Facilitation of female sexual behavior in male rats by septal lesions: an interaction with estrogen.

Although destruction of the septal region markedly facilitates the lordosis behavior of female rats in response to estrogen priming, comparable lesions were found to be ineffective in facilitating the lordotic behavior of estrogen primed male rats. Neither the age at the time of septal destruction nor castration influenced the lordosis behavior of males. However, if prepubertal castrated males were given subcutaneous ovarian grafts or injected daily with 2 μgm estradiol benzoate (EB) during the 30 day period following septal destruction, a prolonged facilitation of the activational effects of EB on lordosis behavior was observed. Male rats subjected to septal destruction alone, chronic exposure to EB alone, exposure to ovarian grafts for 30 days prior to septal destruction, or chronic treatment with EB started 6 mo after septal lesioning, failed to show an increase in behavioral responsiveness to estrogen. Thus, in order for septal lesions to facilitate lordosis behavior of male rats, exposure to EB or ovarian tissue must occur within an apparent critical period following septal destruction. Adult male rats were found to be more responsive to this interaction of septal lesions and EB exposure than pubertal animals. It is suggested that the prolonged facilitation of lordosis behavior which follows septal destruction and estrogen exposure in the male rat may be due to hormonal modifications of the recovery process following brain damage.     

Effects of septal lesions on behavioral sensitivity of female rats to gonadal hormones

Spayed female rats were given bilateral septal lesions or a sham operation and 3 wk later tested for hormone-induced female sexual behavior. When primed with 0.5, 1.0, or 2.0 μg of estradiol benzoate (EB) per day for 3 days and tested for lordosis behavior on the fourth day, animals with septal lesions showed a positive dose-related increase in mean lordosis quotient (LQ), whereas control animals showed a low mean LQ for all doses of EB. After priming with a low dose of EB (0.5 μg/day for 3 days), progesterone administration prior to behavior testing on day 4 produced a comparable facilitation in LQ for both septal-lesioned and sham-operated animals. When treated for 3 days with either 50 or 150 μg of testosterone propionate (TP) and given progesterone prior to behavior testing on day 4, female rats with septal lesions showed a higher mean LQ than sham-operated rats. Thus, septal lesions increase the behavioral sensitivity of female rats to both EB and TP as measured by female sexual behavior, but do not appear to alter the responsiveness of animals to progesterone.     

Effects of neonatal septal lesions on reproductive behavior of male and female rats

The purpose of this study was to examine the effects of neonatally placed septal lesions (SL) in male, female, and androgenized female rats on reproductive behavior. Animals were castrated as adults and tested for both feminine and masculine sexual behavior. After treatment with estradiol benzoate (EB) alone (2 μg daily for 3 days), only the females with SL which had not been given testosterone propionate (TP) neonatally showed a facilitation of lordosis behavior. Following EB (2 μg for 3 days) plus 0.5 mg progesterone (P), both the lesioned and the sham-operated female groups showed an increase in the display of lordosis in either hormonal condition. All animals were given a pretest for masculine sexual behavior and tested on Days 4, 7, 11, and 15 of daily TP treatment (150 μg/day). There was no effect of the neonatally placed SL on masculine sexual behavior in female rats or in female rats androgenized with 30 μg TP. However, lesioned females treated neonatally with 1 mg TP showed a marginal enhancement of masculine sexual behavior. Male rats given SL neonatally showed a marked enhancement of masculine sexual behavior compared to that of controls. These results suggest that, depending on the neonatal hormone environment, SL selectively increase behavioral sensitivity to hormones. Although neonatally lesioned females show behavioral responses similar to females given SL as adults, male rats given SL neonatally are unique in that they show enhanced masculine sexual behavior whereas males lesioned as adults do not.     

Role of postnatal androgens in sexual differentiation of the lordosis-inhibiting effect of central injections of cholecystokinin

The neuropeptide cholecystokinin (CCK) inhibits lordosis behavior when infused into the ventromedial nucleus of the hypothalamus (VMN) of female rats and has no effect when infused into the VMN of male rats. To test whether this sex difference develops under the control of perinatal steroids, male rats were castrated or given sham surgeries within 3 h of birth and female rats were injected with either 0 or 100 micrograms testosterone propionate on postnatal day 5. As adults, these rats were castrated as necessary, implanted with unilateral cannulae directed at the VMN, and tested for their ability to display female sexual behavior and to respond to CCK. Neonatal castration of males prevented defeminization of this response. When treated with 5 micrograms estradiol benzoate (EB), neonatally castrated males showed both lordosis behavior and a profound inhibition of that behavior after infusions of CCK. Neonatally castrated males did not display lordosis behavior when treated with 2 micrograms EB. Control males showed no lordosis behavior and, therefore, no response to CCK. Both doses of EB induced lordosis behavior in neonatally androgenized females. Significantly, these neonatally androgenized females were less responsive to CCK's inhibition of lordosis and were also anovulatory. These results imply that androgens alter the development of CCK responsive circuits as well as defeminize cyclic gonadotropin release. Levels of 125I-sCCK-8 binding in the VMN were correlated closely with an individual's ability to respond to sCCK-8. In summary, the inhibition of female sexual behavior caused by exogenously administered CCK in normal adult female rats appears to be controlled at least partially by levels of CCK receptors in the VMN and to differentiate under the control of perinatally present testosterone.     

Role of septum and preoptic area in regulating masculine and feminine sexual behavior in male rats

The effects of septal or preoptic lesions on both masculine and feminine sexual behaviors were examined in castrated adult male rats. Three weeks after brain surgery, animals were implanted with Silastic tubes containing testosterone (T) and observations of masculine sexual behavior were carried out four times every 5 days. T tubes were removed immediately after the end of the masculine behavioral tests. Two weeks later, animals implanted with Silastic tubes containing estradiol-17 beta(E2) were subjected to three feminine sexual behavioral tests at 5-day intervals. The bilateral lateral septal lesion (LSL) and the medial preoptic lesion (MPOL) effectively suppressed the performance of mounts, intromissions, and ejaculations, whereas the medial septal lesion (MSL), the dorsolateral preoptic lesion (DPOL), and the sham operation did not show any significant suppression of these behaviors. In the feminine sexual behavioral tests, intact and sham-operated control males showed only a low lordotic activity. However, the performance of the lordosis reflex was markedly facilitated by LSL or DPOL, while the lordotic activity of MSL and MPOL males was not significantly different from that of control males. These results suggest that the lateral septum exerts not only a facilitatory influence on masculine sexual behavior but also an inhibitory influence on feminine sexual behavior in male rats. On the other hand, the medial preoptic area may play a critical role in regulating masculine sexual behavior in male rats.     

Intracranial dialysis and microinfusion studies suggest that morphine may act in the ventromedial hypothalamus to inhibit female rat sexual behavior.

The present investigation examined the neural sites and mechanisms of opiate inhibition of female sexual behavior. Systemic administration of morphine (10 mg/kg) significantly reduced ovarian steroid-induced estrous behavior in female rats. This behavioral inhibition was prevented when the opiate receptor antagonist naloxone (5 mg/kg) was administered 30 min prior to morphine. Bilateral infusion of morphine directly into the ventromedial hypothalamus (VMH) also inhibited hormone-dependent estrous behavior for at least 2 hr. Furthermore, naloxone infusion into the VMH 20 min before behavior testing reduced the inhibitory effects of systemically administered morphine on lordosis. These results suggest that morphine may inhibit female sexual behavior by acting directly on the VMH, the primary site at which ovarian steroids facilitate this behavior. In a separate experiment we used in vivo brain microdialysis to test the hypothesis that morphine inhibits lordosis by interfering with norepinephrine (NE) neurotransmission in the VMH. In control rats, the onset of mating was associated with increased NE release in the VMH. Morphine-treated animals displayed neither behavioral estrus nor elevated NE release from the VMH when tested with stimulus males. These data are consistent with the hypothesis that morphine suppresses NE release in the VMH. Nevertheless, mechanisms other than or in addition to attenuation of hypothalamic NE release may contribute to the inhibitory effects of morphine on lordosis.     

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.     

Activation and differentiation of sexual behavior and translocation of hypothalamic estrogen receptors in rats by 6α-fluorotestosterone

Androgens classified as nonaromatizable in placental assay systems typically do not mimic testosterone's effects on sexual behavior in rats. 6α-Fluorotestosterone is an exception. To pursue this challenge to the aromatization hypothesis, we compared several behavioral and neuroendocrine effects of 6α-fluorotestosterone propionate (6α-fluoro-TP) with those of testosterone propionate (TP). Even at a very low dose (6.25 μg/100 g/day), 6α-fluoro-TP maintained most aspects of male sexual behavior as well as TP. It was slightly less potent than TP for inhibiting gonadotropin secretion (testicular development) in prepubertal males. Given neonatally, these androgens were equally likely to induce anovulatory sterility. 6α-Fluoro-TP defeminized sexual development in females and neonatally castrated males half as effectively as TP based on lordosis:mount ratios following estrogen and progesterone therapy in adulthood. Neither androgen masculinized sexual behavior. The behavioral effects of 6α-fluoro-TP correspond to its ability to inhibit cell nuclear accumulation of 17β-[³H]estradiol in the hypothalamuspreoptic area. When injected on a schedule like that used to activate male sexual behavior, the two androgens reduced estrogen uptake equally. When injected into adult castrates on a schedule like that used to defeminize sexual development, 6α-fluoro-TP blocked estrogen uptake half as well as TP. 6α-Fluorotestosterone did not alter estrogen uptake when injected simultaneously with 17β-[³H]estradiol. These data suggest that 6α-fluorotestosterone activates male behavior and defeminizes development because it translocates estrogen receptors in the brain, probably via an aromatized metabolite. Hence androgen aromatizability in the placenta may not reflect neural metabolism and cannot predict the behavioral or neuroendocrine effects of androgens.     

Lordosis behavior in castrated male rats treated with estradiol benzoate or testosterone propionate in combination with an estrogen antagonist, MER-25, and in intact male rats

Lordosis behavior could be elicited by manual stimulation in castrated male rats after treatment with estradiol benzoate (15 μg for 10 days) or testosterone propionate (1 or 3 mg for 10 days). The effect was antagonized by treatment with the estrogen antagonist MER-25 (10mg for 10 days). Prolonged treatment with testosterone propionate (1 mg for 26 days) resulted in display of male (nine of ten rats) as well as female (seven of ten rats) sexual behavior. Eleven of 32 intact male rats (age 120 days) and 22 of 37 other intact males (age 75 days) displayed lordosis in response to manual stimulation without hormonal treatment. Seven intact males which showed lordosis without hormone treatment were injected with MER-25 (10 mg/day × 10 days) and lordosis was abolished in six cases. The results suggest that estrogen is involved in the regulation of lordosis behavior in TP-treated and intact male rats.     

A soy supplement and tamoxifen inhibit sexual behavior in female rats

In addition to displaying proceptive (hopping and darting) and receptive (lordosis) behaviors during a sexual encounter with a male, female rodents will regulate the timing of the encounter by engaging in a series of approaches and withdrawals from the male, a behavior termed paced mating behavior. Proceptive, receptive, and paced mating behaviors are all regulated by, and sensitive to, estrogen and progesterone, suggesting that compounds capable of disrupting these critical hormones may also perturb the display of female sexual behavior. The present experiments examined the impact of the selective estrogen receptor modulator (SERM) tamoxifen and a popular soy phytoestrogen dietary supplement on female sexual behavior in rats. Ovariectomized female rats were given either tamoxifen (TAMOX) by implant or the soy supplement through the diet then injected with estradiol benzoate (EB, 10 microg) or oil followed 48 h later with an injection of progesterone (P, 500 microg). Animals were then tested for sexual behavior 4 h after the P injection. Neither compound had any effect on sexual behavior when administered in conjunction with P alone; however, both significantly diminished receptive behavior, as measured by the lordosis quotient (LQ), in animals primed with both EB and P. Similarly, the hopping and darting rate was also significantly depressed in both the soy- and TAMOX-treated animals, compared to the EB- and P-treated controls, with the soy-treated animals showing significantly less proceptive behavior than the TAMOX-treated animals. Finally, soy but not TAMOX significantly attenuated paced mating behavior in animals compared to the EB- and P-treated controls. These results demonstrate that both the soy supplement and TAMOX act as estrogen antagonists on both proceptive and receptive behavior in female rats.     

Neonatal hormonal influences on the development of proceptive and receptive feminine sexual behavior in rats

The objective of this study was to examine the influence of androgen and of the inhibiting of aromatization of androgen to estrogen during the early neonatal period on the development of receptive (lordosis and acceptance of stimulus male mounting attempts) and proceptive (affiliation with and solicitation of stimulus males) feminine sexual behavior. Within 8 hr of birth, male rats were castrated or received subcutaneous implants of the aromatase inhibitor androst-1,4,6-triene-3, 17-dione (ATD) while females received injections of testosterone propionate (TP). At 90 days of age all treated animals and controls were tested for receptive and proceptive feminine sexual behavior. It was found that androgen present neonatally blocked proceptive as well as receptive behavior patterns in adult rats. The proceptive and receptive feminine sexual behavior patterns displayed by adult males deprived of the effects of androgen neonatally either by castration or by treatment with ATD were comparable to those of normal females.     

Effects of voluntary and forced exercise on lordosis behavior in female rats

We measured sexual behavior (lordosis) in ovariectomized, steroid-treated, exercising female rats. When estradiol-treated animals exercised voluntarily, lordosis was directly related to the amount of exercise. Forced exercise (swimming) following treatment with estradiol 17 beta and progesterone significantly increased lordosis scores but only after animals swam for 2.5 hr per day. Lordosis behavior returned to baseline levels 7 weeks after forced exercise was stopped. Circulating levels of estrogen and progesterone measured immediately after behavioral testing did not differ between animals forced to exercise and their controls. The mechanisms responsible for the increase in lordosis behavior following exercise are unclear. It is possible that a change in body composition, a change in neural sensitivity to gonadal steroids, and/or changes in pituitary or adrenal function contribute to the increased lordosis behavior in exercised animals.     

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.     

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.     

Effects of an estrogen antagonist,MER-25, on mounting behavior and lordosis behavior in the female rat

Four daily injections of 20 mg ethamoxytriphetol, MER-25, to intact female rats with regular 4-day estrous cycles inhibited lordosis behavior, but had no inhibitory effect on mounting behavior. Ten mg/day of MER-25 for 9 days partially antagonized the stimulatory effect of 2 μg/day of estradiol benzoate on lordosis behavior in ovariectomized female rats, but had no inhibitory effect upon mounting behavior. MER-25 (10 mg/day for 9 days) stimulated the display of mounting behavior in ovariectomized female rats. No effects of MER-25 treatment (10 mg for 10 days) comparable to those of testosterone propionate (10, 50, or 250 μg for 10 days) on testicular, seminal vesicle, or ventral prostate weights of intact male rats or on seminal vesicle or ventral prostate weights of castrated male rats were observed. The results show that MER-25 acts differently upon various estrogen sensitive behaviors in the female rat.     

Antiestrogens: Effects of tamoxifen,nafoxidine, and CI-628 on sexual behavior,cytoplasmic receptors,and nuclear binding of estrogen

These experiments utilized the estrogen antagonists CI-628, nafoxidine, and tamoxifen as tools to investigate potential molecular mechanisms of estrogen activation of female rat sexual behavior. Adult female rats, ovariectomized 4–7 days previously and matched for body weight, were administered single sc injections of one of the three antiestrogens, and the ability of the antagonists to block estrogen-induced sexual behavior, to deplete and replenish hypothalamic estrogen receptors, and to inhibit the binding of estradiol by hypothalamic nuclei 2 hr, or 1, 2, 4, or 7 days later was assessed. All three compounds produced a dose- and time-dependent inhibition of estrogen-activated lordosis, with tamoxifen being the most potent inhibitor. The three antiestrogens also caused prolonged depletion of hypothalamic estrogen receptors, but there was no correlation between receptor levels and the degree of inhibition of lordosis behavior at any time point following antiestrogen treatment. Rats showed high levels of sexual receptivity when antiestrogens were injected 2, 4, or 7 days before estrogen; however, hypothalamic estrogen receptors were still markedly (up to 70%) reduced at some of these time points. In contrast, there was a large (r = 0.67), significant correlation between the ability of all three agents to reduce [³H]estradiol binding by brain cell nuclei and their ability to reduce the display of estrogen-induced female sexual behavior. Antiestrogen injections which inhibited lordosis always decreased the level of specific estradiol binding by hypothalamic nuclei. These data indicate that delayed receptor replenishment does not adequately explain the antagonism of lordosis behavior by antiestrogens. The results presented here strongly point to the cell nucleus as the critical locus of receptor-mediated interactions which underlie estrogen and antiestrogen regulation of female sexual behavior.     

Feminine sexual behavior in rats enhanced by prenatal inhibition of androgen aromatization

Male and female rats were exposed to the aromatization inhibitor 1,4,6-androstatriene-3, 17-dione (ATD) in utero via prenatal injections to the pregnant mother. In adulthood, lordosis behavior was measured in response to ovarian hormones. Males and females exposed prenatally to ATD showed enhanced lordosis behavior in response to estrogen alone and in response to estrogen plus progesterone when compared to controls. These data lend further support to the idea of a prenatal, androgen-sensitive phase of sexual differentiation in which defeminization normally occurs in both male and female rats. Further, these data support the concept that androgen aromatization is an important process in this defeminization.     

Effects of septal lesions on the lordotic behavior of weanling male and female rats

Twenty-four-day-old weanling male and female rats were either lesioned in the septal area, gonadectomized, lesioned and gonadectomized, or not treated. Tests for lordotic behavior were carried out at 27 and 28 days of age after priming with estradiol alone and with estradiol plus progesterone. A second set of tests for lordotic behavior was carried out at 47 and 48 days of age. In the interim period, some of the animals were given chronic estrogen treatment. In tests given at 27 days of age, septal lesions facilitated lordotic responding after estrogen priming; no differences were observed between male and female animals. At 47 and 48 days of age, however, unless male rats had been exposed to chronic estrogens following septal lesioning, no facilitation of estrogen-induced lordotic behavior occurred. In addition, it was found that female rats gonadectomized at 24 days of age and given no exposure to estrogens between the tests at 27 and 28 days and those at 47 and 48 days of age showed reduced sensitivity to estrogens, as compared to normal or estrogen-treated females, whether lesioned or not.     

The ventromedial nucleus of the hypothalamus and the hormonal arousal of sexual behaviors in the female rat

Bilateral lesions of the ventromedial nucleus of the hypothalamus interfered with the estrogenic induction of sexual receptivity in the female rat, but seemingly did not affect the ability of female rats to show lordosis following combined stimulation with estrogen and progesterone. In addition, ventromedial hypothalamic lesions did not affect the ability of females to show male-like sexual activity in response to exogenous androgenic stimulation.     

Lordosis behavior in intact male rats: effects of hormonal treatment and/or manipulation of the olfactory system

The aim of this study was to investigate the olfactory mechanisms regulating the display of lordosis behavior in intact Wistar male rats bred in our colony. Gonadally intact males show a low capacity to respond by lordosis to male mounts and were insensitive to manipulations of the olfactory system (exposure to the odor of male urine or accessory bulb removal (AOBR)) which have been previously shown to facilitate the display of lordosis behavior in orchidectomized animals primed with ovarian hormones. Treatment with either estradiol benzoate (EB) or EB and progesterone (P) consecutively did not render these gonadally intact animals sensitive to the effects of AOBR. By contrast exposure to male urine was capable of facilitating the display of lordosis behavior in intact male rats given EB + P consecutively. These results are discussed in the light of previous findings showing that (1) two inhibitory structures, the accessory olfactory bulb and the septal and preoptic areas, are involved in the control of lordosis behavior in the male rat; (2) the effects of olfactory cues on the display of lordosis behavior are dependent on the action of both EB and P in orchidectomized animals.