Mounting behavior and lordosis behavior in castrated male rats treated with testosterone propionate, or with estradiol benzoate or dihydrotestosterone in combination with testosterone propinonate.

Treatment of prepuberally castrated male rats with testosterone propionate (TP, 50, 200, 500, or 1000 μg for 30 days) in adulthood stimulated the display of both mounting behavior and lordosis behavior. No correlation between mounting and lordosis behavior could be detected at any TP dose level. Treatment of prepuberally castrated male rats with either 1 μg estradiol benzoate (EB) or 500 μg dihydrotestosterone (DHT) for 60 days stimulated the display of mounting behavior in three of eight and four of eight rats, respectively. Treatment with 200 μg TP for the last 30 days of rats receiving either EB or DHT for 60 days resulted in an abrupt onset on mounting behavior as compared to rats treated with oil for 60 days. These results show additive effects of EB or DHT and TP upon mounting behavior by male rats and are interpreted as a support for the suggestion that testosterone to estrogen as well as testosterone to DHT conversion may be involved in the mechanism whereby testosterone activates the mounting behavior of castrated rats.     

Male sexual behavior in deer mice (Peromyscus maniculatus) following castration and hormone replacement

Sexually experienced male deer mice (Peromyscus maniculatus bairdi) were castrated and tested for male sexual behavior. In the weeks following castration male sexual behavior decreased. Ejaculation disappeared first, followed by intromission and, finally, mounting. Castrated males failing to copulate were assigned to one of four treatment groups: 200 μg testosterone propionate (TP); 200 μg dihydrotestosterone propionate (DHTP); 2 μg estradiol benzoate (EB); or sesame oil (OIL). TP and DHTP were equally effective in restoring the complete male sexual behavior pattern. In contrast, EB was effective in stimulating mounting and minimally effective in stimulating intromissions (vaginal penetration), but did not stimulate ejaculatory responses. These data indicate that in deer mice testosterone may mediate male sexual behavior through reduction to dihydrotestosterone rather than through aromatization to estradiol.     

Sexual behavior in male rats treated with estrogen in combination with dihydrotestosterone

Male rats castrated at 30 days of age were treated with estradiol benzoate (dose range: 0.05–50 μg EB for 26 days) and dihydrotestosterone (1 mg DHT for 36 days) as adults. The combined EB and DHT treatments resulted in display of male sexual behavior which did not differ from the behavior shown by intact untreated males or castrated, testosterone propionate (1 mg TP for 26 days) treated males. EB alone or DHT alone were relatively ineffective in activating male behavior in castrated males.     

Mounting and receptive behavior in the ovariectomized female rat: Influence of estradiol,dihydrotestosterone, and genital anesthetization

Two experiments were performed with ovariectomized female rats in an attempt to determine whether estradiol and dihydrotestosterone work synergistically in the brain to activate mounting behavior. In Expt 1, performed in Göteborg, it was found that females treated daily with 2 μg estradiol benzoate (EB) combined with 500 μg dihydrotestosterone (DHT) displayed significantly more mounts with pelvic thrusting than other females treated with the oil vehicle, 500 μg DHT, or 2 μg EB. The behavior of rats receiving EB + DHT was indistinguishable from that of yet another group of females which received 200 μg testosterone propionate (TP). In Expt 2, performed in Rotterdam, it was found that ovariectomized female rats treated with either 200 μg TP or 2 μg EB + 200 μg dihydrotestosterone propionate (DHTP) mounted significantly more than females treated with 2 μg EB. Both clitoral size and the growth of cornified papillae on the glans clitoris were stimulated by the administration of TP or EB + DHTP. However, in no group was the frequency of mounting affected by anesthetization of the clitoris and external vagina with lidocaine paste. Lordosis quotients of females treated with EB + DHTP were significantly lower than in rats receiving either EB or TP, again regardless of whether or not the genital region was anesthetized. It is concluded that the effects of DHT on estradiol-induced mounting and receptivity most likely result from the action of this androgen on the brain, and not from the stimulatory effect which DHT may exert on genital sensory receptors.     

Induction of male mating behavior in androgen-insensitive (tfm) and Normal (King-Holtzman) male rats: effect of testosterone propionate, estradiol benzoate, and dihydrotestosterone

Castrated androgen-insensitive rats exhibited mounting and intromission patterns in response to testosterone propionate (TP), estradiol benzoate (EB), or EB combined with dihydrotestosterone (DHT) treatment in adulthood. Treatment with DHT alone was ineffective in stimulating male mating behavior in the mutant rats. Since androgen-insensitive rats, like normal males, have the potential to show mounting behavior following hormone treatment in adulthood, the neural substrate underlying this behavior must be masculinized during development. The effectiveness of gonadal hormones in activating the entire copulatory sequence in castrated littermate males (King-Holtzman) was also examined. TP treatment induced mating behavior in the control rats. DHT also stimulated the complete copulatory pattern, although it was not as effective as TP. The administration of EB, however, did not induce ejaculation in control rats. These results do not support the hypothesis that the activation of male mating behavior by testosterone requires its metabolite estrogen (aromatization hypothesis).     

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.     

Synergistic actions of estrogen and androgen on the sexual behavior of the castrated male rabbit.

Daily injections of 2.5 mg dihydrotestosterone (DHT) for 30 days induced sexual behavior in 19% of piepuberally and 62% of postpuberally castrated New Zealand white male rabbits. Combined treatment of 2.5 mgm DHT plus 5 μgm of estradiol benzoate (EB) activated sexual behavior in 100 and 85% of prepuberally and postpuberally castrated rabbits respectively. Moreover, subjects (Ss) receiving DHT + EB displayed sexual activity in a significantly higher percentage of tests and presented a higher frequency of mounts and intromissions than those Ss receiving only DHT. The results demonstrate that estrogen synergizes with androgen (DHT) to stimulate sexual behavior in the male rabbit.     

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.     

Testosterone implanted in the preoptic area of male Japanese quail must be aromatized to activate copulation

Intracranial implantation of minute pellets of gonadal steroids was combined with aromatase inhibitor treatment to determine if aromatization within the preoptic area (POA) is necessary for androgens to activate sexual behavior in the Japanese quail (Coturnix japonica). In this species, implantation of pellets of testosterone propionate (TP) or estradiol benzoate (EB) in the POA of castrated males restores male-typical copulatory behavior. In Experiment 1, adult male castrated quail were implanted intracranially with 200-micrograms pellets of equimolar mixtures of crystalline TP + cholesterol (CHOL), TP + 1,4,6-androstatriene-3,17-dione (ATD, an aromatase inhibitor), EB + ATD, or CHOL and behavior-tested with intact males and females. Copulation was stimulated by POA implants containing TP or EB (three of six CHOL + TP males and two of seven ATD + EB males copulated vs zero of four CHOL males), but copulation was not inhibited by combining ATD with TP (three of four ATD + TP males copulated). In Experiment 2, adult male castrated quail were injected systemically with ATD or oil for 6 days prior to and 14 days after intracranial implantation of 200-micrograms pellets containing the same amounts of TP or EB as in Experiment 1. The ATD injections completely blocked copulatory behavior in males with TP implants in the POA such that ATD/TP and Oil/TP mount frequencies differed significantly, but failed to block copulation in males with EB implants in the POA (proportions of males copulating were ATD/EB, 6/8; ATD/TP, 0/6; Oil/TP, 4/7). The cloacal foam gland, an androgen-sensitive secondary sex character, was unaffected by the dose of ATD used. We conclude that activation of copulatory behavior by TP implants in the POA is not due to nonspecific effects of high local testosterone concentrations but rather to aromatization. These results support the hypothesis that cells within the POA aromatize testosterone to estrogens, which directly stimulate the cellular processes leading to activation of male-typical copulatory behavior.     

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.     

A comparison of the effects of methyltrienolone (R 1881) and 5 alpha-dihydrotestosterone on sexual behavior of castrated male rats.

The synthetic steroid methyltrienolone (R 1881) binds specifically with high affinity to intracellular androgen receptors and is not metabolized to androstanediol. Administration of R 1881 (1 mg/day) to castrated male rats facilitated intromission in significantly more animals than did 5α-dihydrotestosterone (DHT) (1 mg/day); however, the percentage of animals ejaculating and the pattern of behavior displayed were equivalent in the two groups. Combined administration of estradiol benzoate (EB) (2 μg/day) plus either R 1881 or DHT further facilitated males' sexual performance to levels previously seen in castrated male rats of the same strain when given testosterone propionate (TP). The results suggest that conversion of DHT to 3α- or 3β-androstanediol neither detracts from nor contributes to its ability to activate sexual behavior in the male rat.     

Influence of androgen in the neonatal period on ejaculatory and postejaculatory behavior in the rat

The objective of the present report was to investigate the influence of androgen in the neonatal period on the development of ejaculatory and postejaculatory behavior. At birth, male rats were either castrated (neonatally castrated males), implanted with a Silastic tube of the aromatase inhibitor androsta-1,4,6-triene-3,17-dione for the first 10 days (ATD males), or left untreated (normal males). Female rats were either injected with 0.5 mg testosterone propionate (TP) on Days 1 (day of birth) and 2 (androgenized females) or left untreated (normal females). All gonadally intact animals were castrated at 60 days of age. Following TP administration, all animals were tested for ejaculatory and postejaculatory behavior under both shock and nonshock conditions. All animals were capable of showing the intromission pattern; however, the ejaculatory pattern was exhibited regularly only by those animals exposed to androgen at birth (normal males, androgenized females, and ATD males). The normal males required fewer intromissions to achieve ejaculation than the other two groups exhibiting this reflex. This result is discussed in terms of peripheral genital stimulation deficits and the differentiation of neural tissue responsible for masculine copulatory behavior. Androgenized females and ATD males displayed a refractory period, characterized by 22-kHz vocalizations, equal to or longer than that found in normal males. These results indicate that defeminization is not necessary for the display of normal ejaculatory and postejaculatory behavior.     

Regulation of urine marking in male and female mice: effects of sex steroids

Effects of sex steroids on urine-marking activity were studied in male, female, and neonatally androgenized female mice. Urine marking was estimated by suspending ceramic tubes that were connected in a horizontal row with a steel rod into the home cage of an isolated mouse. Intact males showed high marking activity, which was diminished after castration. Both testosterone propionate (TP) and estradiol benzoate (EB) were effective in restoring the marking activity of castrated males, while 5-alpha-dihydrotesterone (DHT) did not have any stimulative effects. Intact normal females showed quite low marking activity and ovariectomy further depressed it. TP and DHT enhanced the marking of ovariectomized females, but EB restored the activity only to the preovariectomy level. In intact females which were neonatally androgenized, the marking activity was much higher than that of normal females. The pattern of the change induced by gonadectomy and hormone treatment in these females resembled that in males. Thus, ovariectomy reduced the activity and both TP and EB restored the level. These results indicate that the sexual dimorphism in the urine marking in mice is primarily determined by hormonal environment during early postnatal age. Hormonal control of scent marking is discussed in relation to the studies in other rodents.     

A single injection of 17 beta-estradiol facilitates sexual behavior in castrated male mice

Sexual behavior was assessed in castrated adult CD-1 male mice given exogenous steroids under various treatment regimens. Castrated mice maintained on 20 μg testosterone (T) daily for 1 week, but given 250 μg testosterone propionate (TP) on the day of testing showed higher levels of copulatory activity than intact mice or the males receiving an additional dose of 20 μg T on the test day, although plasma testosterone levels were not different at the time of behavioral testing. Castrated males given 50, 125, or 250 μg TP for 1 week including the day of testing showed higher levels of sexual behavior than males receiving the same doses of TP only once, on the test day. A single injection of 17β-estradiol (E₂) completely restored the male copulatory pattern, including ejaculation, in castrated mice under every condition examined. Testosterone and dihydrotestosterone (DHT) were less effective than E₂, as was the combination of E₂ and DHT. The relative efficacy of a single dose of T, DHT, and E₂ plus DHT was dependent upon factors such as the delay between steroid administration and testing, as well as whether or not the castrated mice received androgen replacement prior to testing. Estradiol benzoate (E₂B) was not capable of restoring sexual behavior in castrated mice in this study. The comparison of results obtained with TP, T, E₂, and E₂B suggests that an appreciable, but not necessarily sustained, elevation of E₂ levels in the brain may be critical in the facilitation of male copulatory behavior in mice.     

Regulation of Noncontact Erection in Rats by Gonadal Steroids

Male rats exhibit erections in the presence of inaccessible estrous females, and we investigated which gonadal steroids regulate these noncontact erections (NCEs). Sexually experienced Wistar males (n >/= 8/group) were tested for NCE four times (every 3 days) before castration, after castration, and after receiving subcutaneous implants of 10-mm Silastic capsules that were empty or filled with crystalline testosterone propionate (TP), dihydrotestosterone (DHT), estradiol benzoate (EB), or DHT + EB (10 mm each). Before castration, males responded with NCE in approximately 50% of tests. No males had NCEs after castration, beginning 3 days after surgery. Also, no males responded after treatment with EB or empty capsules. After receiving implants of TP, DHT, or DHT + EB, 50% of males had NCEs, beginning with the first test 3 days after treatment. On every measure of NCE, males treated with DHT or DHT + EB were indistinguishable from each other and from TP-treated males. Among the sexual responses of male rats, NCE appears to be more sensitive than other behaviors to changes in gonadal condition. In its profile of response to gonadal steroids (testosterone+, dihydrotestosterone+, estradiol-), NCE is similar to reflexive erection, for which spinal systems are sufficient, and unlike copulation (T+, DHT-, E+), which depends on discrete areas of the brain. We nonetheless conclude that NCE depends on androgen-sensitive systems in the brain, but androgen-sensitive neurons in the lumbosacral spinal cord may also play a role.     

Androgen- and estrogen-induced copulatory behavior and inhibition of luteinizing hormone (LH) secretion in the male rat

The purpose of the present investigation was to determine if estrogen, aromatizable androgen or nonaromatizable androgen is capable of (1) inducing copulatory behavior and (2) inhibiting the postcastration rise in plasma LH. Castrate male rats were injected daily with either 1 mg testosterone (T), androstenedione (A), dihydrotestosterone (DHT), or 25 μg estradiol benzoate (EB) or oil and tested weekly for masculine behavior and for lordosis behavior after 38 days of steroid treatment. On day 40 blood was collected for radioimmunoassay of plasma LH. At least 89% of the males treated with T, A, or EB and 55% of those treated with DHT displayed ejaculatory behavior whereas none of the oil-treated males showed male copulatory behavior. Only estrogen-treated males displayed lordosis behavior. T and to a lesser extent A treatment reduced high levels of plasma LH; however, DHT and EB further reduced plasma LH to undectable levels. The relative potency of the steroid effect in stimulating accessory sex tissues followed the order: DHT > T > A > EB = oil. Significant dissociation was observed between the effects of these steroids on peripheral morphology, negative feedback, and mating behavior. These results indicate that masculine behavior is facilitated to the greatest extent, although not exclusively, by centrally acting aromatizable androgen or estrogen, whereas under the present conditions only estrogen stimulates feminine behavior.     

Embryonic and posthatching treatments with sex steroids demasculinize the motivational aspects of crowing behavior in male Japanese quail

Demasculinizing action of embryonic estrogen on crowing behavior in male Japanese quails was examined. Eggs were treated with either 20 μg of estradiol benzoate (EB) or vehicle on the 10th day of incubation. Chicks hatched from both groups of eggs were injected daily with either testosterone propionate (TP; 10 μg/g b.w.), 5α-dihydrotestosterone (DHT, a non-aromatizable androgen; 10 μg/g b.w.), or vehicle from 11 to 50 days after hatching, and during this period their calling behaviors were observed. Irrespective of embryonic treatments, all birds received posthatching treatment with either TP or DHT, but not with vehicle, emitted crows in place of distress calls in a stress (non-sexual) context of being isolated in a recording chamber. The posthatching TP, but not posthatching DHT, induced crowing in a sexual context (crowing in their home-cages) from much earlier age than posthatching vehicle in the birds received control embryonic treatment with vehicle. The same TP treatment, however, completely eliminated the crowing in a sexual context in the birds received EB during their embryonic life. In the birds treated with either posthatching DHT or posthatching vehicle, the crowing in a sexual context was only slightly decreased by embryonic EB treatment. These data suggest that posthatching estrogen, derived from testosterone aromatization, enhances the demasculinizing action of embryonic estrogen, and thus strongly reduces the sexual motivation for crowing behavior. This demasculinizing action, however, would not influence vocal control system which generates acoustic pattern of crowing in the presence of androgens allowing the birds to crow in a non-sexual context.     

The effects of the antiestrogen CI-628 on sexual behavior activated by androgen or estrogen in quail

This series of experiments sought to determine whether conversion of androgen to estrogen is important in the activation of male sexual behavior in quail by seeing if an antiestrogen will block androgen stimulated copulation in this species. Experiment I compared the ability of two antiestrogens, MER-25 (5 mg/day) and CI-628 (2 mg/day), to block estrogen stimulated characteristics in female quail. Both treatments greatly reduced oviduct growth in “photically castrated” females given estradiol benzoate (EB, 50 μg/day), but only CI-628 reduced receptivity in these birds. In Experiment II surgically castrated males given 50 μg/day EB together with 2 mg/day CI-628 were much less receptive than castrated males given EB alone, and in addition copulated in fewer tests. In Experiments III, IV, and V, castrated males given testosterone propionate (TP) together with CI-628 were compared with males given TP alone. The ability of CI-628 to suppress TP-stimulated copulation increased with increasing CI/TP dosage ratio, and at the highest ratio (4:1), CI-628 effectively blocked copulation in five out of seven birds. Those birds that did copulate did so in fewer tests and performed fewer cloacal contact movements. CI-628 had no antiandrogenic effects in these experiments. These results suggest that estrogens may be important active metabolites of testosterone with respect to quail copulation.     

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.     

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.