Hormonal differentiation of sexual behavior in Japanese quail

The effect of hormones on the development of Japanese quail during the postembryonic period was examined. First, subcutaneous implants of estradiol monobenzoate (EB) and testosterone propionate (TP) were implanted 6–12 hr after hatching. EB and TP had no effect on the differentiation of sexual behavior in genetic males or females. However, EB had marked feminizing effects on plumage in genetic males. Second, the role of gonadal hormones during development was examined by gonadectomizing males and females 6–12 hr after hatching and treating them intramuscularly with EB or TP as adults. EB-treated adult females displayed sexual behavior typical of the genetic female and developed female plumage. A significant proportion of TP-treated females (57%) displayed male sexual behavior patterns. Cloacal gland development and male-type vocalizations were induced. EB-treated males displayed either male or female sexual patterns depending on the stimulus conditions. Third, to test whether bisexuality in gonadectomized males and females is maintained despite steroid treatment and expression of sexual behavior in adulthood, gonadectomized quail which were originally treated with EB received TP and vice versa. The results indicate that in the absence of gonadal hormones after hatching female quail remain bisexual until exposed to estrogen, whereas gonadectomized male quail retain behavioral bisexuality irrespective of prior estrogen or androgen exposure.     

Neonatal Androgen Affects Copulatory Behavior in the Female Musk Shrew

The role of neonatal testosterone in the development of copulatory behavior was examined in an insectivore, the musk shrew (Suncus murinus). Female musk shrews were treated with testosterone propionate (TP) for the first 5 days of life and then tested in adulthood for either female or male-like copulatory behavior. Early TP had a masculinizing effect; neonatally treated animals mounted a stimulus female more frequently, and with shorter latencies, in response to adult testosterone treatment than did control females. Neonatally androgenized females also showed deficits in female sexual behavior; few received ejaculations from stud males. This difference was likely caused by increased aggression exhibited by the neonatally TP-treated females toward males. In turn, female aggression decreased efficiency of male partners' intromission attempts. Early TP treatments also caused structural abnormalities in the ovaries, but did not effect their capacity to ovulate in response to either gonadotropin-releasing hormone or human chorionic gonadotropin injection. In sum, exposure to TP during development augmented display of male-like behavior in females and had subtle deleterious effects on expression of feminine behavior.     

Mounting behavior of female guinea pigs after prenatal and adult administration of the propionates of testosterone, dihydrotestosterone, and androstanediol.

Female guinea pigs were exposed prenatally (Day 28–58) to the propionates of testosterone (TP), dihydrotestosterone (DHTP), or androstanediol (ADP). Only TP females failed to display lordosis in adulthood after estrogen and progesterone treatment. When given TP in adulthood, females in all groups mounted, but TP and DHTP females showed augmented intromission frequencies and higher percentages of correctly oriented mounts relative to controls. Moreover, TP females responded more quickly to TP injections in adulthood and had higher over-all mounting frequencies than other groups, while DHTP females displayed mounting frequencies intermediate to controls and TP females. ADP females were not different from controls for any measure of mounting behavior.No female in any group mounted when given DHTP in adulthood, even after 7 wk of daily injections. Since male guinea pigs do mount in response to DHTP given in adulthood, the results raise the possibility that mechanisms determining sensitivity to specific steroids may not be mediated exclusively by steroids during critical periods of embryological differentiation.     

Effects of androgen on fighting behavior in male and female Mongolian gerbils (Meriones unguiculatus)

Contrary to the results of most other mammalian species studied thus far, castration in infancy or adulthood has been shown to increase the display of intermale aggression in gerbils tested as adults in dyadic encounters. Males castrated in adulthood were divided into two groups: one that received testosterone propionate (TP) treatment and one that did not. A third group of adult males were sham-operated. Infant subjects were either sham-operated or castrated and tested once without and once with TP. Both infant and adult castrates that received no TP treatment demonstrated significantly more fighting behavior than did sham-operates. Adult subjects treated with TP show significantly less aggression than castrates that did not receive TP. Ovariectomized females were also divided into a TP and no-TP group. Females treated with TP showed significantly less aggression than those that had no treatment showing that TP inhibits aggression in both males and females gonadectomized in adulthood. The results are assessed in terms of the importance of perinatal androgen to “organize” adult behavior patterns.     

Differential responsiveness to replacement therapy of pre- and postpubertally castrated mice with respect to intermale aggression

Male mice castrated before Day 6 of postnatal life differ from adult castrates in that they do not exhibit normal patterns of intermale aggression following replacement therapy as adults. Two experiments sought to determine the effect castration after Day 6, but before puberty, would have on this response to adult replacement therapy. It was found that adult castrates showed some increases in fighting as early as six hr after a subcutaneous (s.c.) injection of 2 mg testosterone propionate (TP). At 30 hr after treatment 14/15 mice fought, while at 72 hr 15/15 fought and the number of fights in 10 min was significantly higher than at 30 hr. In the second experiment, the response to adult treatment with 2 mg TP (s.c.) in mice castrated in Day 10 or Day 50 was compared. Different groups were tested at 16, 40, 64, and 88 hr after TP treatment. The latency to respond to TP was significantly less and the level of fighting obtained was significantly greater in Day 50 castrates than in Day 10 castrates at each time of testing. The proportion of Day 10 (14/15) and Day 50 (15/15) castrates fighting was equal by 88 hr, while the mean fighting frequency was significantly lower in Day 10 castrates (M = 4.93 ± 4.78) than in Day 50 castrates (M = 8.06 ± 1.63). Day 50 castrates fought significantly more often than controls at 40 hr, whereas the level of fighting attained by Day 10 castrates was not significant until 64 hr. These results suggest that even after the organizational period for aggression, testosterone is necessary for maintenance and/or preparation of the substrate essential to the elicitation of aggression.     

Interaction of naltrexone with postnatal administration of testosterone and estrogen on neurobehavioral sexual differentiation in rats

The present study examined whether some effects of gonadal sex hormones on neurobehavioral sexual differentiation might be mediated by endogenous opioids. Male and female pups were administered sesame oil, testosterone propionate (TP; 25 micrograms) or estradiol benzoate (EB; 10 micrograms) on postnatal Days 2 and 3. Half of each group was also administered naltrexone (N; 50 micrograms) twice daily on these two days. Females were studied for effects of the treatments on puberty. Males and females were studied in adulthood for open field behavior, daily water intake, and saccharin consumption and preference for 0.125, 0.25, and 0.50% saccharin solutions. TP treatment significantly delayed the date of vaginal opening, whereas EB treatment significantly accelerated the date. N treatment potentiated this effect of TP, but had no effect in EB treated females, nor did it influence the anovulatory sterility produced by both hormone treatments. N treatment alone had no effect on puberty in females or open field behavior of either sex. The drug produced an overall increase in female saccharin consumption and preference, but no effect was observed in males on these measures. Both TP and EB treatment produced marked increases in daily water consumption in females, an effect which was significantly attenuated by N treatment. Effects of both hormones on saccharin consumption were sex dependent and partially antagonized by N treatment. Finally, we observed a sex difference in daily water intake wherein females were found to consume approximately 20% more water on a body weight basis in a 24-hr period than males. Postnatal TP and EB treatment increased adult daily water consumption in females above the level of controls. This increase was partially antagonized by N. Treatment with N alone had no effect on female water consumption, but produced a small decrease in male consumption. Overall, these results provide preliminary evidence that some organizational effects of TP and EB on nonreproductive sex differences may be mediated by endogenous opioids.     

The influence of caging conditions and hormone treatments on fighting in male and female hamsters

After gonadectomy, more individually caged female hamsters fought prior to the initiation of hormone treatments than did group-caged females. Daily injections of testosterone propionate (TP), estradiol benzoate (EB), or progesterone (Prog) had no influence on the number of individually caged females that fought. However, TP and EB were effective in increasing the number of group-caged females that fought. In contrast to females, both individually and group-caged males fought infrequently after castration. Daily injections of TP, EB, or Prog were effective in increasing the number of individually caged males that fought, while only TP and EB were effective in group caged males. Prog failed to increase the number of group-caged hamsters of either sex that fought.     

Estrogen plus androgen induced mounting in adult female hamsters

This study demonstrated that the combined administration of estrogens and androgens activates the display of mounting by female hamsters. Forty-nine ovariectomized hamsters were injected daily with either estradiol benzoate (EB, N = 8); dihydrotestosterone propionate (DHTP, N = 7); testosterone propionate (TP, N = 6); androstenedione (AD, N = 9); EB plus DHTP (N = 10); or estrone plus DHTP (E₁ + DHTP, N = 9). All androgens were administered at a dose of 1 mg per day for the first 24 days and at a dose of 2 mg per day for the last 14 days. The EB dose was 6 μg per day and the E₁ dose was 100 μg per day. Females were tested for male behavior once a week starting on Day 10 of injections and for female behavior on Day 39.One hundred percent of EB + DHTP treated females; 67% of the E₁ + DHTP treated females; 55% of the AD treated females; 33% of the TP treated females; 29% of the DHTP treated females; and none of the EB treated females mounted during at least one test. Only one of the E₁ + DHTP treated females showed the intromission pattern; otherwise most females which mounted displayed the intromission pattern. The median number of days preceding the onset of mounting ranged from 21 to 31 days and did not differ among treatment groups.     

Effects of testosterone, estrogen, and dihydrotestosterone upon aggressive and sexual behavior of female rats

Groups of female TMD rats were treated either with estradiol benzoate (EB), dihydrotestosterone propionate (DHTP), testosterone propionate (TP), EB + DHTP (EB/DHTP), or with oil. These groups of females were tested for social aggression and for masculine and feminine sexual behavior. In addition, patterns of masculine and feminine sexual responses during the aggressive encounters, were investigated. TP-treated females of the same strain were used as opponents in the tests for aggression. In accordance with previous results, EB did not activate aggression whereas TP treatment resulted in a significant increase in aggression in females. Aggressive responses were activated by adding DHTP to EB, up to levels equal to those activated by TP. Sexual responses were observed in the tests for aggression as well as in tests for sexual behavior. The results indicated that feminine and masculine sexual responses were affected significantly by hormonal treatment. Mounting behavior in the test for aggression was activated by TP and by EB/DHTP. Lordosis and proceptive responses were inhibited in these groups as compared to EB-treated females, both in tests for aggression and in tests for sexual behavior. The results are consistent with the idea that dihydrotestosterone inhibits feminine and activates masculine sexual activity. The results also indicate that EB and DHTP synergistically activate aggression.     

A re-examination of the lordosis response in female rats given high doses of testosterone propionate or estradiol benzoate in the neonatal period

High lordosis quotients (LQ) were observed when female Wistar rats injected with 1.25 mgm of testosterone propionate (TP) on Day 4 of postnatal life were tested as intact adults. The high LQ was not due to testing during the lights-on period, the age at which the females were tested, the use of a strain that was insensitive to the masculinizing action of TP or estradiol benzoate (EB), the age at which the females were injected with TP or EB, or an abnormal response to estrogen. High LQ values were found in similar tests on adult female rats of two other strains injected with 1.25 mgm TP on Day 4 of life. A marked reduction of the facilitatory action of progesterone on receptivity in estrogen-primed animals was demonstrated in the females of all three strains treated with TP or EB during the neonatal period and for males after castration as adults.Analysis of the experimental records of the mating tests showed that females anovulatory following TP or EB administration during the neonatal period and tested either intact and under the influence of endogenous hormones or under the influence of exogenous estrogen showed a rapid and highly significant increase in receptivity during the course of prolonged (20 min) tests with two or three active stimulus males. This effect was very much reduced if the treated females were under the influence of exogenous estrogen plus progesterone. The effect was not seen in males castrated as adults and treated with estrogen, or in females not treated with steroids in the neonatal period and tested intact at proestrus alone or under the influence of exogenous steroids after ovariectomy. A significant increase in LQ during the test period was observed in females of the Wistar strain which were anovulatory as a result of exposure to constant light and were tested intact without any exogenous hormone being administered.It is suggested that although tests involving a limited number of mounts or attempts to mount at low rates over a short period of time may be adequate to determine the degree of receptivity of normal female rats they are not adequate to establish the capacity of female rats treated with steroid hormones during the neonatal period to display the lordosis response.     

Effects of estradiol benzoate, estrone, and propionates of testosterone or dihydrotestosterone on sexual and related behaviors of ovariectomized rhesus monkeys

Ovariectomized adult rhesus monkeys were injected daily for 10 days with either 1 mg of dihydrotestosterone propionate (DHTP), 1 mg of testosterone propionate (TP), 10 μg of estradiol benzoate (EB), or 500 μg of estrone (El). On the 5th and 10th days of treatment, females received two 24-min behavioral tests with each of two adult males. All females received every hormonal treatment during the course of the study, with the order of treatments counterbalanced. Prior to the initiation of an hormonal treatment, each subject received two tests with no hormone treatment (NORX). Three behaviors related to female proceptivity were recorded. Treatment with DHTP had no influence on any aspect of proceptivity measured, in comparison to the NORX condition, whereas El or TP treatment augmented the frequencies of two of the proceptive behaviors and EB increased all three. The response of the male toward the female was influenced by the female's hormonal condition. Treatment with TP or DHTP did not increase the frequency of male contact or the mount rate in comparison to the NORX condition, whereas EB or El treatment did. In addition, DHTP was the only steroid which failed to increase the percentage of tests with intromission or ejaculation when compared to NORX. Female receptivity, as measured by acceptance or rejection of male contacts, was not different for the NORX-, TP-, EB-, or El-treated conditions. DHTP treatment, however, reduced female receptivity in comparison to all other conditions. Treatment with DHTP or TP resulted in an increase in the frequency of female yawning behavior, whereas neither estrogen treatment showed any effect on this behavior. The influences of TP on female proceptive and male sexual behavior were never duplicated or even approximated by treatment of females with the nonaromatizable DHTP. Nor was there any evidence that TP inhibited female receptivity below the level characteristic of NORX females, as was true for DHTP.     

Influences of pre- and postnatal testosterone treatment on defeminization of sexual receptivity in pigs

Sexual receptivity was evaluated in female and male pigs that had experienced varying periods of exposure to testosterone pre- and postnatally. For prenatal exposure, pregnant sows were treated with testosterone propionate (TP) from Day 29-35 or Day 39-45 of gestation at a dosage that caused virilization of the external genitalia of their female offspring. Eighty-three percent of the females that received TP prenatally had regular estrous cycles, but reached puberty later than control females. Only 26% of the females that received TP both pre- and postnatally (4-6 mo of age) were observed in estrus by 10 mo of age. After ovariectomy and acute treatment with estradiol benzoate (EB), the proportion of females that showed the immobilization response (receptivity) was similar for all groups of females independent of pre- or postnatal TP treatment. Females treated prenatally from Day 39-45 showed the immobilization response for fewer days after treatment with a high dosage of EB than did controls. On the basis of these observations, we conclude that receptivity in female pigs is not affected greatly by testosterone treatment at the stages of development that were investigated. Males castrated at birth and treated with a single injection of EB after 9.5 mo showed the immobilization response. In contrast, few males castrated at 8 mo or castrated at birth and treated with TP from 3 to 6 mo showed the immobilization response after EB treatment. These observations provide direct evidence for a postnatal component of testosterone-dependent defeminization of receptivity in male pigs.     

Expression of male-typical behavior in adult female pseudohermaphroditic rhesus: Comparisons with normal males and neonatally gonadectomized males and females

Two types of pseudohermaphroditic female rhesus produced by exposure to either testosterone propionate (TP) or dihydrotestosterone propionate (DHTP) prior to birth were ovariectomized postpuberally and evaluated for the display of male-typical sexual behavior in response to exogenous TP in adulthood (2 mg/kg/day for 12 weeks). Their performance in standardized tests with estrogenized female partners was compared to that of neonatally gonadectomized males and females identically tested and treated with exogenous TP as adults. In addition intact adult males not given exogenous TP were tested with the same estrogenized female partners. There were no reliable differences between the two types of pseudohermaphrodites on any measure of behavior shown during the tests. Accordingly results were combined. Reliable behavioral changes induced by the TP given in adulthood were limited to increases in purse-lip responses, the induced increases were similar in pseudohermaphrodites and castrated males, and increases were reliably greater in these two groups of subjects than in females. Pseudohermaphrodites and castrated males did not differ reliably from intact males in performance of purse-lip gestures during TP treatment. In the performance of mounting, however, pseudohermaphrodites and castrated males remained consistently below the standard of the intact males. The estrogenized female partners displayed proceptive responses most frequently to the intact males and least frequently to the females. Their proceptive responses with castrated males resembled their performance with intact males, but with pseudohermaphrodites their proceptive responses more closely resembled their performance with females. Receptive behavior of the female partners was displayed most frequently to intact males, at intermediate levels to castrated males, and least often to pseudohermaphrodites. Results are completely consistent with the notion that androgens in high concentrations before birth alter mechanisms related to the later display of masculine behavior. These alterations in behavioral mechanisms are of such a nature that the display of male-typical behavior induced by androgens in adulthood is more pronounced and more frequent than it would have been otherwise. The alterations in masculine behavior observed in pseudohermaphroditic rhesus are not different in kind or scope than those reported extensively for lower mammals.(ABSTRACT TRUNCATED AT 400 WORDS)     

Behavioral demasculinization of female quail is induced by estrogens: studies with the new aromatase inhibitor, R76713.

The injection before Day 12 of incubation of estradiol benzoate (EB) into Japanese quail eggs produces a complete behavioral demasculinization of adult males that will hatch from these eggs. These males never show copulatory behavior even after administration of high levels of exogenous testosterone (T). It is usually assumed that such a demasculinization normally takes place in female embryos under the influence of endogenous estrogens but few experimental data are available to confirm the validity of this model. A series of four experiments was performed during which R76713, a triazole derivative that specifically inhibits aromatase (estrogen synthetase) activity, was injected into quail eggs at different stages of incubation to prevent the production of endogenous estrogens. The consequences of these embryonic treatments on the T-activated sexual behavior in adults were then quantified. When injected before Day 12 of incubation, R76713 completely blocked the behavioral demasculinization of females without affecting the behavior of the males. After a treatment with T, almost all R76713-treated females showed as adults a masculine copulatory behavior that was undistinguishable from the behavior of intact males. This effect was fully reversed by the injection in egg of EB demonstrating that the effects of R76713 were specifically due to the suppression of endogenous estrogens. Injection of R76713 during the late phase of the incubation (Day 12 or Day 15) only maintained weak copulatory behavior in females which confirmed that the behavioral demasculinization in quail takes place mainly though not exclusively during the early stages of ontogeny. In a last experiment, we combined an early R76713 treatment with an injection of EB either on Day 9 or on Day 14 of incubation. This showed that the sensitivity to differentiating effects of estrogens varies with age in a sexually differentiated manner. The EB injection on Day 9 demasculinized both male and female embryos. If this injection was delayed until Day 14, it was no longer effective in males but still caused a partial demasculinization of females. This demonstrates that even if females are not yet behaviorally demasculinized on Day 9 of incubation (suppression of aromatase activity at that age will maintain the behavior), their sensitivity to estrogens is already different from that of males.     

Neonatal dihydrotestosterone and estrogen stimulation: Effects on sexual behavior of male rats

Male rats castrated on the second day after birth (Day 2) were, for the next 10 days, given daily injections of one of five steroids or steroid combinations: 200 μg of testosterone propionate (TP); 200 μg of dihydrotestosterone propionate (DHTP); 5 μg of estradiol benzoate (EB); 5 μg of estradiol benzoate plus 200 μg of dihydrotestosterone propionate; oil vehicle (VH). Control male rats castrated on Day 90 received a sham castration and oil vehicle in the neonatal period. All animals were given TP in adulthood and tested for male sexual behavior. There was no difference in mounting activity among the subjects. Day 2 DHTP subjects displayed intromissions but were incapable of ejaculating. The more frequent display of intromissions by Day 2 DHTP animals in comparison to Day 2 VH animals could be solely due to their larger and more highly developed penes. On the other hand, the ejaculatory failure of the Day 2 DHTP subjects was attributed to some deficiency in central neural processes controlling ejaculatory mechanisms rather than inadequate penile development. Equivocal results were obtained with the Day 2 EB and Day 2 EB-DHTP animals in that only a few animals in both groups showed an ejaculatory pattern.     

Sexual differentiation of behavior in the zebra finch: effect of early gonadectomy or androgen treatment

Treatment of nestling zebra finches with estradiol benzoate (EB) has been shown to masculinize singing in females and demasculinize copulatory behavior in males, suggesting that sexual differentiation of these behaviors is under hormonal control such that testicular hormones induce the capacity for song and ovarian hormones suppress the capacity for mounting. Two experiments were carried out to obtain a more complete picture of sexual differentiation in this species. In Experiment 1, nestlings were injected daily for the first 2 weeks after hatching with testosterone propionate (TP), dihydrotestosterone propionate (DHTP), or a combination of DHTP and EB. As adults, birds were gonadectomized and implanted with TP prior to testing, then tested again after implantation with EB. Singing was not increased in females by any of the treatments. The only effect of either TP or DHTP given alone was defeminization of female proceptive behavior by DHTP. Thus androgens appear to have less influence than estrogens on sexual differentiation of behavior in this species. The combination of DHTP and EB demasculinized mounting in males. In Experiment 2, nestlings were gonadectomized at 7-9 days of age and implanted with TP prior to testing in adulthood. Early gonadectomy had little effect on later behavior; early castrated males sang, danced, and copulated normally and early ovariectomized females neither sang nor mounted.     

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.     

Testosterone increases singing and aggression but not male-typical sexual partner preference in early estrogen treated female zebra finches

Female zebra finches given estradiol benzoate (EB) as nestlings and testosterone propionate (TP) as adults show masculinized sexual partner preference, preferring females instead of males. This suggests an organizational effect of EB on sexual partner preference in a socially monogamous species that pairs for life. It is not known whether there is an activational hormone effect on sexual partner preference in this species, or whether adult testosterone treatment is necessary for masculinized preference to be expressed. In this experiment females were injected with EB daily for the first 2 weeks posthatching. As adults they were given TP filled or empty implants. Subjects were then given two-choice preference tests with male vs female stimuli, in which singing as well as proximity to the stimuli was recorded, followed by tests in a group aviary for social behavior and pairing preference. Females with TP implants sang more than females with empty implants and were more aggressive toward other females. They did not, however, differ from females with empty implants in any measure of sexual partner preference. Neither group showed a marked preference for males; instead both groups were equally interested in males and females. Thus adult testosterone treatment is not necessary for early estrogen treated females to show a shift in sexual partner preference in the male-typical direction.     

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

To test the hypothesis that masculinization may be androgen dependent and defeminization, estrogen dependent, newborn female hamsters were administered 50–2000 ng of estradiol benzoate (EB), 0.05–50 ng of the synthetic estrogen RU-2858, or 1000 ng of testosterone propionate (TP). All three agents facilitated the display of male-type mounting responses in adulthood. A dose of 500 ng of EB was most potent in this regard, although significant masculinization was induced by 50 ng of EB and 0.05 ng of RU-2858 as well as by TP. TP did not inhibit adult lordotic behavior. Lordosis durations were reduced in a dose-dependent manner by EB, whereas the dose-response curve for RU-2858-induced defeminization was found to be nonlinear. The observation that picogram to nanogram amounts of estrogen can masculinize is consistent with the aromatization hypothesis of sexual differentiation.     

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.