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

Androgen receptors and sociosexual behaviors in mammals: The limits of generalization

Circulating testosterone is easily aromatized to estradiol and reduced to dihydrotestosterone in target tissues and elsewhere in the body. Thus, the actions of testosterone can be mediated either by the estrogen receptors, the androgen receptor or by simultaneous action at both receptors. To determine the role of androgens acting at the androgen receptor, we need to eliminate actions at the estrogen receptors. Alternatively, actions at the androgen receptor itself can be eliminated. In the present review, I will analyze the specific role of androgen receptors in male and female sexual behavior as well as in aggression. Some comments about androgen receptors and social recognition are also made. It will be shown that there are important differences between species, even between strains within a species, concerning the actions of the androgen receptor on the behaviors mentioned. This fact makes generalizations from one species to another or from one strain to another very risky. The existence of important species differences is often ignored, leading to many misunderstandings and much confusion.

Kisspeptin neurons as a key player bridging the endocrine system and sexual behavior in mammals

Reproductive behaviors are sexually differentiated: for example, male rodents show mounting behavior, while females in estrus show lordosis behavior as sex-specific sexual behaviors. Kisspeptin neurons govern reproductive function via direct stimulation of gonadotropin-releasing hormone (GnRH) and subsequent gonadotropin release for gonadal steroidogenesis in mammals. First, we discuss the role of hypothalamic kisspeptin neurons as an indispensable regulator of sexual behavior by stimulating the synthesis of gonadal steroids, which exert "activational effects" on the behavior in adulthood. Second, we discuss the central role of kisspeptin neurons that are directly involved in neural circuits controlling sexual behavior in adulthood. We then focused on the role of perinatal hypothalamic kisspeptin neurons in the induction of perinatal testosterone secretion for its "organizational effects" on masculinization/defeminization of the male brain in rodents during a critical period. We subsequently concluded that kisspeptin neurons are key players in bridging the endocrine system and sexual behavior in mammals.

Neonatal Kisspeptin is Steroid-Independently Required for Defeminisation and Peripubertal Kisspeptin-Induced Testosterone is Required for Masculinisation of the Brain: A Behavioural Study Using Kiss1 Knockout Rats

Rodents show apparent sex differences in their sexual behaviours. The present study used Kiss1 knockout (KO) rats to evaluate the role of kisspeptin in the defeminisation/masculinisation of the brain mechanism that controls sexual behaviours. Castrated adult Kiss1 KO males treated with testosterone showed no male sexual behaviours but demonstrated the oestrogen-induced lordosis behaviours found in wild-type females. The sizes of some of the sexual dimorphic nuclei of Kiss1 KO male rats are similar to those of females. Plasma testosterone levels at embryonic day 18 and postnatal day 0 (PND0) in Kiss1 KO males were high, similar to wild-type males, indicating that perinatal testosterone is secreted in a kisspeptin-independent manner. Long-term exposure to testosterone from peripubertal to adult periods restored mounts and intromissions in KO males, suggesting that kisspeptin-dependent peripubertal testosterone secretion is required to masculinise the brain mechanism. This long-term testosterone treatment failed to abolish lordosis behaviours in KO males, whereas kisspeptin replacement at PND0 reduced lordosis quotients in Kiss1 KO males but not in KO females. These results suggest that kisspeptin itself is required to defeminise behaviour in the perinatal period, in cooperation with testosterone. Oestradiol benzoate treatment at PND0 suppressed lordosis quotients in Kiss1 KO rats, indicating that the mechanisms downstream of oestradiol work properly in the absence of kisspeptin. There was no significant difference in aromatase gene expression in the whole hypothalamus between Kiss1 KO and wild-type male rats at PND0. Taken together, the present study demonstrates that both perinatal kisspeptin and kisspeptin-independent testosterone are required for defeminisation of the brain, whereas kisspeptin-dependent testosterone during peripuberty to adulthood is needed for masculinisation of the brain in male rats.

The Effects of a Single Developmentally Entrained Pulse of Testosterone in Female Neonatal Mice on Reproductive and Metabolic Functions in Adult Life

Early postnatal exposures to sex steroids have been well recognized to modulate predisposition to diseases of adulthood. There is a complex interplay between timing, duration and dose of endocrine exposures through environmental or dietary sources that may alter the sensitivity of target tissues to the exogenous stimuli. In this study, we determined the metabolic and reproductive programming effects of a single developmentally entrained pulse of testosterone (T) given to female mice in early postnatal period. CD-1 female mice pups were injected with either 5 μg of T enanthate (TE) or vehicle (control [CON] group) within 24 hours after birth and followed to adult age. A total of 66% of T-treated mice exhibited irregular cycling, anovulatory phenotype, and significantly higher ovarian weights than vehicle-treated mice. Longitudinal nuclear magnetic resonance measurements revealed that TE group had greater body weight, whole-body lean, and fat mass than the CON group. Adipose tissue cellularity analysis in TE group revealed a trend toward higher size and number than their littermate CONs. The brown adipose tissue of TE mice exhibited white fat infiltration with down-regulation of several markers, including uncoupling protein 1 (UCP-1), cell death-inducing DNA fragmentation factor, α-subunit-like effector A, bone morphogenetic protein 7 as well as brown adipose tissue differentiation-related transcription regulators. T-injected mice were also more insulin resistant than CON mice. These reproductive and metabolic reprogramming effects were not observed in animals exposed to TE at 3 and 6 weeks of age. Collectively, these data suggest that sustained reproductive and metabolic alterations may result in female mice from a transient exposure to T during a narrow postnatal developmental window.

The androgen receptor in health and disease

Androgens play pivotal roles in the regulation of male development and physiological processes, particularly in the male reproductive system. Most biological effects of androgens are mediated by the action of nuclear androgen receptor (AR). AR acts as a master regulator of downstream androgen-dependent signaling pathway networks. This ligand-dependent transcriptional factor modulates gene expression through the recruitment of various coregulator complexes, the induction of chromatin reorganization, and epigenetic histone modifications at target genomic loci. Dysregulation of androgen/AR signaling perturbs normal reproductive development and accounts for a wide range of pathological conditions such as androgen-insensitive syndrome, prostate cancer, and spinal bulbar muscular atrophy. In this review we summarize recent advances in understanding of the epigenetic mechanisms of AR action as well as newly recognized aspects of AR-mediated androgen signaling in both men and women. In addition, we offer a perspective on the use of animal genetic model systems aimed at eventually developing novel therapeutic AR ligands.

How to make a sexy snake: estrogen activation of female sex pheromone in male red-sided garter snakes

Vertebrates indicate their genetic sex to conspecifics using secondary sexual signals, and signal expression is often activated by sex hormones. Among vertebrate signaling modalities, the least is known about how hormones influence chemical signaling. Our study species, the red-sided garter snake (Thamnophis sirtalis parietalis), is a model vertebrate for studying hormonal control of chemical signals because males completely rely on the female sex pheromone to identify potential mates among thousands of individuals. How sex hormones can influence the expression of this crucial sexual signal is largely unknown. We created two groups of experimental males for the first experiment: Sham (blank implants) and E2 (17β-estradiol implants). E2 males were vigorously courted by wild males in outdoor bioassays, and in a Y-maze E2 pheromone trails were chosen by wild males over those of small females and were indistinguishable from large female trails. Biochemically, the E2 pheromone blend was similar to that of large females, and it differed significantly from Shams. For the second experiment, we implanted males with 17β-estradiol in 2007 but removed the implants the following year (2008; Removal). That same year, we implanted a new group of males with estrogen implants (Implant). Removal males were courted by wild males in 2008 (implant intact) but not in 2009 (removed). Total pheromone quantity and quality increased following estrogen treatment, and estrogen removal re-established male-typical pheromone blends. Thus, we have shown that estrogen activates the production of female pheromone in adult red-sided garter snakes. This is the first known study to quantify both behavioral and biochemical responses in chemical signaling following sex steroid treatment of reptiles in the activation/organization context. We propose that the homogametic sex (ZZ, male) may possess the same targets for activation of sexual signal production, and the absence of the activator (17β-estradiol in this case) underlies expression of the male phenotype.

Prenatal endocrine influences on sexual orientation and on sexually differentiated childhood behavior

Both sexual orientation and sex-typical childhood behaviors, such as toy, playmate and activity preferences, show substantial sex differences, as well as substantial variability within each sex. In other species, behaviors that show sex differences are typically influenced by exposure to gonadal steroids, particularly testosterone and its metabolites, during early development (prenatally or neonatally). This article reviews the evidence regarding prenatal influences of gonadal steroids on human sexual orientation, as well as sex-typed childhood behaviors that predict subsequent sexual orientation. The evidence supports a role for prenatal testosterone exposure in the development of sex-typed interests in childhood, as well as in sexual orientation in later life, at least for some individuals. It appears, however, that other factors, in addition to hormones, play an important role in determining sexual orientation. These factors have not been well-characterized, but possibilities include direct genetic effects, and effects of maternal factors during pregnancy. Although a role for hormones during early development has been established, it also appears that there may be multiple pathways to a given sexual orientation outcome and some of these pathways may not involve hormones.

Effects of prenatal androgens on rhesus monkeys: a model system to explore the organizational hypothesis in primates

After proposing the organizational hypothesis from research in prenatally androgenized guinea pigs (Phoenix, C.H., Goy, R.W., Gerall, A.A., Young, W.C., 1959. Organizational action of prenatally administered testosterone propionate on the tissues mediating mating behavior in the female guinea pig. Endocrinology 65, 369-382.), the same authors almost immediately extended the hypothesis to a nonhuman primate model, the rhesus monkey. Studies over the last 50 years have verified that prenatal androgens have permanent effects in rhesus monkeys on the neural circuits that underlie sexually dimorphic behaviors. These behaviors include both sexual and social behaviors, all of which are also influenced by social experience. Many juvenile behaviors such as play, mounting, and vocal behaviors are masculinized and/or defeminized, and aspects of adult sexual behavior are both masculinized (e.g. approaches, sex contacts, and mounts) and defeminized (e.g. sexual solicits). Different behavioral endpoints have different periods of maximal susceptibility to the organizing actions of prenatal androgens. Aromatization is not important, as both testosterone and dihydrotestosterone are equally effective in rhesus monkeys. Although the full story of the effects of prenatal androgens on sexual and social behaviors in the rhesus monkey has not yet completely unfolded, much progress has been made. Amazingly, a large number of the inferences drawn from the original 1959 study have proved applicable to this nonhuman primate model.

The control of sexual differentiation of the reproductive system and brain

This review summarizes current knowledge of the genetic and hormonal control of sexual differentiation of the reproductive system, brain and brain function. While the chromosomal regulation of sexual differentiation has been understood for over 60 years, the genes involved and their actions on the reproductive system and brain are still under investigation. In 1990, the predicted testicular determining factor was shown to be theSRYgene. However, this discovery has not been followed up by elucidation of the actions of SRY, which may either stimulate a cascade of downstream genes, or inhibit a suppressor gene. The number of other genes known to be involved in sexual differentiation is increasing and the way in which they may interact is discussed. The hormonal control of sexual differentiation is well-established in rodents, in which prenatal androgens masculinize the reproductive tract and perinatal oestradiol (derived from testosterone) masculinizes the brain. In humans, genetic mutations have revealed that it is probably prenatal testosterone that masculinizes both the reproductive system and the brain. Sexual differentiation of brain structures and the way in which steroids induce this differentiation, is an active research area. The multiplicity of steroid actions, which may be specific to individual cell types, demonstrates how a single hormonal regulator, e.g. oestradiol, can exert different and even opposite actions at different sites. This complexity is enhanced by the involvement of neurotransmitters as mediators of steroid hormone actions. In view of current environmental concerns, a brief summary of the effects of endocrine disruptors on sexual differentiation is presented.

Prenatal dihydrotestosterone differentially masculinizes tonic and surge modes of luteinizing hormone secretion in sheep

The control of LH secretion in sheep is sexually differentiated. Males begin to reduce their sensitivity to inhibitory steroid feedback, leading to a pubertal increase in tonic LH secretion by 10 weeks of age, but females remain hypersensitive until 30 weeks. Moreover, only females can respond to the positive feedback action of estradiol to produce a preovulatory LH surge. Prenatal exposure of the female lamb to testosterone masculinizes tonic LH and abolishes the LH surge postnatally. However, the type of steroid involved is not known because testosterone can be converted to estradiol or dihydrotestosterone (DHT). This study tested the hypothesis that DHT, which cannot be converted to an estrogen, masculinizes tonic LH without defeminizing the LH surge. Pregnant ewes were treated with DHT (800, 400, or 200 mg/week) during the critical period for sexual differentiation of gonadotropin secretion (days 30-90; 145 days is term). To evaluate the time of the decrease in responsiveness to steroid inhibition, a constant steroid feedback signal was produced. At 4 weeks of age, androgenized females (800 mg, n = 5; 400 mg, n = 4; 200 mg, n = 5) and control males (n = 7) and females (n = 9) were gonadectomized and implanted with a SILASTIC brand estradiol capsule. Tonic LH secretion in males began to increase at 6.7 +/- 0.5 weeks (mean +/- SEM). In DHT-treated females, the LH increase began at the same time (800 mg DHT, 10.7 +/- 3.9 weeks; 400 mg DHT, 9.9 +/- 5.9 weeks; 200 mg DHT, 7.1 +/- 4.9 weeks). This was several months earlier than in control females (29.1 +/- 0.8 weeks; P < 0.05). After puberty, estradiol induced LH surges in 8 of 9 control females and 11 of 12 DHT-treated females, but not in any control males. These results lead to the hypothesis that in the sheep, distinct requirements exist for differentiation of 2 types of reproductive hormone control systems, and that conversion of testosterone to an estrogen is not essential for both. Aromatization is necessary to prevent the surge control of GnRH from operating in the male, but nonaromatizable androgens differentiate the tonic control to permit high GnRH secretion earlier in life.

Prenatal hormones organize sex differences of the neuroendocrine reproductive system: observations on guinea pigs and nonhuman primates

1. The central nervous systems (CNS) of males and females differ in the control mechanisms for the release of gonadotropins from the anterior pituitary gland as well as the capacity to display sex specific behaviors. 2. In guinea pigs and monkeys, these differences are organized through the actions of prenatal androgens secreted by the fetal testes. In both males and females androgen receptors have been identified within the brain during the period in development in which organization of the CNS occurs. Sex differences between the ratio of cytosolic and nuclear androgen receptors are due to the amount of endogenous androgen present in the circulation of the developing fetus. Thus, at least part of the biochemical machinery necessary for androgen action resides in the CNS during the period of sexual differentiation. 3. In addition to the physiological differences that have been observed, morphological differences that are androgen dependent have been found in the medial preoptic nucleus and the bed nucleus of the stria terminalis of the guinea pig. The location of these sex differences in brain morphology coincides roughly with the location of steroid binding neurons. 4. In some species the in situ conversion of testosterone to dihydrotestosterone (DHT) by the 5 alpha-reductases or to estradiol-17 beta by cytochrome P450 aromatase mediates testosterone's action. The gonadotropin surge mechanism of adult guinea pigs exposed to a 5a-reductase inhibitor in utero during the critical period for sexual differentiation was unaffected in either males or females even though the development of the external organs of reproduction of males was feminized by the treatment. Likewise, the gonadotropin surge mechanism of subjects exposed to an aromatase inhibitor in utero during the critical period for sexual differentiation was unaffected by this treatment. 5. The mechanism controlling negative feedback, however, was affected in both males and females. Subjects that were exposed to an aromatase inhibitor while developing in utero could not respond to the negative feedback actions of estrogen on gonadotropin release in adulthood. 6. The surge mechanism for the control of gonadotropin secretion in nonhuman primates is not sexually differentiated as it is in rodents. Castrated male monkeys release surge amounts of LH in response to an estrogen challenge. Both infant and adult dimorphic behaviors of rhesus monkeys are organized by the prenatal actions of androgen.

Co-localization of androgen receptor and nitric oxide synthase in the ventral premammillary nucleus of the newborn rat: an immunohistochemical study

The distribution of the neuronal nitric oxide synthase (nNOS), androgen receptor (AR), estrogen receptor (ER) and aromatase (ARO) was studied in the dorsal and ventral premammillary nuclei (PMd and PMv) of the newborn rat by immunohistochemistry. In the intact male pups, nNOS immunoreactivity (-IR) was present both in the PMd and the PMv, while AR-IR was detected only in the PMv. On the other hand, ER-IR and ARO-IR were scarcely encountered in the both PMd and PMv. By double immunostaining of nNOS and AR, all the nNOS-IR cells in the PMv were revealed to contain AR-IR. In the intact female pups, nNOS-IR was present in the both PMd and PMv, but neither ER-, nor ARO-IR were detected in the PM region. In the PMv of the intact female rat, no AR-IR was detected at 6 days of age, while it was detected as only a faint staining within 12 h after birth. When the male pups were castrated neonatally, no AR-IR was detected in the PMv. Subcutaneous injections of 5alpha-dihydrotestosterone (DHT) induced strong AR-IR in the castrated male and the intact female pups. On the contrary, the intensity of nNOS-IR stayed unchanged among these animals. Neonatal androgen and nitric oxide has been considered important to brain development. Moreover, involvement of the PMv in aggressive and mating behavior of male animals has been reported. Together with the fact that the AR-IR and nNOS-IR were found in the same neurons in the PMv, involvement of this nucleus in masculinization of the brain by non-aromatizable androgen is postulated.

Effects of prenatal testosterone and ATD on reproductive behavior in guinea pigs

Most sexual dimorphisms in reproductive behavior are hormonally organized in the guinea pig. The study sought to determine whether the sexually dimorphic requirement for the aromatization of testosterone in the activation of mounting is organized by testosterone prenatally and whether aromatization of testosterone contributes to the organization of mounting behavior. Pregnant females were treated with testosterone, the aromatase inhibitor ATD, or vehicle from days 28-65 of gestation. The offspring were gonadectomized and tested as adults for lordosis and androgen-activated mounting behavior. Prenatal testosterone treatments altered the hormonal requirements for androgen-activated mounting in females such that they resembled normal males, and did not require aromatization as adults. Prenatal inhibition of aromatase activity decreased mounting activity in females but not in males. This treatment had no influence on lordosis in either sex. The results support the hypothesis that the same hormones that activate mounting behavior in the adult guinea pig are responsible for the organization of mounting behavior.

Lordosis behavior in males of two inbred strains of guinea pig

The lordosis behavior of male guinea pigs from inbred strains 2 and 13 was examined. Significantly more isolated gonadally intact males of strain 2 than strain 13 displayed lordosis. Castration did not decrease the display of lordosis. In castrated strain 2 males, those which showed lordosis did not have higher plasma androgen, estrone or estradiol levels than those which did not show lordosis. They also did not differ hormonally from ovariectomized strain 2 females even though strain 2 females never showed lordosis without hormone replacement. Although the lordosis shown by strain 2 males was not related to endogenous gonadal hormone levels, estradiol benzoate (EB) administration facilitated lordosis. EB had no clear effect on lordosis in strain 13 males. Progesterone after EB priming had no further facilitative effect in males of either strain. These results indicate that lordosis is more readily elicited from strain 2 than strain 13 males. Furthermore, lordosis in strain 2 males is not dependent upon gonadal hormones for its display although it is facilitated by EB (but not progesterone).

Female-typical sexual behavior of rhesus and defeminization by androgens given prenatally

Adult rhesus monkeys were observed in standardized tests for female-typical sexual and related social responses. In the first experiment reported, 7 castrated males and 5 spayed females were paired with each of 4 intact males on two occasions following intramuscular injection with estradiol benzoate (EB) (6 micrograms/kg X 14 days) and on two other occasions without such treatment. In tests without EB, males and females did not behave differently toward the intact male partners, and all responses were displayed at low frequencies. In tests with EB, females showed reliably higher frequencies than males of approaching, sitting close to, grooming, and soliciting, and they presented to a higher proportion of the male partner's sexual contacts. EB reliably increased the frequency of display of all of these same five responses in females but not in castrated males. The intact male partners displayed reliably fewer approaches, sexual contacts, mounts, intromissions, and ejaculations to castrated males than to spayed females regardless of estrogenization. In a second experiment 10 intact adult pseudohermaphroditic females and 6 intact control females were tested following EB injections with each of the same 4 intact males. Pseudohermaphrodites were experimentally produced by injecting pregnant females with either testosterone propionate (TP) or dihydrotestosterone propionate (DHTP). Pseudohermaphrodites, regardless of type of androgen used in their production, showed reliably fewer solicits than controls to male partners. Moreover, they displayed most of the other responses at lower average frequencies than controls. Frequencies of intromission and ejaculation by intact male partners were reliably lower with pseudohermaphrodites than with control females, but frequencies of approach, sexual contact, and mount were not reliably different. We conclude that in this testing and measurement situation male and female rhesus monkeys differ markedly in the degree of expression of female-typical sexual behaviors, and genotypic males are behaviorally less responsive to estrogens than females. Exposing genotypic females to androgens during fetal life decreases the expression of female-typical, estrogen-influenced responses, and the effect is most pronounced on those soliciting responses that subserve proceptivity.

Differentiation of coital behavior in mammals: a comparative analysis

The evidence reviewed suggests that in all mammalian species the adult male's ability to display masculine coital behavior depends in part on exposure of the developing brain to testicular testosterone or its metabolites. In many mammals, particularly rodents, ruminants, and some carnivores, perinatal exposure to androgen also causes behavioral defeminization, i.e., reduced capacity to display typically feminine coital behavior in response to gonadal hormones in adulthood. The data reviewed suggest that no such process occurs in certain other mammalian species, including ferret, rhesus monkey, marmoset, and man. Testicular androgen may cause behavioral defeminization only in those species in which expression of feminine sexual behavior normally depends on the neural action of progesterone, acting synergistically with estradiol; new data support this claim in the ferret. The possible contribution of estrogenic and 5 alpha-reduced androgenic metabolites of testosterone to the occurrence of behavioral masculinization and defeminization is considered in those mammalian species for which data are available.