Inhibition of estrogen facilitation of sexual behavior by the intracerebral infusion of actinomycin-D

It has been shown previously that intracerebral actinomycin-D (Act-D) pellets inhibit estrogen facilitated female sexual behavior, but it was not possible to test the reversibility of this effect. In the present study an attempt was made to distinguish between the possible temporary interruption by Act-D of the biochemical action of estrogen which facilitates sexual receptivity and permanent toxic effects of the drug. Act-D in saline was infused into the third ventricle or the preoptic area (POA) to determine whether a reversible suppression of sexual behavior as measured by the lordosis quotient (LQ) could be produced. Ovariectomized rats were implanted with midline guide tubes entering the third ventricle (eight rats) or with bilateral tubes extending to the corpus callosum above the POA (67 rats). Each animal served as its own control since pretest and Act-D and recovery tests were performed 10–14 days apart in most subjects. For each behavioral test implanted subjects were primed with 3μg estradiol benzoate (EB) and 0.5 mg progesterone (P) 48 hr later. Behavioral tests, each involving 50 mounts, were performed 4–6 hr after P. Following the pretest the animals were retested under experimental conditions. Inner cannulae were inserted into the POA through the guide tubes and 0.11 μg Act-D infused 24 or 12 hr before, simultaneously with, or 6, 12, 18, or 26 hr after EB. A recovery test was performed 10–14 days later with no intracerebral infusion. The control procedure (infusion of of saline either simultaneously with or 12 hr after EB) did not alter the LQ. Act-D infusion produced a reversible suppression of lordosis which was dependent upon the time of administration of Act-D. Intraventricular infusion of Act-D 6 hr after EB reversibly inhibited lordosis behavior and no lesions were produced. Act-D infused into the POA simultaneously with EB or 6 hr later reversibly suppressed the LQ. In the 6 hr group, for example, the LQ fell from 78.3 to 35.7, but 10–14 days later reached 74.3. Although brain lesions of varying extent were produced by Act-D, the marked but reversible suppression of lordosis behavior is consistent with the view that Act-D inhibits estrogen facilitation of lordosis behavior by means of a biochemical rather than cytotoxic action.     

The inhibition of steroid-induced sexual behavior by intrahypothalamic actinomycin-D

Lordosis behavior can be elicited in the ovariectomized rat after treatment with estradiol benzoate (EB) and progesterone (P) injections, but the EB must act for an extended period before P can facilitate this behavior. The possibility that this action of EB involves the stimulation of RNA or protein synthesis was tested by implanting actinomycin D (Act-D) directly into the preoptic area, one probable site of estrogen action. A total dose of 0.18 μg Act-D in bilateral cocoa butter pellets significantly inhibited lordosis behavior when implanted 12 hr after the injection of 3 μg. but not 15 μg EB. Implantation of this dose of Act-D subcutaneously, or intrahypothalamically 32 hr after EB injection, was without effect. Act-D placed in the ventromedial hypothalamus also suppressed lordosis, but implants in the caudate nucleus were without effect. At the time of the behavioral tests the animals were in excellent condition as determined by calculation of a health score, and no physical lesions were evident at the site of the implants. However, it was impossible to test the reversibility of this suppression of lordosis behavior since the animals became ill and many died within 1–2 weeks of implantation. The present results are consistent with, but not proof of, the concept that RNA synthesis may be essential for steroidinduced sexual behavior.     

Specificity and neural sites of action of anisomycin in the reduction or facilitation of female sexual behavior in rats

These experiments were designed to investigate the role of neuronal protein synthesis in the hormonal activation of female sexual behavior using intracranial implants of the protein synthesis inhibitor, anisomycin. In the first experiment, female rats receiving bilateral cannulae implants in the medial preoptic area (POA), septal region (SEPT), ventromedial hypothalamus (VMH), or midbrain central gray (CG) were injected with 2.5 micrograms estradiol benzoate (EB), followed 48 hr later by 500 micrograms progesterone (P). Females receiving anisomycin in the VMH at the time of EB injection had lower levels of lordosis and darting compared to tests without anisomycin. Sexual behavior was unaffected in females receiving anisomycin implants in the POA, SEPT, or CG. In a second experiment, we replicated the finding that anisomycin could attenuate lordotic responsivity when placed in the VMH of female rats injected with 2.5 micrograms EB and 500 micrograms P. In addition, we found that POA implants of anisomycin could facilitate lordosis in females given a low dose of EB (1.25 microgram) plus 500 micrograms P. In a third experiment, we assessed the effects of anisomycin application to the VMH or POA of female rats receiving estradiol (E; diluted 1:250 with cholesterol) implants in the VMH and systemic P. Treatment of the VMH with anisomycin prior to E in the VMH suppressed lordotic responding, whereas anisomycin application to the POA prior to E in the VMH had no effect on lordosis. The results of these experiments suggest that reducing protein synthesis in the region of the VMH disrupts the action of estrogen on the VMH, and that the facilitative action of anisomycin in the POA of female rats requires more estrogen treatment than threshold stimulation of the VMH alone.     

Facilitation of receptive behavior in estrogen-primed female rats by the anti-progestin, RU 486

The progestin receptor antagonist RU 38486 (henceforth referred to as RU 486) was tested for facilitative effects on female receptive behavior in ovariectomized Long-Evans rats primed with 2 micrograms estradiol benzoate (EB). RU 486 (0, 0.5, 1.6, or 5.0 mg) was administered 48 hr after estrogen priming. The lordosis quotient (LQ) and lordosis score (LS) were assessed 4 hr after RU 486 administration in a standardized test consisting of a 10-mount test by a stimulus male. A significant dose effect was found by both LQ and LS, with those subjects receiving 5 mg of RU 486 being significantly more receptive than vehicle control animals. Thus RU 486 acted as a weak progestin agonist under testing conditions typical for assessment of progestin facilitation of female sexual behavior in rats. Low levels of proceptive behavior (hops and darts) were seen in a minority of the tests, and did not vary systematically as a function of the dose of RU 486 administered. We also examined the effects of RU 486 given before progesterone (P) on receptivity in a blocking paradigm and confirmed previous reports that the antagonist significantly attenuates facilitation of sexual behavior when given in combination with P. A progestin receptor assay of the cytosols of the hypothalamus-preoptic area in estrogen-primed female rats treated with 5 mg RU 486 revealed a significantly greater depletion of available cytosolic P receptors than when rats were treated with a similarly facilitating dose of P (100 micrograms). The results suggest a possible dual mode of action for RU 486--a weak, receptor-mediated agonistic effect on sexual behavior when given alone to estrogen-primed rats, and a competitive blocking effect on receptivity when administered with P.     

Mu-, delta-, and kappa-opioid receptor agonists selectively modulate sexual behaviors in the female rat: differential dependence on progesterone.

Previous studies suggested that opioid receptor agonists infused into the lateral ventricles can inhibit (through mu receptors) or facilitate (through delta receptors) the lordosis behavior of ovariectomized (OVX) rats treated with estrogen and a low dose of progesterone. The present study investigated the behavioral and hormonal specificity of those effects using more selective opioid receptor agonists. Sexually experienced OVX rats were implanted stereotaxically with guide cannulae aimed at the right lateral ventricle. One group of rats was treated with estradiol benzoate (EB, 10 micrograms) 48 hr and progesterone (P, 250 micrograms) 4 hr before testing, whereas the other group was treated with EB alone. Rats were infused with different doses of the selective mu-receptor agonist DAMGO, the selective delta-receptor agonist DPDPE, or the selective kappa-receptor agonist U50-488. The females were placed with a sexually vigorous male in a bilevel chamber (Mendelson and Gorzalka, 1987) for three tests of sexual behavior, beginning 15, 30, and 60 min after each infusion. DAMGO reduced lordosis quotients and magnitudes significantly in rats treated with EB and P, but not in rats treated with EB alone. In contrast, DPDPE and U50-488H increased lordosis quotients and magnitudes significantly in both steroid-treatment groups. Surprisingly, measures of proceptivity, rejection responses, and level changes were not affected significantly by mu or kappa agonists, although proceptivity and rejection responses were affected by DPDPE treatment. These results suggest that the effects of lateral ventricular infusions of opioid receptor agonists on the sexual behavior of female rats are relatively specific to lordosis behavior. Moreover, the facilitation of lordosis behavior by delta- or kappa-receptor agonists is independent of progesterone treatment, whereas the inhibitory effect of mu-receptor agonists on lordosis behavior may require the presence of progesterone.     

Homotypical sexual behavior in gonadectomized female and male rats treated with 5α-19-hydroxytestosterone: Comparison with related androgens

Ovariectomized female rats were treated in turn over several weeks with estradiol benzoate (EB), testosterone (T), 19-hydroxytestosterone (19HT), dihydrotestosterone (DHT) and 5α-19-hydroxytestosterone (5α19HT). EB was given as a single dose, the androgens were given over 3 days, and progesterone (P) was given 48 hr after the last injection. Each week, rats were tested for lordosis behavior 4–6 hr after P. High levels of receptivity were seen after EB + P, 19HT + P and T + P. Rats treated with DHT + P or 5α19HT + P were unreceptive. Four groups of castrated male rats were treated with T, 19HT, DHT and 5α19HT for 4 weeks starting from castration. In weekly sexual behavior tests, only T and 19HT maintained normal copulatory performance throughout the experiment. 19HT and 5α19HT had negligible effects on peripheral androgen target organs. The failure of 5α19HT to stimulate sexual behavior in rats of either sex supports the view that this steroid does not undergo central aromatization.     

Estrogen and progesterone interactions influencing sexual and social behavior in the brown lemming, Lemmus trimucronatus.

The effects of estrogen and progesterone on the social and sexual behavior of brown lemmings, Lemmus trimucronatus, were investigated. The behavior of hormone-treated and untreated ovariectomized females and sexually vigorous males was observed in six consecutive daily 5-min dyadic encounters. Sexual receptivity, as measured by lordosis, and other social behaviors including nasonasal contact, boxing postures, allogrooming, perineal investigation, and male mounting increased following 48 hr of exposure to daily injections of 0.5 μg estradiol benzoate (EB). Lordosis in EB-primed females was not facilitated or inhibited by short-term (4 hr) exposure to 0.5 mg progesterone (P). Long-term (greater than 24 hr) exposure to P apparently inhibited lordosis and other social behaviors in EB-treated females, although males continued to attempt to mount these females. In EB-treated females a dramatic increase in threat-leaps, directed by the female toward the male, was observed within 4 hr of P injection. Threat-leaps declined when P was withdrawn. Threat-leaps were also observed in ovariectomized females after prolonged exposure to P only (0.5 mg/day). Vaginal perforation and cornification were first apparent 48 hr after EB injection. P-alone treated ovariectomized females also showed vaginal perforation but cornified cells were infrequent and these animals did not show lordosis.     

Effects of the antiestrogens,MER-25 and CI 628, on rat and hamster lordosis

Antiestrogens were used to test the hypothesis that estrogen exerts a “maintenance,” as well as a “priming,” effect on rat and hamster sexual receptivity as it apparently does for guinea pigs. MER-25 (75 or 150 mg/kg) significantly reduced rat LQ when given ?2 hr or 8 hr after EB injection. MER-25 given at 34 hr (2 hr prior to P) failed to diminish rat LQ. With hamsters, MER-25 in large doses (750 mg/kg) given either at ?2 hr or 34 hr reduced lordosis duration to 40% of controls, but this effect was confounded by severe illness among the MER-25 injected animals. Lower doses failed to block behavior, but still produced some toxicity. CI 628 (50 mg/kg) greatly reduced hamster lordosis duration and increased lordosis latency when given 0 hr, but not 34 hr, after EB. The results are consistent with similar previous work on rats and do not support the concept of estrogen “maintenance” in either rats or hamsters.     

Hysterectomy-induced facilitation of lordosis behavior in the rat

The present study investigated the effect of hysterectomy on hormone-induced lordosis behavior. Lordosis quotients (LQ) were measured in hysterectomized-ovariectomized (HO) and ovariectomized-sham hysterectomized (OSH) rats after several treatments including either estradiol benzoate (EB) alone or EB plus progesterone (P) 44 hr later. Testing consisted of placing the females with sexually active males 48 hr after EB. In Experiment 1, HO animals treated with 5 μg/kg EB and 0.5 mg P had significantly higher LQs than OSH animals; groups treated with 10 μg/kg plus P were not different. Experiment 2 showed that a single injection of 50 μg/kg EB resulted in equally high levels of receptivity in both groups. The LQs of HO animals injected with 3 μg/kg for 4 days did not differ from those of OSH animals; however, the administration of 0.5 mg P 24 hr after the fourth EB injection resulted in significantly higher LQs in the HO group (Experiment 3). In Experiment 4, HO rats injected with 5 μg/kg EB and 0.1 mg P 44 hr later displayed higher levels of lordosis behavior than OSH animals. It was concluded that hysterectomy facilitated the lordosis behavior of ovariectomized rats injected with both EB and P and that the mechanism for this potentiation remains to be determined.     

Neuronal responsiveness to gonadotropin-releasing hormone and its correlation with sexual receptivity in the rat

In the present study, an attempt was made to correlate the neuronal responsiveness of individual preoptic-septal (POA/S) units to iontophoretically applied GnRH with the onset of sexual receptivity. In both behavioral and electrophysiological studies, ovariectomized, estrogen-primed rats were used. In behaviorally tested rats, lordosis quotients (LQ) were determined at varying times following progesterone (P) injection. For electrophysiological studies, P was given 1 hr after the start of recording. GnRH was iontophoretically applied for 30 sec at 16 nA on spontaneously discharging cells. A unit was deemed excited or inhibited if a repeatable 30% change in discharge rate was observed. From 2-10 hours as the LQ increased from 17 to 90 the total number of GnRH sensitive cells did also. The majority of responsive cells were excited by the peptide. As receptivity displayed a sharp increase from 2 to 6 hours the mean responsiveness of cells excited by GnRH was significantly elevated over inhibitory responses. These findings confirm the E/P biasing effect on POA/S unit responses to GnRH. Moreover, they suggest that a dynamic relationship exists between GnRH responses at the cellular level and sexual behavior throughout the course of steroid-induced receptivity.     

Protein synthesis in the medial preoptic area is important for the mating-induced decrease in estrus duration in hamsters

Sexual receptivity in female hamsters potentially lasts for about 16 h. However, vaginal cervical stimulation (VCS) from a male during mating eventually reduces receptivity and can shorten the duration of behavioral estrus. The process by which this change in response to the male takes place is unknown. Recently, detection of the Fos protein has indicated that the medial preoptic area (POA) is one of the brain regions particularly responsive to VCS. Additionally, the POA may have an inhibitory effect on sexual receptivity. To determine if protein synthesis in the POA is required to initiate the VCS-induced decrease in estrus duration, a protein synthesis inhibitor (anisomycin, 0.50 microg) or a control substance (cholesterol) was applied bilaterally to the POA of steroid-primed ovariectomized female hamsters. Females were tested with a sexually active male at five time points following the initial test for sexual receptivity (hour 1, 2, 6, 12, and 24). Half of the females tested were allowed to receive VCS from a male, while half were fitted with vaginal masks to prevent penile intromission. Each group receiving VCS showed a significant decrease in lordosis duration evident between hour 2 and hour 6, except the group which received anisomycin in the POA. In this respect the POA anisomycin group was similar to animals which did not receive VCS. Hamsters with vaginal masks and the anisomycin/POA animals allowed to receive VCS exhibited their first decrease in lordosis duration between hour 6 and hour 12. These results indicate that protein synthesis is important for VCS-induced decrease in estrus duration in the POA.     

Regulation of estrogen-stimulated lordosis behavior and hypothalamic progestin receptor induction by antiestrogens in female rats

Two estrogen antagonists, CI-628 (CI) and tamoxifen (TX), were used to examine the relationship between estrogen priming of lordosis behavior and progestin receptor induction in the hypothalamus-preoptic area (HPOA) of ovariectomized female rats. Lordosis behavior was assessed by measuring lordosis quotients (LQ) in response to injection of 2 micrograms of estradiol benzoate (EB) followed 48 hr later by 500 micrograms of progesterone (P). Behavior testing began 4 hr after P injection. The effects of antiestrogens were assessed by injecting CI and TX (1-2 mg) from 0 to 48 hr prior to EB. Levels of cytosol progestin receptor in the HPOA were determined by quantifying the specific binding of 0.5 nM [3H]R5020 to cytosols from animals receiving the same EB and antiestrogen treatments used in behavioral testing. TX given concurrently with or CI given 2 hr before EB abolished both lordosis behavior and induction of HPOA progestin receptors. In contrast, CI given 12 hr prior to EB abolished lordosis but permitted a 95% elevation in the concentration of progestin binding sites in the HPOA. TX or CI given 48 hr before EB resulted in moderate levels of lordosis (mean LQs from 56 to 69) and induction of HPOA progestin receptors from 85 to 130% above noninjected controls. However, CI given 24 hr prior to EB produced less than a 40% increase in brain R5020 binding even though lordosis behavior was equivalent to that seen in the 48-hr animals (mean LQ = 53). These data indicate that the effects of antiestrogens on female sexual behavior and on the synthesis of brain progestin receptors depend on which antiestrogen is used and the time interval between administration of estrogen and antiestrogen. They also demonstrate that under some conditions estrogen induction of cytosol progestin receptors in the HPOA can be dissociated from estrogen priming of lordosis behavior in rats.     

Modulation of the arcuate nucleus–medial preoptic nucleus lordosis regulating circuit: A role for GABAB receptors

Estradiol rapidly activates a microcircuit in the arcuate nucleus of the hypothalamus (ARH) that is needed for maximal female sexual receptivity. Membrane estrogen receptor-α complexes with and signals through the metabotropic glutamate receptor-1a stimulating NPY release within the ARH activating proopiomelanocortin (POMC) neurons. These POMC neurons project to the medial preoptic nucleus (MPN) and release β-endorphin. Estradiol treatment induces activation/internalization of MPN μ-opioid receptors (MOR) to inhibit lordosis. Estradiol membrane action modulates ARH gamma-aminobutyric acid receptor-B (GABA_B) activity. We tested the hypothesis that ARH GABA_B receptors mediate estradiol-induced MOR activation and facilitation of sexual receptivity. Double-label immunohistochemistry revealed expression of GABA_B receptors in NPY, ERα and POMC expressing ARH neurons. Approximately 70% of POMC neurons expressed GABA_B receptors. Because estradiol initially activates an inhibitory circuit and maintains activation of this circuit, the effects of blocking GABA_B receptors were evaluated before estradiol benzoate (EB) treatment and after at the time of lordosis testing. Bilateral infusions of the GABA_B receptor antagonist, CGP52432, into the ARH prior to EB treatment of ovariectomized rats prevented estradiol-induced activation/internalization of MPN MOR, and the rats remained unreceptive. However, in EB-treated rats, bilateral CGP52432 infusions 30 min before behavior testing attenuated MOR internalization and facilitated lordosis. These results indicated that GABA_B receptors were located within the lordosis-regulating ARH microcircuit and are necessary for activation and maintenance of the estradiol inhibition of lordosis behavior. Although GABA_B receptors positively influence estradiol signaling, they negatively regulate lordosis behavior since GABA_B activity maintains the estradiol-induced inhibition.     

Effects of progesterone implants in the habenula and midbrain on proceptive and receptive behavior in the female rat

Two brain areas behaviorally responsive to progesterone (P) were examined to determine their possible involvement in the control of rat preceptive behavior, i.e., solicitation behavior directed at the male. Progesterone implants were placed in the habenular nuclei and the interpeduncular nucleus-ventral tegmental area of the midbrain reticular formation (MRF). Different testing procedures and levels of priming with estradiol benzoate (EB) were used in order to distinguish the effects of P in either region on proceptive and receptive behavior during exposure to 10 mounts by stimulus males. To test for receptivity, sexually experienced 60-day-old ovariectomized (ovx) rats bearing stereotaxically placed guide cannulas extending to the habenula or MRF were given 10 μg EB subcutaneously. Forty-eight hours later, lordosis quotient (LQ) was determined. Immediately following this test, each animal was implanted with cholesterol (C) or P and was retested 2 hr later. Treatments for the proceptivity test were similar except that the animals received 2.5 μg EB/100 g body wt sc for 7 days before testing on the eighth day; LQ as well as hopping, darting, and ear wiggling were scored. In the receptivity test, P implantation in both the medial portions of the habenula and the MRF significantly increased lordosis above the levels found both in their preimplantation tests and following control implantation of C. Little proceptivity was observed. In the proceptivity test, P implants in both regions also significantly increased proceptive behavior above both types of control tests. All animals were highly receptive, and there was no difference in LQ among the groups. There was no increase of plasma P levels in similarly implanted animals during a 24-hr monitoring period, indicating that systemic leakage of the hormone was not responsible for the observed behavior. The data indicate that both the habenula and MRF are P-sensitive regions. Progesterone's action on the two areas facilitates expression of both proceptive and receptive components of female sexual behavior, indicating that the neural regulation of the two kinds of behavior is integrated at these levels.     

Suppression of lordosis in guinea pigs by ethamoxy-triphetol (MER-25) given at long intervals (34-46 hr) after estradiol benzoate treatment

Ovariectomized guinea pigs were given estradiol benzoate (EB) followed 40 hr later by progesterone (P). Behavioral testing commenced 1 hr after P injection and continued at hourly intervals for 8 hr. This treatment activated lordosis in almost 100% of animals. Administration of the antiestrogen MER-25 (75 mg/kg body wt per injection) between 2 hr before and 6 hr after EB treatment did not cause a significant decline in proportion of animals displaying lordosis, but did cause a decrease in length of time the lordosis position was held (maximum lordosis, sec). In contrast, $\text{13}\text{14}$ animals given MER-25 at 2 hr before and 2 hr after P and $\text{8}\text{10}$ animals given MER-25 simultaneously with and 2 hr after P, failed to show lordosis. Administration of supplementary EB at around the time of P injection, partially alleviated these behavior-blocking effects of MER-25. When MER-25 was given 2–6 hr after administration of P there was a significant decrease in duration of heat (hr). These results suggest that in addition to its early “triggering” effects, estrogen has important “maintenance” effects which determine the character of heat in guinea pigs. Continued presence of estrogen in the nervous system may be a requirement for the facilitatory actions of P on sexual behavior in guinea pigs, but such a requirement may not exist in other rodents such as rats.     

Comparison of some CNS effects of luteinizing hormone-releasing hormone and progesterone

Luteinizing hormone-releasing hormone (LHRH) has been reported to facilitate lordotic behavior in estrogen-primed ovariectomized (OVX) female rats in a manner similar to progesterone (P). This study compared P and LHRH with respect to their behavioral effects and site of action within the brain. The hormones were compared using two different components of sexual behavior, receptivity and proceptivity. To test for receptivity, OVX females were given behaviorally ineffective estradiol benzoate (EB) injections sc 48 hr before testing. They were then treated with either P, LHRH, or vehicle by various routes. Two and/or four hours later, receptivity (LQ) was measured. Treatments for the proceptivity test were similar except that a larger EP-priming dose, which facilitates preceptive behavior, was used. Four hours later, LQ and hopping, darting, and earwiggling were scored. In the receptivity test, sc administration of 1 mg P or 1 μg LHRH (but not 0.5 or 5.0 μg) significantly elevated LQ with respect to vehicle injection 4 hr after treatment. In the proceptivity test, 0.5, 1.0, and 5.0 μg of LHRH given sc failed to alter significantly either LQ or soliciting behavior. Progesterone facilitated both parameters. Implantation of crystalline P into the midbrain reticular formation (MRF) has been shown to elicit both the receptive and preceptive effects of the steroid. Microinjection of as much as 100 ng of LHRH in 1.0 μl saline into the same region failed to enhance lordotic behavior compared to saline injection alone, while a 200-ng intracerebroventricular dose significantly facilitated lordosis at 4 hr. The data indicate that LHRH does not induce proceptive behavior. The effects of peripherally administered LHRH on receptive behavior are similar but less pronounced than those of P. The two hormones elicit this effect from different sites in the brain.     

A possible involvement of adrenaline in the facilitation of lordosis behavior in the ovariectomized rat

In order to examine a possible role of adrenaline (AD) or noradrenaline (NA) in the control of lordosis behavior, lordosis quotient (LQ) was observed daily for 8 consecutive days in the ovariectomized rat given daily 1 or 2 microgram/0.1 ml oil of estradiol benzoate (EB) alone or together with 100 microgram/0.1 ml saline of AD or NA. AD but not NA treated together with EB caused a greater change in the daily LQ than the same dose of EB alone and the change in the daily LQ by daily treatment with both 1 microgram EB and 100 microgram AD was equivalent to that by daily treatment with 2 microgram EB alone. A half mg progesterone (P) could induce the lordosis behavior in the ovariectomized rat treated 48 hr prior with both 1 microgram EB and 50 or 100 microgram AD, but not in the one treated with 1 microgram EB alone. While 50, 100 or 200 microgram NA or 10 microgram AD had no effect, 50 or 100 microgram AD pretreated together with 2 microgram EB produced a markedly higher LQ after P than 2 microgram EB alone in the ovariectomized rat. This effect of AD on the induction of lordosis behavior was produced only when AD was pretreated simultaneously with EB and AD priming 24 or 43 hr after EB failed to elicit the effect. Therefore, it is suggested that a change of the brain target site in the estrogen sensitivity produced by AD plays a part in the control of lordosis behavior.     

Facilitation of Sexual Receptivity by Ventromedial Hypothalamic Implants of the Antiprogestin RU 486

RU 486 is known primarily as an antagonist to progestins and glucocorticoids. However, RU 486 has also been shown to have agonistic progestational properties in biochemical and behavioral studies. In the current study, RU 486 was implanted directly into tim ventromedial hypothalamus (VMH) to test for facilitative action on the receptive behavior of female ovariectomized Long-Evans rats primed with 5 μg of estradiol benzoate. Cannulae containing RU 486, progesterone (P), or empty cannulae were implanted 48 hr after estrogen priming. The lordosis quotient and the lordosis score were assessed 4 hr after the cannulae were lowered by a standardized test consisting of 10 mounts by a stimulus male. P and RU 486 significantly facilitated receptivity compared to blank implants in terms of lordosis quotient and lordosis score, with no significant difference between the hormone treatments. While only a single dose of each treatment was given in the current study, RU 486 facilitated lordosis when implanted to the VMH as well as progesterone in contrast to our previous results where the steroids were administered systemically.     

Role of hypothalamic serotonergic receptors in the control of lordosis behavior in the female rat

The role of serotonin in mediating hypothalamic control of sexual behavior in estrone-primed ovariectomized (OVX) rats was studied by comparing the lordotic patterns following medial preoptic (MPOA) and arcuate-ventromedial (ARC-VM) infusions of serotonin (5-HT), methysergide (MS), and vehicle. In the initial experiments, low receptivity (preinfusion receptivity: mean lordosis/mount ratio = 0.164) was maintained by priming each animal with a low dose of estrone 48 hr prior to mating. The infusion of MS in either the MPOA or ARC-VM area resulted in a significant enhancement of lordotic behavior from initial low receptivity, 5-HT infusions were found to have no statistically significant effect upon lordotic behavior. In order to corroborate the findings observed in the low preinfusion receptivity protocol, OVX rats were primed with higher doses of estrone to maintain a high level of receptivity (preinfusion receptivity: mean lordosis/mount ratio = 0.787). Using this protocol, significant depressions in lordotic behavior were observed following MPOA or ARC-VM infusions of 5-HT, It was thus proposed that serotonergic receptors within the MPOA or ARC-VM areas have inhibitory effects upon lordotic behavior. In addition to the effects of 5-HT upon estrogen-induced sexual receptivity, serotonergic influences upon luteinizing hormone-releasing hormone (LRH)-facilitated mating behavior were also evaluated. Comparisons were made between the lordotic responses following MPOA or ARC-VM infusions of vehicle, LRH, or LRH with 5-HT in OVX rats primed with low doses of estrone. The infusion of LRH into the MPOA or ARC-VM significantly enhanced lordotic behavior above vehicle levels. However, the addition of 5-HT to the LRH infusate abolished this behavioral enhancement. These findings indicated that LRH and 5-HT have opposing effects within forebrain areas known to be important for the control of lordotic behavior.     

Female lordosis pattern in the male rat induced by estrogen and progesterone: effect of interruption of the dorsal inputs to the preoptic area and hypothalamus.

Lordosis behavior was very rare in castrated male rats which had been pretreated with 50 mug estradiol benzoate (EB) for successive 2 days and 1 mg progesterone (P) 6-8 hr prior to testing on the third day. Only one out of 8 rats displayed lordosis in response to mounts by the sexually matured males. However, the occurrence of lordosis behavior was markedly increased in similarly treated castrated males in which the dorsal afferents to the preoptic area (POA) and hypothalamus were removed by the surgical cut. Twelve out of 19 rats of the group showed lordosis response. The incidence was less frequent in rats receiving sham deafferentation. These results suggest that the dorsal inputs to the POA and hypothalamus may exert a tonic inhibitory influence on the lordosis mediating system in the male rat.