Facilitatory and inhibitory effects of beta-endorphin on lordosis in female rats: relation to time of administration.

The purpose of the present study was to investigate the effect of time of beta-endorphin (beta-EP) administration on lordosis in ovariectomized female rats injected subcutaneously (sc) with estradiol benzoate (EB) and progesterone (Prog). Intracerebroventricular (icv) injections of beta-EP and naloxone (NLX), an opioid receptor antagonist, were administered at the various stages of sc steroid hormone priming. Facilitation of lordosis induced by 10 microg beta-EP was observed exclusively within the initial 6 h of estrogen action, after which inhibition of lordosis occurred. At 12 h after EB priming, at the time of sc Prog treatment (or 43 h after EB priming), icv injection of 10 microg beta-EP significantly inhibited lordosis. Lordosis was significantly facilitated by icv injections of 1 and 10 microg beta-EP at the time of sc EB priming, but not by 0.1 microg beta-EP. A dose-response relationship was identified for lordosis in experimental animals receiving icv injection of beta-EP. Lordosis was inhibited by icv injections of 1 and 10 microg beta-EP at 1 h before the test (or 47 h after EB priming). Lordosis was significantly inhibited by icv injection of NLX at all stages. From the present results, it seems that two different mechanisms are involved in endorphinergic modulation of rats' sexual receptivity: (a) the endorphinergic system at the initial stages of estrogen action facilitates the estrogen activation of lordosis; (b) the endorphinergic system at the final stages of steroid action inhibits lordosis. Moreover, there exists a critical time between 6 and 12 h after estrogen priming for endorphinergic mediation to modulate estrogen action.     

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.     

Hormonal Modulation of the Cutaneous Initiation of Lordosis in Infant and Adult Rats

The purpose of these experiments is to compare the regional specificity (Experiment 1) and the hormonal modulation (Experiment 2) of the cutaneous initiation of lordosis in 4- to 6-day-old male and female rats (infants) and in 60- to 90-day-old female rats (adults). In Experiment 1, subjects were primed with 100 μg estradiol benzoate (EB) and 0.5 mg progesterone (P) and were denervated on the Waist (dermatomes L1-L3), Midriff (dermatomes T10-L3), Flanks (dermatomes L4-L6), or Sides (dermatomes T10-L6). In infants, there were no significant differences between males and females. Denervation of the Waist. Midriff, or Sides but not of the Flanks significantly decreased the percentage of subjects displaying lordosis, lordosis quotient (LQ), and mean lordosis duration; no significant differences were obtained among Waist-, Midriff-, or Sides-denervated infants. In contrast, denervation of the Sides but not of the Waist significantly decreased LQ and mean lordosis intensity among adults. In Experiment 2, Waist-denervated infants and their surgical Controls were treated either with 100 μg EB and 0.5 mg P or with the oil vehicle; Waist-denervated adults and their surgical Controls received either 100 or 10 μg EB (no P). Regardless of hormone treatment, denervation of the Waist significantly decreased LQ and lordosis duration in infants and decreased LQ and lordosis intensity in adults. In infants, the only effect of priming with EB and P was to increase the percentage of pups showing lordosis and lordosis duration among the surgical Controls. In contrast, priming with 100 μg EB significantly increased the percentage of rats displaying lordosis, LQ, and lordosis intensity among Waist-denervated adults. These data suggest that cutaneous input from the Waist is important for eliciting lordosis in both infant and adult rats, and that the importance of this input is modulated by hormone priming in adult but not infant rats.     

Progesterone-Facilitated Lordosis in Medial Preoptic Area-Lesioned, Juvenile Guinea Pigs

Juvenile female guinea pigs rarely display lordosis in response to estradiol and progesterone treatments that elicit sexual receptivity in adults. To test the hypothesis that the medial preoptic area (MPOA) tonically inhibits the display of steroid-induced lordosis in juveniles, 11-day-old guinea pigs were ovariectomized (OVX) and received bilateral, sham, or electrolytic lesions aimed at the MPOA 3–4 days later. At 20–22 days of age, these females were tested for the expression of sexual receptivity following injections of estradiol benzoate (EB, 10 μg sc) and progesterone (0.5 mg sc, 40 h after EB). The lesions damaged portions of the MPOA, the nucleus of the diagonal band of Broca, the lateral aspect of the medial preoptic nucleus, the medial part of the preventricular portion of the periventricular nucleus, and the anterior commissure. The lesions did not alter the display of estradiol-induced lordosis. However, after treatment with EB plus progesterone, 20% of the sham-lesioned females displayed lordosis, as compared to 80% of the MPOA-lesioned animals. These data are consistent with the hypothesis that neurons originating in and/or traversing the MPOA tonically suppress the display of progesterone-facilitated lordosis in juvenile guinea pigs. Removal of this inhibitory input allows prepubertal females to respond behaviorally to estradiol and progesterone in an adult-typical fashion.     

Masculinization and defeminization induced in female hamsters by neonatal treatment with estradiol, RU-2858, and nafoxidine

Newborn female hamsters were treated with 0.1 or 1.0 ng of estradiol benzoate (EB), with 1.0 ng–2.0 μg of the synthetic estrogen RU-2858, or with 0.1 or 0.5 μg of the antiestrogen nafoxidine. When adult the animals were treated with EB and progesterone and tested for the display of lordosis and with testosterone propionate and tested for the display of mounting behavior. The EB doses used failed to alter sexual differentiation. RU-2858 masculinized and defeminized in a dose-dependent manner being most effective when given neonatally as two divided doses. Nafoxidine inhibited lordosis without enhancing mounting behavior. The findings support the hypothesis that estrogens may be involved in the normal sexual differentiation process.     

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.     

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.     

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.     

Behavioral responses to intracerebroventricularly administered neurohypophyseal peptides in mice

Lysine vasopressin (LVP), arginine vasopressin, oxytocin, and arginine vasotocin administered intraventricularly (icv) to mice all provoked a dose-dependent behavioral response in the range 0.1 – 1.0 μg. This response included a pronounced hyperactivity, extensive foraging, increased grooming, and at higher doses, stereotyped scratching, squeaking, and occasional barrel rolling. The four hormones were all approximately equipotent. Desglycinamide lysine vasopressin and [desaminocys₁, D-Arg₈] vasopressin produced some of the characteristic behaviors, but were much less potent. While pretreatment of the animals with reserpine (5 mg/kg ip), haloperidol (0.5 mg/kg ip), or physostigmine (0.5 mg/kg ip) sedated the animals and attenuated the locomotion and grooming, these drugs did not substantially alter the characteristic behavioral responses to LVP. Pretreatment with α-methyl-p-tyrosine (400 mg/kg ip), p-chlorophenylalanine (320 mg/kg ip), 6-hydroxydopamine (100 μg icv), ergotamine (0.5 μg icv), ethoxolamide (52 ng icv), diphenhydramine (20 μg icv), prostaglondin F_2α (2 μg icv), or naloxone (1 mg/kg ip) did not alter the LVP-induced behaviors. None of these drugs or -amphetamine (0.5 to 20 mg/kg ip) or nicotine (0.1 or 1 μg icv) mimicked the behavioral effects of the hormones.     

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.     

Considerations into the mechanism of estrogen-stimulated uterine prostaglandin synthesis

Progesterone priming of the ovariectomized rat, followed by a single injection of estradiol-17β (10 μg) is followed by an increased uterine synthesis of both PGF and PGE. The administration of an estrogen antagonist (MER-25; 10 mg) concomitantly with estradiol had no effect on uterine prostaglandin synthesis. Similarly, the administration of either Actinomycin D or cycloheximide, antibiotics demonstrated to inhibit mRNA and protein synthesis, respectively, is without effect on estrogen-stimulated uterine prostaglandin synthesis. These results are considered with regard to the classic receptor theory of estrogen action and are a preliminary indication that estrogen-stimulated uterine prostaglandin synthesis may not require those receptor mediated events.     

Progesterone facilitation of lordosis in male and female Sprague-Dawley rats following priming with estradiol pulses

Adult male Sprague-Dawley rats rarely exhibit progesterone-facilitated lordosis following steroid treatments which are effective in females. In contrast, progesterone-facilitated lordosis has been observed following priming with estradiol pulses in another strain. The aim of this study was to compare progesterone-facilitated feminine sexual behavior in adult male and female Sprague-Dawley rats following priming with estradiol benzoate (EB) or estradiol pulses. Female sexual behavior was measured in adult, gonadectomized males and females treated as follows: Two pulses of estradiol followed by progesterone or oil the next day; EB (two doses) for 3 days, and progesterone or oil the next day. These protocols were repeated at 4- or 6-day intervals, respectively. Progesterone-facilitated lordosis was observed consistently in both sexes treated with estradiol pulses. By the fifth test, lordosis quotients did not differ between the sexes, but the lordosis ratings in progesterone-treated males remained lower than those observed in females. Proceptivity (hop-darting) was facilitated by progesterone in females, but was never observed in males. Lordosis was induced in both sexes by 15 micrograms EB, but was not reliably facilitated by progesterone. Treatment with the lower dose of EB (1.5 micrograms) induced high levels of receptivity in females (occasionally facilitated by progesterone), but not in males regardless of subsequent treatment (i.e, progesterone or oil). These data suggest that progesterone-facilitated lordosis can be induced in male Sprague-Dawley rats, if a regimen of estradiol pulses is used. Thus, the brain of the adult male is not inflexibly differentiated with regard to progesterone facilitation of feminine receptive behavior.     

Aromatization and the induction of male sexual behavior in male, female, and androgenized female hamsters

Eight weeks after gonadectomy male, female, and androgenized [10 μg testosterone propionate (TP), 24 hr after birth] female hamsters were given daily treatment with: 150 μg dihydrotestosterone (DHT), 5 μg estradiol benzoate (EB), 150 μg DHT + 5 μg EB, 150 μg DHT + 1 μg EB, 30 μg DHT + 5 μg EB, 30 μg DHT + 1 μg EB, or the oil vehicle. Treatment of castrated male hamsters with 5 μg EB fully restored mounting but relatively few of these animals intromitted and none ejaculated. Treatment with 150 μg DHT restored all components of male sexual behavior but only in a small proportion of the males. Combined treatment with EB and DHT restored mounts, intromissions, and ejaculations in the majority of the males. Although as little as 30 μg DHT + 1 μg EB restored the full complement of male behavior, the males which received 150 μg DHT + 5 μg EB or 150 μg DHT + 1 μg EB required fewer intromissions to achieve ejaculation than the males which received 30 μg DHT + either dose of EB. The response of the androgenized females was similar to that of the males except that the androgenized females had lower intromission rates and none ejaculated. Relatively few of the nonandrogenized females responded to EB and DHT treatment and those that did mounted only a few times each test. These results demonstrate that both EB and DHT can stimulate male sexual behavior in the hamster and that the sensitivity to EB and DHT for copulatory behavior is determined by early postnatal androgen exposure.     

Diethylstilbestrol facilitates masculine and feminine copulatory behavior in female rats

Diethylstilbestrol (DES), which binds to estrogen receptor without crossreacting to androgen receptor, was tested for its ability to facilitate male-typical mounting behavior. The administration of either 30 or 90 μg of DES per day to adult ovariectomized female rats activated mounting behavior in 94% of the animals (last three tests). The response to the two dosages did not differ. The mount frequency response to 30 μg of DES of 6.8 (mean of last three tests) was only about half as high as the response to 100 μg of testosterone propionate. All animals receiving DES also responded with lordosis behavior when mounted. The lower dosage of DES depleted 91% of hypothalamic cytosol estrogen receptors, and the higher dosage 96%. Androgen receptors were not depleted. Thus the synthetic estrogen DES can facilitate masculine sex behavior by interacting with estrogen receptors without binding to or translocating androgen receptors.     

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.     

Differential sensitivity of mounting and lordosis control systems to early androgen treatment in male and female hamsters.

The effects of early testosterone propionate (TP) treatment on the adult sexual behavior of hamsters were investigated in two experiments. In Expt. I, male and female pups were injected with oil vehicle or 1, 5, 10, 50, 100, or 250 μg of TP 24 hr after birth. In Expt. II, males and females received either oil or 10 μg of TP on the day of birth (Day 1), Day 3, Day 5, Day 7, or Day 9. At 70 days of age all animals were gonadectomized and 10 days later tested for lordosis behavior after estrogen and progesterone priming. One week after the test for female behavior all females began receiving 500 μg of TP each day and were tested for mounting and intromission behavior three times at 10 day intervals. Lordosis behavior was inhibited by as little as 5 μg of TP given 24 hr after birth. In males this dose produced the maximal effect, but in females increasing dosages resulted in a proportional decrease in lordosis duration. One μg of TP neonatally facilitated later mounting and intromission behavior in females and 250 μg of TP was no more effective than 1 μg. Lordosis duration was inhibited in females by 10 μg of TP on either Day 1 or 3, however, mounts and intromissions were facilitated by TP treatment on Day 1, 3, 5 or 7. These experiments demonstrate that the mechanisms mediating masculine behavior are more sensitive to neonatal TP treatment than are the mechanisms mediating lordosis behavior.     

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.     

The comparative potency of various steroids to complete the priming process for lordosis in guinea pigs

Ovariectomized adult guinea pigs were treated with a regimen of estradiol benzoate (0.2 μg/animal estradiol benzoate at hr 0 and 19) that was shown to be minimally effective for the induction of lordosis. They were then treated with 10, 20, or 80 mg of enclomiphene, 5, 20, 40, or 100 μg of estradiol, or testosterone, cortisol, estrone, estriol, diethylstilbestrol, catechol estradiol, or catechol estrone (all at a dose equivalent to 5 μg of estradiol) at hr 28. At hr 39 all females were given 0.5 mg progesterone, and subsequently tested for lordosis behavior. Of the various agents injected at hr 28 only estradiol (at all doses given), estrone, estriol, and diethylstilbestrol were effective in supporting display of lordosis behavior. The results indicate that the antiestrogen enclomiphene, the catechol estrogens, and at least some C₁₉ and C₂₁ steroids are weaker than E₂ or ineffective in facilitating lordosis behavior when given late in the priming period. Because previous work had shown that enclomiphene has partial estrogenic effects on lordosis behavior when administered early in the priming period (i.e., at hr 0, 19), it is suggested the early and late phases of the priming process induced by E₂ entail qualitatively different neural processes.     

Effect of 5 alpha-dihydrotestosterone on sexual receptivity and neural progestin receptors in ovariectomized rats given pulsed estradiol

Experiments were carried out to examine the mechanism whereby 5 alpha-dihydrotestosterone (DHT) antagonizes the stimulatory effects of estrogen plus progesterone (P) on sexual receptivity (lordosis) in the ovariectomized rat. Estradiol (E2; 1 microgram s.c. in 10% ethanol) was administered in a discontinuous (pulsed) treatment regimen thought to mimic phase requirements of estrogen action; two injections of E2 were given either 6 or 12 h apart (first injection, Hour 0). Progesterone (0.5 mg in oil) was injected at Hour 20, and behavioral testing occurred at Hour 24. Dihydrotestosterone (2.5 mg s.c. in 10% ethanol/propylene glycol) inhibited lordosis when it was given before (-12 or -3 h), between (+3, or -3 and +3 h), or after (+8 h) the two E2 injections, but was not effective when given at +20 h. Significant inhibition of E2 + P-induced lordosis was achieved by 2.5 but not 1.0 or 0.2 mg DHT at -3 h, while uterine weights in the same animals were reduced significantly by 2.5 and 1.0 mg DHT. Serum E2 and DHT concentrations peaked rapidly after injection, declining to near baseline by 3 and 12 h, respectively. Induction of cytosolic progestin receptors (cPR) in the preoptic area and medial basal hypothalamus by estrogen was not prevented by DHT when animals were given the two pulsed E2 injections or daily injections of estradiol benzoate, although P was able to override the inhibitory behavioral effects of DHT in the latter but not the former group.(ABSTRACT TRUNCATED AT 250 WORDS)