thus indicating a high level of sexual arousal. Additionally, high-arousal animals of both sexes exhibited greater levels of anxiety-like behaviors and reduced exploratory behavior in the elevated plus maze and light-dark box tasks. Taken together, these data illustrate the impact of Ag on motivated behaviors.

Reverse engineering the lordosis behavior circuit

Reverse engineering takes the facts we know about a device or a process and reasons backwards to infer the principles underlying the structure-function relations. The goal of this review is to apply this approach to a well-studied hormone-controlled behavior, namely the reproductive stance of female rodents, lordosis. We first provide a brief overview on the considerable amount of progress in the analysis of female reproductive behavior. Then, we propose an analysis of the mechanisms of this behavior from a reverse-engineering perspective with the goal of generating novel hypotheses about the properties of the circuitry elements. In particular, the previously proposed neuronal circuit modules, feedback signals, and genomic mechanisms are considered to make predictions in this manner. The lordosis behavior itself appears to proceed ballistically once initiated, but negative and positive hormonal feedback relations are evident in its endocrine controls. Both rapid membrane-initiated and slow genomic hormone effects contribute to the behavior's control. We propose that the value of the reverse-engineering approach is based on its ability to provide testable, mechanistic hypotheses that do not emerge from either traditional evolutionary or simple reductionistic perspectives, and several are proposed in this review. These novel hypotheses may generalize to brain functions beyond female reproductive behavior. In this way, the reverse-engineering perspective can further develop our conceptual frameworks for behavioral and systems neuroscience.

Co-localization of midbrain projections, progestin receptors, and mating-induced fos in the hypothalamic ventromedial nucleus of the female rat

In female rats, sexual behavior requires the convergence of ovarian hormone signals, namely estradiol and progesterone, and sensory cues from the male on a motor output pathway. Estrogen and progestin receptors (ER and PR) are found in neurons in the hypothalamic ventromedial nucleus (VMH), a brain region necessary for lordosis, the stereotypic female copulatory posture. A subset of VMH neurons sends axonal projections to the periaqueductal gray (PAG) to initiate a motor output relay, and some of these projection neurons express PR. Previous studies showed that VMH neurons are activated during mating, based on the expression of the immediate early gene Fos. Many of the activated neurons expressed ER; however, it is not known if such activated neurons co-express PR. Fluorogold, a retrograde tracer, was injected into the PAG of ovariectomized rats to label neurons projecting from the VMH. Hormone-treated animals then were mated, and their brains were immunohistochemically stained for PR and Fos. Of the Fos-positive neurons, 33% were double-labeled for PR, 19% were double-labeled with Fluorogold, and 5% were triple-labeled for Fos, PR, and the retrograde tracer. The majority of triple-labeled neurons were found in the rostral, rather than caudal, portion of the VMH. These results show that PR-containing neurons are engaged during sexual behavior, which suggests that these neurons are the loci of hormonal-sensory convergence and hormonal-motor integration.

Acute estrogen potentiates excitatory responses of neurons in rat hypothalamic ventromedial nucleus

In a previous behavioral study, brief application of a membrane-limited estrogen to neurons in rat hypothalamic ventromedial nucleus (VMN) facilitated lordosis behavior-inducing genomic actions of estrogen. Here, electrophysiological recordings from single neurons were employed to characterize these membrane-initiated actions. From rat hypothalamic slices, electrical activity was recorded from neurons in the ventrolateral VMN, the cell group crucial for estrogen induction of lordosis. In addition to the resting activity, neuronal responses to histamine (HA) and N-methyl-d-aspartate (NMDA) were also recorded before, during, and after a brief (10-15 min) application of estradiol (E, 10 nM). These two transmitters were chosen because their actions are mediated by different mechanisms: HA through G protein-coupled receptors and NMDA by ligand-activated ion channels. Vehicle applications did not affect either resting activity or neuronal responses. In contrast, acute E exposure modulated neuronal responses to transmitters, with no significant effect on the resting activity. It potentiated excitatory responses to HAs (20 out of 48 cells tested) and to NMDA (10 out of 19 cells), but attenuated inhibitory responses to HA (3 out of 6 units). Both of these hormonal actions would increase VMN neuronal excitation. In separate experiments, neuronal excitation was found to be suppressed by anesthetics, which would block E's induction of lordosis when administered at the time of estrogen application. These data are consistent with the notion that increasing electrical excitation of VMN neurons can be a mechanism by which acute E exposure facilitates the lordosis-inducing genomic actions of estrogens.

Early membrane estrogenic effects required for full expression of slower genomic actions in a nerve cell line

Interpretations of steroid hormone actions as slow, nuclear, transcriptional events have frequently been seen as competing against inferences of rapid membrane actions. We have discovered conditions where membrane-limited effects potentiate later transcriptional actions in a nerve cell line. Making use of a two-pulse hormonal schedule in a transfection system, early and brief administration of conjugated, membrane-limited estradiol was necessary but not sufficient for full transcriptional potency of the second estrogen pulse. Efficacy of the first pulse depended on intact signal transduction pathways. Surprisingly, the actions of both pulses were blocked by a classical estrogen receptor (ER) antagonist. Thus, two different modes of steroid hormone action can synergize.

Estrogen-induced remodeling of hypothalamic neural circuitry

For decades, sexual behavior has been a valuable model system for behavioral neuroscientists studying the neural basis of motivated behaviors. One striking example of a change in motivation is the binary switch in sexual receptivity that occurs during the estrous cycle in female rats. Investigations of the neural basis of this change in behavior have fundamentally advanced our understanding of both behaviorally relevant neural pathways and basic mechanisms of steroid action in the brain. These advances have made this behavioral model system a staple of neuroendocrinology. A challenge that remains before us, given our current understanding of the circuitry and chemistry, is to develop a coherent model of how neural plasticity in the hypothalamus contributes to the dependence of this behavior on motivational state. This review will focus on the ventromedial nucleus of the hypothalamus, especially its ventrolateral subdivision. First, the anatomical, neurochemical, and functional aspects of the macro- and microcircuitry of this brain region will be discussed, followed by a discussion of the likely mechanisms of estrogen action within the ventrolateral VMH. Then, the evidence for estrogen-induced neural plasticity will be considered, including a comparison with the effects of estrogen on synaptic organization in other brain regions. Finally, a working model of neural plasticity within the ventrolateral VMH microcircuitry will be presented as a starting point for future experiments to verify or, more likely, revise and expand.

Differential regulation of AP-1 DNA binding activity in rat hypothalamus and pituitary by estrogen

Ap-1 proteins such as Fos and Jun are nuclear transcription factors that have been postulated to function as third messengers in signal transduction pathways to regulate target gene expression. Using electrophoretic mobility shift assays (EMSA), we have studied estrogen (E) effects on regulation of AP-1 DNA binding activity in the rat hypothalamus and pituitary. AP-1 binding is defined herein as the specific association with a consensus AP-1 site during EMSA. Specific AP-1 binding activity was observed in nuclear extracts from the hypothalamus and pituitary of ovariectomized (OVX) female and castrated (CAS) male rats. Treatment with E increased the levels of AP-1 binding activity in the pituitary and uterus, whereas E decreased the levels of AP-1 binding in the hypothalamus, of OVX females. These effects were observed within 60 min and maintained for at least 72 h after a single dose of estrogen. Estrogen-induced changes in AP-1 binding were much more prominent in OVX females than in CAS males. Treatment with progesterone in OVX females had no significant effects on AP-1 binding activity in either pituitary or hypothalamus. Analysis of AP-1 binding activity in both hypothalamus and pituitary by supershift, immunodepletion and shift-Western blot indicated that part of the AP-1 binding was due to the presence of Fos and Jun proteins. However, Western blot analysis shows that the levels of Fos and Jun proteins in the hypothalamic nuclear extracts were not altered by E treatment. We conclude that E produced tissue and sex-differentiated alterations in AP-1 DNA binding activity in the hypothalamus and pituitary of female rats, which may be related to differential estrogenic actions on gene regulation.

Anesthesia during hormone administration abolishes the estrogen induction of preproenkephalin mRNA in ventromedial hypothalamus of female rats

Estrogen treatment increases preproenkephalin (PPE) mRNA levels in the ventromedial nucleus of the hypothalamus (VMH). Roy et al. (Brain Res., 337 (1985) 163-166) discovered that anesthesia during estrogen priming could reduce female rat sexual receptivity. In the present study we tested whether the action of estrogen to induce PPE gene expression in the VMH could be similarly affected by anesthesia. By quantitative in situ hybridization and slot-blot analysis techniques we found a 1.8-fold increase in PPE mRNA levels in the VMH after 1 hour of estrogen treatment in ovariectomized (OVX) Sprague-Dawley female rats. Anesthetizing the rats with pentobarbital for 1 h during the exposure to estrogen blocked the estrogen induction of PPE mRNA in the VMH. By way of contrast no changes in the PPE mRNA levels were observed in the caudate putamen. A similar trend was seen using chloral hydrate. It appears that neuronal activity is required for the early phase of estrogen induction of PPE mRNA levels in the VMH. This in turn could be correlated with changes in female sociosexual behaviors.

Effects of non-competitive NMDA receptor antagonists on reproductive and motor behaviors in female rats

MK-801 and dextrorphan, selective non-competitive antagonists at N-methyl-D-aspartate (NMDA) receptors, were used to evaluate the effect of NMDA receptor blockade on sexual and motor behaviors in female rats. Ovariectomized rats were treated with estradiol benzoate (EB) for 48 or 72 h followed by progesterone (P) 3.5-4 h before testing the animals for sexual receptivity. After testing for estrous responsiveness, the effect of NMDA antagonists on several motor behaviors was also assessed. Lordosis frequency and intensity were inhibited in animals that received 0.5 mg/kg MK-801 30 min before EB; the same dose of MK-801 was relatively ineffective when administered 24 h after EB. In neither case did MK-801-treated females differ from controls when motor behaviors were assessed after mating tests. When 30 mg/kg dextrorphan, a short-acting NMDA antagonist, was administered 15 min before P, sexual behavior was not blocked. However, both 0.05 mg/kg MK-801 and 30 mg/kg dextrorphan suppressed ongoing female sexual behavior within 30 min in animals made receptive with EB and P. These deficits in sexual behavior were associated with changes in motor performance. MK-801 (0.1 mg/kg) and dextrorphan (30 mg/kg) abolished movement in the vertical dimension (e.g. jumping and rearing). By contrast, the drugs increased movement in the longitudinal (locomotion) and lateral (circling) dimensions. At 0.2 mg/kg, MK-801 blocked movement in both the vertical and longitudinal dimensions; however, it failed to block circling. Only at 0.4 mg/kg did MK-801 inhibit lateral movements and righting reflexes.(ABSTRACT TRUNCATED AT 250 WORDS)

Different roles of alpha-noradrenergic receptor subtypes in regulating lordosis

Ovariectomized guinea pigs were given free estradiol (E) at hr 0 and 28, and progesterone (P) at hr 39. Experiment 1: The alpha-1 noradrenergic antagonist prazosin, but not the alpha-2 noradrenergic antagonist idazoxan, prevented display of lordosis behavior when administered systemically 30 min prior to E injections at either hr 0 or 28, or 30 min prior to both injections. Experiment 2: Multiple injections of idazoxan (i.e., 30 min prior to and 60 and 120 min after each E injection) failed to prevent display of lordosis. Experiment 3: E-primed animals were given a single injection of idazoxan 1 hr before P, or 5 hr after P. In those animals given idazoxan 1 hr before P, display of lordosis was not prevented. However, in animals given idazoxan once lordosis display had begun (i.e., 5 hr after P) ongoing lordosis behavior was blocked. These data suggest differential roles of alpha-noradrenergic receptor subtypes in regulation of lordosis: noradrenergic transmission through the alpha-1 subtype may mediate hormone-priming processes leading to lordosis, whereas transmission through the alpha-2 subtype may modulate ongoing lordosis responses.

Effect of 5 alpha-dihydrotestosterone and flutamide on the facilitation of lordosis by LHRH and naloxone in estrogen-primed female rats

Although 5 alpha-dihydrotestosterone (DHT) is a potent inhibitor of lordosis behavior in ovariectomized estrogen-primed female rats, the mechanism(s) by which this steroid has this action is unknown. The present experiments sought to determine whether DHT inhibits lordosis by preventing the known facilitatory actions of luteinizing hormone-releasing hormone (LHRH), naloxone, and Substance P on lordosis. Lordosis behavior was examined in ovariectomized, estrogen-primed rats prior to or 30, 60, 90, and 180 min following intracerebroventricular (ICV) infusion of LHRH (500 ng), naloxone (1 microgram). Substance P (1 microgram), or saline and 0.01 N acetic saline vehicles, and the effects of DHT (2.5 mg/rat) following similar treatment were examined. In Experiment 1, LHRH and naloxone increased lordosis within 30 min after infusion, while Substance P and the saline or acetic saline vehicles had no effect. Treatment with DHT in combination with estrogen prevented the facilitation of lordosis by LHRH and naloxone. In Experiment 2, ovariectomized, estrogen-primed females shown to be responsive to LHRH during a first screening test were tested for lordosis after receiving either DHT or DHT in combination with the androgen receptor antagonist, Flutamide (7.5 mg/injection x 3). Again, DHT prevented the facilitatory action of LHRH; however, Flutamide did not counteract that effect. In Experiment 3, Flutamide did not counteract the inhibitory effect of DHT on estrogen and progesterone-induced lordosis. These results demonstrate that the inhibitory effect of DHT cannot be overridden by neuroactive peptides which themselves stimulate receptivity. It seems unlikely that DHT inhibits lordosis either by interfering with the behavioral action of these peptides or by activation of the androgen receptor.

Males increase progestin receptor binding in brain of female voles

In female prairie voles, behavioral estrus is induced by exposure to an unfamiliar male and ovulation is induced by mating. Experiments were conducted to determine whether a saturable high-affinity progestin binding site (PRC) is present in cytosols of brain tissue from females exposed to male stimuli for a period of time which is sufficient to bring most females into heat. PRC were detected in both the medialbasal hypothalamus (MBH) and preoptic area (POA). However, PRC levels increased in response to male stimuli in the MBH but not in the POA. The lack of an increase in the POA could not be attributed to changes in circulating progesterone. These results indicate that social stimuli can influence cellular events within specific areas of the female brain and suggest that one distinguishing feature between the spontaneous and induced ovulators may be the pattern of estrogen-induced progestin receptors within areas of the brain which are involved with the control of sexual behavior and/or ovulation.

Mediation of norepinephrine-stimulated cyclic AMP accumulation by adrenergic receptors in hypothalamic and preoptic area slices: effects of estradiol

Adrenergic receptor agonists and antagonists were employed to establish (a) which receptor subtypes mediate the cyclic AMP response to norepinephrine in hypothalamic and preoptic area slices from gonadectomized female rats and (b) which receptor subtypes might be modulated by the steroid hormone estradiol. Slice cyclic AMP levels were elevated by the beta receptor agonist isoproterenol, but not by alpha 1 (phenylephrine, methoxamine) or alpha 2 (clonidine) agonists. However, the alpha agonist phenylephrine potentiated the effect of the beta agonist isoproterenol on slice cyclic AMP accumulation. In slices from rats given no hormone treatment, the beta antagonist propranolol inhibited norepinephrine-stimulated cyclic AMP production, while the alpha 1 antagonist prazosin was without effect. In contrast, the cyclic AMP response to norepinephrine in slices from estradiol-treated rats was blocked more effectively by prazosin than by propranolol. Estradiol treatment also attenuated the production of cyclic AMP by the beta agonist isoproterenol. The data suggest (a) that norepinephrine induction of cyclic AMP accumulation in hypothalamic and preoptic area slices is mediated by beta receptors and potentiated by alpha receptor activation and (b) that estradiol depresses beta and increases alpha 1 receptor function in slices from brain regions associated with reproductive physiology.

Alpha 1-noradrenergic receptor blockade decreases nuclear estrogen receptor binding in guinea pig hypothalamus and preoptic area

Prazosin, a putative alpha 1-noradrenergic antagonist, reduced nuclear estrogen receptor levels in the hypothalamus and preoptic area of the estrogen-primed guinea pig. Noradrenergic transmission may alter steroid-dependent processes and neuroendocrine function through actions on steroid-concentrating cells.