Effects of testosterone, dihydrotestosterone, or estradiol administered neonatally on sexual behavior of female ferrets

Genetics and Epigenetics of the X and Y Chromosomes in the Sexual Differentiation of the Brain

For many decades to date, neuroendocrinologists have delved into the key contribution of gonadal hormones to the generation of sex differences in the developing brain and the expression of sex-specific physiological and behavioral phenotypes in adulthood. However, it was not until recent years that the role of sex chromosomes in the matter started to be seriously explored and unveiled beyond gonadal determination. Now we know that the divergent evolutionary process suffered by X and Y chromosomes has determined that they now encode mostly dissimilar genetic information and are subject to different epigenetic regulations, characteristics that together contribute to generate sex differences between XX and XY cells/individuals from the zygote throughout life. Here we will review and discuss relevant data showing how particular X- and Y-linked genes and epigenetic mechanisms controlling their expression and inheritance are involved, along with or independently of gonadal hormones, in the generation of sex differences in the brain.

The baubellum is more developmentally and evolutionarily labile than the baculum

Understanding the evolutionary forces that influence sexual dimorphism is a fundamental goal in biology. Here, we focus on one particularly extreme example of sexual dimorphism. Many mammal species possess a bone in their penis called a baculum. The female equivalent of this bone is called the baubellum and occurs in the clitoris, which is developmentally homologous to the male penis. To understand the potential linkage between these two structures, we scored baculum/baubellum presence/absence across 163 species and analyzed their distribution in a phylogenetic framework. The majority of species (N = 134) shared the same state in males and females (both baculum and baubellum present or absent). However, the baubellum has experienced significantly more transitions, and more recent transitions, so that the remaining 29 species have a baculum but not a well-developed baubellum. Even in species where both bones are present, the baubellum shows more ontogenetic variability and harbors more morphological variation than the baculum. Our study demonstrates that the baculum and baubellum are generally correlated across mammals, but that the baubellum is more evolutionarily and developmentally labile than the baculum. The accumulation of more evolutionary transitions, especially losses in the baubellum, as well as noisier developmental patterns, suggests that the baubellum may be nonfunctional, and lost over time.

Epigenetic setting for long-term expression of estrogen receptor α and androgen receptor in cells

Epigenetic regulation of the nuclear estrogen and androgen receptors, ER and AR, constitutes the molecular basis for the long-lasting effects of sex steroids on gene expression in cells. The effects prevail at hundreds of gene loci in the proximity of estrogen- and androgen-responsive elements and many more such loci through intra- and even inter-chromosomal level regulation. Such a memory system should be active in a flexible manner during the early development of vertebrates, and later replaced to establish more stable marks on genomic DNA. In mammals, DNA methylation is utilized as a very stable mark for silencing of the ERα and AR isoform expression during cancer cell and normal brain development. The factors affecting the DNA methylation of the ERα and AR genes in cells include estrogen and androgen. Since testosterone induces brain masculinization through its aromatization to estradiol in a narrow time window of the perinatal stage in rodents, the autoregulation of estrogen receptors, especially the predominant form of ERα, at the level of DNA methylation to set up the "cell memory" affecting the sexually differentiated status of brain function has been attracting increasing attention. The alternative usage of the androgen-AR system for brain masculinization and estrogenic regulation of AR expression in some species imply that the DNA methylation pattern of the AR gene can be established by closely related but different systems for sex steroid-induced phenomena, including brain masculinization.

Sexual differentiation of pheromone processing: links to male-typical mating behavior and partner preference

Phoenix et al. (Phoenix, C., Goy, R., Gerall, A., Young, W., 1959. Organizing actions of prenatally administered testosterone propionate on the tissues mediating mating behavior in the female guinea pig. Endocrinology 65, 369-382.) were the first to propose an essential role of fetal testosterone exposure in the sexual differentiation of the capacity of mammals to display male-typical mating behavior. In one experiment control male and female guinea pigs as well as females given fetal testosterone actually showed equivalent levels of mounting behavior when gonadectomized and given ovarian steroids prior to adult tests with a stimulus female. This finding is discussed in the context of a recent, high-profile paper by Kimchi et al. (Kimchi, T., Xu, J., Dulac, C., 2007. A functional circuit underlying male sexual behaviour in the female mouse brain. Nature 448, 1009-1014.) arguing that female rodents possess the circuits that control the expression of male-typical mating behavior and that their function is normally suppressed in this sex by pheromonal inputs that are processed via the vomeronasal organ (VNO)-accessory olfactory nervous system. In another Phoenix et al. experiment, significantly more mounting behavior was observed in male guinea pigs and in females given fetal testosterone than in control females following adult gonadectomy and treatment with testosterone. Literature is reviewed that attempts to link sex differences in the anatomy and function of the accessory versus the main olfactory projections to the amygdala and hypothalamus to parallel sex differences in courtship behaviors, including sex partner preference, as well as the capacity to display mounting behavior.

Roles of estrogen receptors α and β in differentiation of mouse sexual behavior

Sex differences in brain and behavior are ubiquitous in sexually reproducing species. Developmental differences in circulating concentrations of gonadal steroids underlie many sexual dimorphisms. During the late embryonic and early perinatal periods, the testes produce androgens, thus, male brains are exposed to testosterone, and in situ testosterone is aromatized to estradiol. In contrast, females are not exposed to high concentrations of testosterone or estradiol until puberty. In many species, neural sex differences and sexually dimorphic behaviors in adults are initiated primarily by estradiol exposure during early development. In brain, estradiol activates two independent processes: masculinization of neural circuits and networks that are essential for expression of male-typical adult behaviors, and defeminization, the loss of the ability to display adult female-typical behaviors. Here, data for the roles of each of the known estrogen receptors (estrogen receptor alpha and estrogen receptor beta) in these two processes are reviewed. Based on work done primarily in knockout mouse models, separate roles for the two estrogen receptors are suggested. Estrogen receptor alpha is primarily involved in masculinization, while estrogen receptor beta has a major role in defeminization of sexual behaviors. In sum, estradiol can have selective effects on distinct behavioral processes via selective interactions with its two receptors, estrogen receptor alpha and estrogen receptor beta.

A previously uncharacterized role for estrogen receptor beta: defeminization of male brain and behavior

Sex differences in brain and behavior are ubiquitous in sexually reproducing species. One cause of sexual dimorphisms is developmental differences in circulating concentrations of gonadal steroids. Neonatal testes produce androgens; thus, males are exposed to both testosterone and estradiol, whereas females are not exposed to high concentrations of either hormone until puberty. Classically, the development of neural sex differences is initiated by estradiol, which activates two processes in male neonates; masculinization, the development of male-type behaviors, and defeminization, the loss of the ability to display female-type behaviors. Here, we test the hypothesis that defeminization is regulated by estrogen receptor beta (ERbeta). Adult male ERbeta knockout and WT mice were gonadectomized, treated with female priming hormones, and tested for receptive behavior. Indicative of incomplete defeminization, male ERbeta knockout mice showed significantly higher levels of female receptivity as compared with WT littermates. Testes-intact males did not differ in any aspects of their male sexual behavior, regardless of genotype. In olfactory preference tests, males of both genotypes showed equivalent preferences for female-soiled bedding. Based on these results, we hypothesize that ERbeta is involved in defeminization of brain and behavior. This aspect of ERbeta function may lead to developments in our understanding of neural-based sexually dimorphic human behaviors.

Parental responsiveness is feminized after neonatal castration in virgin male prairie voles, but is not masculinized by perinatal testosterone in virgin females

We previously found a large sex difference in the parental responsiveness of adult virgin prairie voles (Microtus ochrogaster) such that most males are spontaneously parental, whereas most females are not. Because this sex difference is independent of the gonadal hormones normally circulating in adult virgin voles, the present study examined whether perinatal hormones influence the development of this sex difference. Males were treated prenatally (via their pregnant dam) with both the androgen receptor blocker flutamide (5 mg/day/dam) and the aromatase inhibitor ATD (1 mg/day/dam), or oil, for the last 2 weeks of gestation. Half of the subjects from each group were castrated on the day of birth and the other half received a sham surgery. As adults, intact males were castrated and all males received a silastic capsule filled with testosterone. Prenatal treatment with flutamide and ATD had no effect on males' behavior toward pups, but neonatal castration significantly reduced the percentage of males acting parentally. In a second experiment, females were exposed to testosterone propionate (TP; 50 microg/day/dam) or oil via their dam during the last 2 weeks of gestation. For the first neonatal week, half of the females from each group were injected with TP (1 mg/day) and the other half oil. As adults, females were ovariectomized and half from each group received a testosterone-filled capsule and the other half received an empty capsule. None of the perinatal TP treatments increased females' parental responsiveness, although females from all groups that received testosterone capsules as adults were highly parental. Therefore, although postnatal testicular hormones are necessary for high parental responsiveness in males, the behavior of females is not influenced by perinatal exposure to testosterone.

Cell death in the sexually dimorphic dorsal preoptic area/anterior hypothalamus of perinatal male and female ferrets

A sexually dimorphic male nucleus (MN) is present in Nissl-stained sections through the dorsal (d) preoptic area/anterior hypothalamus (POA/AH) of male ferrets. The MN-POA/AH is composed of a cluster of large cells which is organized in males by the action of estradiol, formed via the neural aromatization of circulating testosterone (T), during the last quarter of a 41-day gestation. Several recent studies using rodent species have raised the possibility that the hormone-induced masculinization of POA/AH morphology is mediated at least in part by a perinatal modulation of cell death. We asked whether a perinatal reduction in cell death contributes to the differentiation of the MN-POA/AH in the male ferret, which is a carnivore species. The appearance of internucleosomal DNA fragmentation, detected by in situ end labeling (ISEL) using the ApopTag kit (Oncor Corp.) and of pyknotic cell nuclei in Nissl-stained sections were used to estimate the occurrence of cell death. Male and female ferret kits were killed at four different ages spanning the perinatal period during which the MN-POA/AH is organized and assumes an adult phenotype. A peak density of dying cells was present in both sexes at postnatal day (P) 2, which is nearly 1 week after the age, embryonic day (E) 37, when the MN-POA/AH is first visible in male ferrets using Nissl stains. The density of cells in the sexually dimorphic dPOA/AH which were either ISEL-positive or pyknotic was similar in males and females on E34, as well as on P2, 10, and 20. In the nondimorphic ventral POA/AH, the highest density of dying cells was present in both sexes at E34, and there were significantly more ISEL-positive cells present in males than females at this particular age. In contrast to previous studies using rodents, our results suggest that in fetal male ferrets a modulation of the incidence of cell death contributes little to estradiol's organizational action in the dPOA/AH.

Ontogeny of sex differences in the mammalian hypothalamus and preoptic area

1. There are numerous sites in the nervous system where steroid hormones dramatically influence development. Increasing interest in mechanisms in neural development is providing avenues for understanding how gonadal steroids alter the ontogeny of these regions during sexual differentiation. 2. An increasing number of researchers are examining effects of gonadal steroids on neurite outgrowth, cell differentiation, cell death, cell migration, and synaptogenesis. The interrelated timing of these events may be a key aspect influenced by gonadal steroids throughout development. 3. The preoptic area and hypothalamus are characteristically heterogeneous in terms of cell type (e.g., different neuropeptides) and cell derivation. Perhaps a major reason for the ontogeny of sexual differences in the preoptic area and hypothalamus lies in the convergence of many different cell types from diverse sources (i.e., proliferative zones surrounding the lateral and third ventricles, and the olfactory placodes) that can be influenced in an interactive manner by gonadal steroid mechanisms. 4. The characterization of multiple mechanisms (e.g., trophic, migratory, apoptotic, fate, etc.,) that contribute to permanent changes in brain structure and ultimately function is essential for unraveling the process of sexual differentiation.

Injection of an aromatase inhibitor after the critical period of sexual differentiation

We have investigated the possible role of the second week of life in the differentiation of sexually dimorphic behaviours, dependent on the androgenic aromatization, and its possible relationship with the serotonergic systems. For this purpose, 5 mg/kg of a suspension of an aromatase inhibitor, LY43578, has been intraventricularly injected to males on day 12 of life. Studies have been made in adulthood on exploratory and motor activities, anxiety, sexual motivation, and sexual performance. Indoleamine levels in the hypothalamus and corpus striatum have been measured. Sexual behaviour, exploration, and serotonergic metabolism were not affected by the treatment. Sex partner preference and anxiety in the plus-maze showed a feminized tendency in the treated group that, however, did not reach statistical significance. From these results we have confirmed the restriction of the critical period of androgenic aromatization for the organization of reproductive and exploratory behaviour.

Effects of sex and androgen treatment on dendritic dimensions of neurons in the sexually dimorphic preoptic/anterior hypothalamic area of male and female ferrets

A sexually dimorphic group of cells at the dorsal border of the preoptic/anterior hypothalamic area (POA/AH) of ferrets has been previously identified in Nissl-stained tissue. In this study, Golgi-stained tissue was examined in order 1) to determine whether sex differences exist in dendritic dimensions of neurons from this region, and 2) to assess the effects of adult androgen treatment on dendritic morphology in ferrets of both sexes. Brains from adult ferrets given daily injections of testosterone propionate (5 mg/kg body weight) or oil vehicle for 5 weeks after gonadectomy were impregnated by Golgi-Cox procedures. After sectioning at 120 microns, 78 multipolar neurons were selected from the sexually dimorphic POA/AH of 12 ferrets and reconstructed in three dimensions with the aid of a computer-assisted neuron tracing system. Large sex differences were observed in somal area and most aspects of dendritic morphology, including total length, number of branches, and total dendritic surface area. Androgen also appeared to accentuate dendritic arborization in both sexes, but this effect was weaker than the sex effect, more apparent in males than females, and restricted to fewer variables. The most statistically significant effects of adult androgen treatment in males were found for total dendritic surface area and percentage of fourth order dendrites, and in females, average dendritic thickness. These data show that strong sex differences exist in dendritic structure of neurons in the POA/AH, and suggest that alterations in levels of gonadal steroids in adulthood may promote synaptic remodeling in a region of the brain involved in the control of sexually dimorphic behaviors.

Role of monoamines in the male differentiation of the brain induced by androgen aromatization

Cerebral androgen aromatization has been described as a mechanism responsible for masculinization of the brain, and monoamines seem to be involved in sexual differentiation of the brain. The aim of this study was to investigate the possible implication of monoamines in the masculinization of the brain induced by cerebral androgen aromatization not only in the classic hypothalamic areas but also in some extrahypothalamic ones. For this purpose, 1-day-old male Wistar rats were injected intraventricularly with 5 mg/kg of a suspension of an aromatase inhibitor, LY43578. Saline was administered to male and female control groups. At adulthood, open-field, heterotypical, and homotypical sexual behavior tests were performed and cerebral amines were determined by HPLC-ED. Behavioral tests revealed feminine-like exploratory activity and defecation rate in the treated group, as well as an 89% lordotic response and decreased number of mounts plus intromissions. Testosterone levels were not affected by the treatment. Striatal and limbic serotonergic metabolism showed a sexual dimorphism, higher in males than females, that disappeared in the treated group. From these results, we suggest a possible role of extrahypothalamic serotonin in the mediation of the estrogen-induced mechanisms of behavioral sexual differentiation.

Effects of fetal androgen on childhood behavior

The effects of fetal androgen excess or deficiency on postnatal behavior were examined in 7 males and 14 females with congenital adrenal hyperplasia or hypoplasia aged 3 to 21 years. The subjects were divided into 3 groups: those with androgen excess (A+) comprised a group of 13 patients with classical 21-hydroxylase deficiency and one with 11-beta-hydroxylase deficiency; a normal or reduced androgen (a+) group was represented by one patient with late-onset 21-hydroxylase deficiency and one with congenital adrenal hypoplasia; and a group with absent androgen (A-) consisted of 5 patients with a cholesterol side-chain cleaving-enzyme deficiency. Behavior was evaluated as male (M) or female (F) according to the pattern of play, classification of which was based on data of prevalent play in 1,275 preschool and 400 school boys and girls. Play prevalent in both sexes was classified as neutral (N). The mothers of the patients were requested to check the preferred play during childhood from a randomized play list. The androgen excess group showed M or bisexual (M/F) type, whereas all of the androgen deficient group revealed F type irrespective of gender. In preschool children, coincidence of M or F play type with genetic sex, social sex and androgen exposure was 38%, 53% and 90%, respectively, indicating androgen-dependency of playing patterns. This persisted into school age, although the coincidence rate was slightly changed by environmental effects. These results suggest that fetal androgen plays a role in the sexual differentiation of the central nervous system.

The effects of embryonic treatments with gonadal hormones on sexually dimorphic behavior of chicks

In order to study the role of sex steroids in the differentiation of chick behavior, two groups of experiments were carried out. The first part of the study documented sexual dimorphisms in three behavioral measures in chicks: open-field activity, flocking response, and masculine sexual behavior activated by testosterone (crowing, waltzing, and mating attempts). In the second part, possible organizing influences on these sexually dimorphic behaviors were examined. Male and female embryos were injected with estradiol benzoate (EB) or testosterone propionate (TP). Treatment of males with EB or TP demasculinized all three behaviors. None of the steroid treatments had any effect on the behavior of the females. Plasma testosterone levels of the chicks were not affected by any of these treatments, either before or after testosterone activation. Comb weight was reduced by treatment of male embryos with EB and increased by TP in female embryos, which suggests different mechanism for the development of somatic and behavioral characteristics. The results suggest that exogenous T or E given embryonically can exert similar effects on both sexual behavior and nonreproductive activity of chicks.

Neonatal testosterone masculinizes sexual behavior without affecting the morphology of the dorsal preoptic/anterior hypothalamic area of female ferrets

We examined whether testosterone (T) administered to female ferrets neonatally--a treatment known to enhance masculine coital capacity--induces formation of the sexually dimorphic male nucleus in the dorsal preoptic/anterior hypothalamic area (MN-POA/AH), and/or sensitizes dorsal POA/AH neurons to the stimulatory effect of later androgen treatment on somal dimensions. In males, the MN-POA/AH was present in all subjects, and exposure to androgen following castration at postnatal day 56 (P56) increased both MN-POA/AH volume as well as mean somal areas of MN-POA/AH neurons relative to oil-treated controls. Females given androgen from P5 to P20 and for one month beginning after ovariectomy on P56 failed to develop the MN-POA/AH, but displayed high levels of masculine sexual behavior. Somal areas of dorsal POA/AH neurons in females that received either T or a control neonatally did not increase following androgen treatment at P56. Thus, the correlation that exists between somal enlargement of dorsal POA/AH neurons and masculine sexual behavior in androgen-treated males is not found in behaviorally masculinized females. Masculine coital ability does not appear related to aspects of dorsal POA/AH morphology, supporting data from a previous study in which lesions of the MN-POA/AH caused negligible deficits in masculine sexual behavior of adult male ferrets.

Can a single androgen receptor fill the bill?

If the above two hypotheses are correct, they would require at least one more specific nuclear receptor for T, and at least one membrane receptor to account for the very rapid effects induced by androgens on certain target tissues. If this is the case, clearly a single androgen receptor will not fill the bill.

Effects of lesions of a sexually dimorphic nucleus in the preoptic/anterior hypothalamic area on the expression of androgen- and estrogen-dependent sexual behaviors in male ferrets

The male nucleus of the preoptic/anterior hypothalamic area (MN-POA/AH) is a sexually dimorphic structure present in male, but not in female ferrets. Ovariectomized female ferrets given increasing dosages of estradiol benzoate (EB) normally run faster towards a stud male in an L-maze (i.e. become more proceptive). In two separate experiments, only gonadectomized males with bilateral damage to the MN-POA/AH following large or small electrolytic lesions approached stud males more quickly in response to EB. By contrast, males which received sham lesions, unilateral large POA/AH lesions, or bilateral lesions which missed the MN-POA/AH on at least one side failed to show EB-induced reductions in approach latencies in pre- or post-operative tests. Males with large POA/AH lesions also displayed significant post-operative decrements in masculine sexual behaviors during treatment with a high dose of testosterone propionate (TP). Less severe, but statistically significant deficits in masculine coital performance were also observed in males with small lesions which damaged the MN-POA/AH bilaterally; however, the ability of these males to achieve intromissions appeared normal. Together, these results suggest that the MN-POA/AH of the male ferret exerts an inhibitory influence on estrogen-dependent proceptive responsiveness, but play only a minor role in the control of masculine coital behavior.

The influence of androgenic and estrogenic hormones on sexual behavior in castrated adult male pigs

The objectives of these studies were to evaluate the influence of testosterone propionate (TP), estradiol cypionate (EC), dihydrotestosterone propionate (DHTP), EC + TP, EC + DHTP, and TP + DHTP on traits of masculine sexual behavior in castrated adult male pigs of different breeds. Masculine sexual behavior was restored and maintained by TP, whereas EC initially activated sexual behavior, including copulation and ejaculation, but was unable to sustain copulatory behavior for the 8- to 18-week periods that were evaluated. Treatment with DHTP was ineffective for stimulation of sexual behavior; thus, it is suggested that testosterone promotes some aspects of masculine sexual behavior in male pigs via aromatization to estrogen, but both androgen and estrogen are required for maintenance of the full complement of masculine sexual behavior traits.

Effect of sex, intrauterine position and androgen manipulation on the development of brain aromatase activity in fetal ferrets

Abstract Experiments were conducted to explore the possible relationship between testicular androgen secretion and the development of brain aromatase activity in fetal ferrets. Aromatase activity in the preoptic+mediobasal hypothalamus and temporal lobe was similar in fetuses of both sexes between embryonic Days 26 and 36 even though whole body androgen content was invariably higher in males than females. Whole body androgen content was significantly higher in females located caudally (downstream) from two or more as opposed to zero or one males in the same uterine horn; nevertheless their brain aromatase activity was similar. Finally, maternal treatment with either the androgen receptor antagonist Flutamide or 5alpha-dihydrotestosterone propionate beginning on gestational Day 24 did not affect brain aromatase activity in fetal offspring of either sex, delivered on embryonic Day 34. Previous studies suggest that the biosynthesis of estrogen in the fetal ferret brain is normally greater in males than females. The present results suggest that this sex difference results primarily from increased androgenic substrate being available to non-saturated aromatizing enzymes and not from an androgen-dependent activation of aromatase.

Embryonic sex steroids affect mating behavior and plasma LH in adult chickens

Chicken embryos of both sexes were treated with either antiestrogen (tamoxifen = T), antiandrogen (flutamide = F), aromatization inhibitor (ATD = A), estradiol (E), or oil (control = C). Before puberty, some males of each group were castrated. At puberty, birds were tested under the following regimes: castrated males injected daily with testosterone propionate (CAS + TP) or estradiol benzoate (CAS + EB), intact males (M-INT), intact females (F-INT), and females injected daily with TP (F-TP). In the M-INT and CAS + TP males, E treatment suppressed masculine mating behavior. The embryonic treatments with T, F, and A demasculinized only the frequency of copulations. None of the antihormone treatments caused any masculinization of the sexual activity in the F-TP birds. Untreated males had higher plasma LH than females. The embryonic treatment with E reduced (feminized) the LH levels in CAS + EB birds. This effect was less pronounced in M-INT birds. The results suggest that in chickens, estradiol plays a role in the masculinization of copulatory behavior potential in the developing male embryo. High embryonic estradiol reduces the potential for displaying male sexual behavior at puberty. Feminization of LH secretion requires a high level of estradiol in both embryonic and adult life.

Developmental changes in brain and serum binding of testosterone and in brain capillary uptake of testosterone-binding serum proteins in the rabbit

Developmental changes in the brain uptake of circulating testosterone and of testosterone-binding proteins, such as testosterone-binding globulin (TeBG) or albumin, may play a role in the sexually dimorphic changes in brain structure that are mediated by circulating testosterone. The present studies examine developmental changes in binding of testosterone in both the serum and brain compartments in postnatal rabbits in vivo and developmental changes in the uptake of [3H]TeBG or [3H]albumin by capillaries isolated from developing rabbit brain. The results show that between 10 and 15 days postnatally both the brain sequestration of testosterone and rabbit serum binding of the hormone are markedly increased relative to the newborn period. In addition, both [3H]TeBG and [3H]albumin were taken up by microvessels isolated from 28-day-old rabbit brain, and this process for [3H]TeBG was more active in capillaries obtained from neonatal rats as opposed to adult rats. In summary, these studies show that the binding systems for testosterone are modulated in a parallel fashion in both the serum and brain compartments. In addition, uptake mechanisms for serum testosterone-binding proteins such as TeBG and, to a lesser extent, albumin exist in the capillaries of developing rabbits. These brain capillary plasma protein uptake systems may allow for the distribution into brain of circulating serum proteins such as TeBG and, to a lesser extent, albumin, in developing rabbits.

Evidence implicating aromatization of testosterone in the regulation of male ferret sexual behavior

We compared the effects of the aromatase inhibitor, 1,4,6-androstatriene-3,17-dione (ATD) and castration on the expression of mating behavior in adult male ferrets which were in breeding condition. Males implanted SC with Silastic capsules containing ATD displayed significantly less neck gripping, mounting and intromittive behavior than intact males which received empty capsules, although the ATD-induced reductions in behavior were not as large as those seen after castration. ATD had no effect on mating behavior in castrated males. As reported in another publication, brain aromatase activity was significantly reduced in both the intact and castrated males treated with ATD in the present study. Plasma estradiol (E2) levels were uniformly low in intact and castrated males, regardless of whether they received ATD or no steroid. As expected, plasma testosterone (T) levels were significantly lower in castrated than in intact males, and ATD treatment did not affect these values. These results suggest that E2 formed via the neural aromatization of T contributes to the activation of masculine sexual behavior in intact male ferrets in breeding condition.

Role for prenatal estrogen in the development of masculine sexual behavior in the male ferret

Previous studies have shown that neonatal exposure to testosterone is essential for coital masculinization in male ferrets. In the present experiments, masculine sexual behavior was diminished in male ferrets by prenatal exposure to drugs which inhibited estrogenic stimulation of the brain. Similarly timed prenatal treatments with testosterone failed to masculinize the behavior of female offspring. We hypothesize that prenatal exposure of the male ferret to estrogen, derived from the neural aromatization of circulating androgen, may sensitize the developing brain to the subsequent masculinizing action of testosterone shortly after birth.

Sexual dimorphism in the preoptic/anterior hypothalamic area of ferrets: effects of adult exposure to sex steroids

The organization of neuronal cell bodies in the caudal preoptic area (POA) and rostral anterior hypothalamic area (AH) was studied in Nissl-stained brain sections from adult male and female ferrets. Computer-assisted image-analysis procedures were developed to help estimate the areas of cellular density and the sizes of individual perikarya. At the junction of the POA and AH, a bilateral dorsal-medial group of neurons was apparent only in male ferrets (dorsal nucleus). At the same coronal level, a ventral-medial group of neurons was apparent bilaterally in both males and females (ventral nucleus). The mean somal area of cells in the dorsal nucleus of males was significantly greater than the mean somal area of cells in the corresponding dorsal region of females or in the ventral nucleus of both sexes. The dorsal nucleus was clearly discernible in adult males regardless of their hormonal status, although cells in the dorsal nucleus were larger in intact breeding males or gonadectomized males given testosterone, estradiol or dihydrotestosterone than in gonadectomized males given no gonadal hormones or given progesterone. Neither the grouping of large cells nor the steroid-induced increase in cell size, characteristic of the male dorsal nucleus, was seen in the comparable dorsal region of females. The sex difference in cellular organization observed in the ferret at the junction of the POA and AH is the first difference of this type to be seen in the POA/AH of a non-rodent mammalian species. Its identification will, hopefully, aid in the analysis of the neural mechanisms that control various sex-specific behaviors in this species.

Neonatal exposure of female ferrets to testosterone alters sociosexual preferences in adulthood

Sociosexual preferences in adult female ferrets, as measured in a choice arena, were altered by neonatal exposure to exogenous testosterone. Adult female ferrets showed a preference for males which did not depend on the presence of gonadal steroids, because gonadectomized and gonadectomized estrogen-treated females showed identical preferences for males. Adult castrated males showed no preference for females unless these males were treated with testosterone. A similar no-preference pattern was found in adult females that had received testosterone neonatally. Females exposed neonatally to dihydrotestosterone or estradiol exhibited the normal females' male-oriented preference. These results indicate that testosterone secreted by the testes in the developing male may interrupt the phenotypic female development pattern and hence prevent the emergence of a homosexual preference in adulthood in the male ferret.

Perinatal androgen manipulations do not affect feminine behavioral potentials in voles

Adult voles show sexual differences in their behavioral responses to estrogen. To determine whether this sexual dimorphism is related to early androgen exposure as it is in other rodents, female voles were treated neonatally with testosterone. In addition, males were castrated neonatally or treated perinatally with either the antiandrogen, flutamide or with the antiaromatase, ATD. When androgenized females were treated with estrogen in adulthood, they exhibited normal sexual behaviors. Males deprived of androgen or treated with ATD during development did not display feminine behaviors when injected with estrogen in adulthood. These results suggest that the organizational hypothesis of sexual differentiation cannot explain the development of feminine behavior potentials in the vole. It is possible that the development of feminine behaviors in voles requires exposure to ovarian hormones during prepubertal development.

Effect of prenatal exposure to aromatase inhibitor, testosterone, or antiandrogen on the development of feminine sexual behavior in ferrets of both sexes

Experiments were conducted to assess the role of prenatal exposure of the brain to estrogen in controlling the development of proceptive and receptive feminine sexual behavior in ferrets of both sexes. Female ferrets, deprived prenatally of estrogen via maternal ovariectomy on gestational day 30 (42-day gestation) plus SC implantation of an aromatase inhibitor, 1,4,6-androstatriene-3,17-dione (ATD), into their mothers, were significantly less receptive than control females when tested in adulthood after ovariectomy and administration of low (5 and 10 micrograms/kg) dosages of estradiol benzoate (EB). However, they were no less receptive than control females in response to a high (15 micrograms/kg) dosage of EB. Estrogen-deprived females showed EB-induced reductions in approach latencies to a stud male (proceptive responses) which were equivalent to those of control females. These results suggest that estrogenic stimulation of the female brain during fetal development enhances later receptive responsiveness to estradiol. However, prenatal estrogen appears not to be an absolute requirement for the development of receptive or proceptive coital capacity in females. In a previous study castrated male ferrets failed to show EB-induced reductions in the latency to approach a sexually active male, indicating that they were proceptively defeminized. In the present study females exposed prenatally to exogenous testosterone also failed to display significant EB-induced reductions in approach latencies to a sexually active male. Males deprived prenatally of estrogen ran faster to a stud male after adult administration of increasing dosages of EB.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of neonatal castration and testosterone treatment on sexual partner preference in the ferret

Groups of male and female ferrets were tested in a T maze to determine whether they preferred to approach and interact with a sexually active male or an estrous female. Control male and female ferrets gonadectomized (GX) on postnatal Day 35 and tested in adulthood while receiving no hormone or testosterone (T) displayed no significant preference. When given estradiol benzoate (EB), however, control males preferred stimulus females whereas control females preferred stimulus males. When tested in adulthood with EB treatment, males GX on postnatal Day 5 showed a significant reduction in their approach to stimulus females, although they did not switch their preference to stimulus males and thereby resemble control females. Female ferrets GX on postnatal Day 5 and given a high dosage of T over postnatal Days 5-20 showed a significant reduction in their approach to stimulus males, although they did not switch their preference to stimulus females, and thereby resemble control males. The results suggest that extended perinatal exposure of male ferrets to T is required for the development of a sociosexual preference for females.

Activity in the ferret: oestradiol effects and circadian rhythms

The present study was conducted to determine whether oestradiol increases activity in the European ferret (Mustela furo), whether this effect is sexually dimorphic, and whether a 24-h rhythm is present in the ferret's daily activity. The activity of male and female adult, postpubertally gonadectomized ferrets was monitored while they were maintained singly on a 13:11 light-dark cycle, before and after implantation with oestradiol-17 beta. Gonadectomized male and female ferrets exhibited equal levels of activity, and neither sex exhibited a significant change in activity following oestradiol implantation. None of the ferrets exhibited a strong circadian rhythm, although weak 24-h rhythms and shorter harmonic rhythms were present. Golden hamsters (Mesocricetus auratus), monitored in an identical manner, exhibited strong circadian rhythms. It was concluded that oestradiol administration may not cause an increase in activity in the ferret, and that this species lacks a strong circadian activity rhythm.

Gender-transposition theory and homosexual genesis

The genesis of homosexuality, and therefore of heterosexuality also, has traditionally been argued as either wholly biological or wholly social-environmental. The theory of gender transposition integrates findings regarding both prenatal hormonal programming of the sexual brain, and postnatal social programming.

Adult erotosexual status and fetal hormonal masculinization and demasculinization: 46,XX congenital virilizing adrenal hyperplasia and 46,XY androgen-insensitivity syndrome compared

Among 30 young women with a history of the treated adrenogenital syndrome (CVAH), 11 (37%) rated themselves as bisexual or homosexual. Among a control group consisting of 15 women with the 46,XY androgen-insensitivity syndrome (AIS) plus 12 with the Rokitansky syndrome (MRKS), the corresponding figure was 2 (7%), both bisexual. Chi-square was significant beyond the 0.01 level. In Kinsey's 1953 sample 15% of women experienced homoerotic arousal imagery by age 20, and 10% had had homoerotic partner contact. The most likely hypothesis to explain the CVAH findings is that of a prenatal and/or neonatal masculinizing effect on sexual dimorphism of the brain in interaction with other developmental variables.

Postnatal differentiation of sexual preference in male pigs

Attraction to sexually mature males and the immobilization response were evaluated after postpubertal estrogen treatment of ovariectomized females and of males castrated within 48 hr after birth or at 4 or 8 months of age. The time spent in the end of an evaluation pen which housed a mature intact male, the proportion of animals that showed the immobilization response, and the latency to onset and the duration of this response were similar in ovariectomized females and males castrated within 48 hr after birth. These two groups spent more time in the male end of the evaluation pen as opposed to the opposite end which housed an ovariectomized female, showed a shorter latency to the onset of the immobilization response, and expressed this response for a greater number of days than males castrated either at 4 or 8 months of age. Males castrated at 4 or 8 months did not show a strong preference for either a mature male or an ovariectomized female. The immobilization response in estrogen-treated males castrated at 4 or 8 months of age diminished as these animals became older. On the basis of the observations made in this study, attraction to a mature, intact male is a sexually dimorphic behavioral trait in pigs, and defeminization of this trait in male pigs is associated with the pubertal increase in testicular steroid secretion. Presently, pigs are the only mammalian species in which a role has been identified for pubertal, testicular steroid secretion in the defeminization process.

Characterization of estradiol receptors in brain cytosols from perinatal ferrets

Studies were undertaken to characterize the binding of [3H]estradiol ([3H]E2) to blood plasma and to brain cytosols collected from perinatal ferrets of both sexes. A dialysis experiment showed that the binding capacity of plasma for [3H]E2 was low in neonatal ferrets. Saturable, high-affinity binding of [3H]E2 to cytosols prepared from ferret hypothalamus + preoptic area (H + POA), basal temporal lobe, and midbrain + brainstem (sexes pooled) was demonstrated 5 days prior to the date of expected parturition (42-day gestation), as well as on the day of birth and on postnatal days 5 and 10. The binding of E2 to cytosols prepared from H + POA and temporal lobe of newborn ferrets met established criteria for estrogen receptors: (a) it was saturable; (b) it had a high affinity (Kd approximately 10(-10) M); (c) it was apparently macromolecular since it migrated in front of a 4.7 S dansyl-bovine serum albumin marker on sucrose gradients of low ionic strength and eluted in the void volume of Sephadex LH-20 columns; (d) it was apparently proteinaceous since binding was destroyed by preincubation with pronase; and (e) it was steroid-specific. Previous research suggests that perinatal exposure to E2 causes neither behavioral defeminization nor masculinization in the developing ferret. The present findings raise the question of whether estrogens, acting via neural receptors, normally affect brain development in ferrets of either sex.