Evidence for sexual differentiation of glia in rat brain

It is well established that gonadal steroids mediate sexual differentiation of the brain via direct effects on neurons during a restricted critical period. In addition, estrogen can influence glial morphology in the adult brain, and in vitro studies suggest estrogen induces glial differentiation. However, there is a lack of in vivo evidence for steroid effects on glia during the critical period. We report here a hormone-mediated sexual differentiation of arcuate glia as early as Postnatal Day 1. Using glial fibrillary acidic protein immunoreactivity (GFAP-ir), we compared the responsiveness of astroglia in the rat arcuate nucleus among five hormonally different groups. The results indicate increased GFAP-ir cell surface area 24 hr after hormonal manipulation in castrate males compared to intact males, intact females (ANOVA; P < 0.01), and females injected with testosterone propionate (50 microg; ANOVA; P < 0.05). However, astroglia in intact males extended their processes significantly greater distances from the cell body compared to all other treatment groups (ANOVA; P < 0.01). The GFAP-ir cells were categorized into four distinct classes ranging from a simple bipolar to a fully stellate morphology. The frequency distribution of classes varied between groups with more stellate cells found in intact males. Finally, these sex differences in arcuate glia persisted into adulthood. We hypothesize that during the critical period, testosterone, or its metabolite estrogen, induce sexual differentiation of glia. We further hypothesize that in females glial cells remain partially undifferentiated and this may be important to glial plasticity seen in adult female arcuate.     

Influence of gender and the endocrine environment on the distribution of androgen receptors in the lacrimal gland

Androgens are known to regulate both the structure and function of lacrimal tissue in a variety of species. To explore the endocrine basis for this hormone action, the following study was designed to: (1) determine the cellular distribution of androgen receptors in the lacrimal gland; and (2) examine the influence of gender and the endocrine environment on the glandular content of these binding sites. Lacrimal glands were obtained from intact, castrated, hypophysectomized, diabetic or sham-operated male or female adult rats, mice or hamsters, as well as from orchiectomized rats exposed to placebo compounds or physiological levels of testosterone. The cellular location of androgen receptors was evaluated by utilizing an immunoperoxidase protocol, in which a purified rabbit polyclonal antibody to the rat androgen receptor was used as the first antibody. Our findings with lacrimal glands showed that: (1) androgen receptors are located almost exclusively in nuclei of epithelial cells; (2) the cellular distribution or intranuclear density of these binding sites is far more extensive in glands of males, as compared to females; (3) orchiectomy or hypophysectomy, but not sham-surgery or diabetes, lead to a dramatic reduction in the immunocytochemical expression of androgen receptors; and (4) testosterone administration to orchiectomized rats induces a marked increase in androgen receptor content, relative to that in placebo-exposed glands. Our results also reveal that a 10 kb androgen receptor mRNA exists in the rat lacrimal gland. Overall, these findings demonstrate that gender and the endocrine system may significantly influence the distribution of androgen binding sites in rat lacrimal tissue. Moreover, our results show that androgens up-regulate their own lacrimal gland receptors.     

Functional antagonism of gonadal steroids at the 5-hydroxytryptamine type 3 receptor

Steroid hormone action involves binding to cognate intracellular receptors that, in turn, bind to respective response elements and thus modulate gene expression. The present study shows that the gonadal steroids, 17beta-estradiol and progesterone, may also act as functional antagonists at the 5-hydroxytryptamine type 3 (5-HT3) receptor in whole-cell voltage-clamp recordings of HEK 293 cells stably expressing the 5-HT3 receptor. Functional antagonistic properties at this ligand-gated ion channel could also be shown for 17alpha-estradiol, 17alpha-ethinyl-17beta-estradiol, mestranol, R 5020, testosterone, and allopregnanolone but not for pregnenolone sulfate and cholesterol. An antagonism at the 5-HT3 receptor could further be observed with the aromatic alcohol 4-dodecylphenol but not with phenol or ethanol. Thus, the modulation of 5-HT3 receptor function by steroids or alcohols is dependent on their respective molecule structure. The antagonistic action of steroids at the 5-HT3 receptor is not mediated via the serotonin binding site because the steroids did not alter the binding affinity of [3H]GR65630 to the 5-HT3 receptor, and kinetic experiments revealed a quite different response pattern to 17beta-estradiol when compared with the competitive antagonist metoclopramide. BSA-conjugated gonadal steroids labeled with fluorescein isothiocyanate bound to membranes of HEK 293 cells expressing the 5-HT3 receptor in contrast to native HEK 293 cells. However, there was no dose-dependent displacement of the binding of gonadal steroids to membranes of cells expressing the 5-HT3 receptor in binding experiments or fluorescence studies. Thus, gonadal steroids probably interact allosterically with the 5-HT3 receptor at the receptor-membrane interface. The functional antagonism of gonadal steroids at the 5-HT3 receptor may play a role for the development and course of nausea during pregnancy and of psychiatric disorders.     

Sex differences in EEG in adult gonadectomized rats before and after hormonal treatment

EEG activity was recorded from the left and right parietal cortex in adult male and female Wistar rats that were gonadectomized (GNX) after puberty during 2 days without and 3 days with hormonal treatment (either testosterone propionate, 5 alpha-DHT or vehicle in males and progesterone, estradiol benzoate or vehicle in females). In contrast to EEG characteristics reported for intact rats, GNX abolished right over left parietal activation in both sexes and, sex differences in EEG interhemispheric correlation and in theta and delta relative power in the right parietal; additionally GNX males showed higher absolute power than females. Hormonal treatment reestablished interparietal asymmetry in both sexes and a lack of sex differences in absolute power, however, it was not enough to reestablish sex differences in delta and theta proportion in the right parietal nor in interhemispheric correlation. Differential effects were obtained with testosterone propionate and 5 alpha-DHT in males suggesting that activational effects of testosterone on EEG are probably exerted through testosterone or its aromatized metabolites. The results of our study indicate that the activational effects of gonadal steroids after puberty are necessary for maintaining sex differences in the EEG of the adult rat.     

Androgen regulation of the insulin-like growth factor-I and the estrogen receptor in rat uterus and liver

For the first time testosterone is shown to be an important regulator of the insulin-like growth factor-I (IGF-I) in the rat uterus under in vivo conditions. In this study the regulation of IGF-I and the estrogen receptor (ER) by gonadal steroids in the uterus and liver of female rats was monitored. The ER level was assayed by hormone binding after treatment with testosterone, 5 alpha-dihydrotestosterone or estradiol and specific mRNA species were analyzed by a solution hybridization/RNase protection assay using 35S-labeled RNA probes. Ovariectomized rats restored uterine weight after treatment with testosterone. Uterine IGF-I mRNA was more than 20-fold higher in testosterone treated rats compared to untreated ovariectomized controls after 48 h treatment. The effects of testosterone on ovariectomized animals was followed in a timecourse study. Testosterone administration increased uterine IGF-I mRNA expression during the first 48 h and the maximally induced level was maintained throughout the duration of the experiment (168 h). Since induction of IGF-I mRNA by estrogen is transient, these data indicate that androgen and estrogen increase IGF-I mRNA by different mechanisms. Regulation of IGF-I mRNA by gonadal steroids was also studied in hypophysectomized animals. The rats were given either testosterone, 5 alpha-dihydrotestosterone or estradiol, and uterine IGF-I mRNA was measured after 1 week of treatment. At this timepoint estrogen treated rats showed levels of IGF-I mRNA not significantly different from those of hypophysectomized controls. In contrast testosterone and 5 alpha-dihydrotestosterone increased the IGF-I mRNA level 30 and 40 times, respectively, relative to hypophysectomized control animals. Since 5 alpha-dihydrotestosterone is not convertable to estrogen, the induction by testosterone was considered to be a true androgenic phenomenon.     

Sexual behavior and alpha-2 adrenoreceptors in the neocortex of male rats after castration and testosterone administration

Castration of male rats inhibited their sexual behaviour and increased the density of the alpha-2 adrenergic receptors in the brain cortex. Treatment of castrated or intact males with testosterone activated their sexual behaviour and decreased the receptor density in the brain cortex. The obtained evidence testify to the involvement of the brain alpha-2 adrenergic receptors in the effect of testosterone on male sexual behaviour.     

Is plasminogen deficiency a thrombotic risk factor? A study on 23 thrombophilic patients and their family members

We reported previously a significant reduction of oxytocin (OT) receptor binding in the brain of 20-month old rats relative to 3-month old ones. The present study shows that testosterone treatment of aging rats restores normal adult levels of OT receptor binding in the olfactory tubercle and in the hypothalamic ventromedial nucleus, but not in the caudate-putamen. These data indicate that the reduced plasma testosterone found in 20-month old rats is responsible for the loss of OT receptors in the olfactory tubercle and hypothalamic ventromedial nucleus, whereas other aging-related mechanisms may account for the decrease of OT receptor binding in the caudate-putamen.     

Enzymatic sulfation of steroids: II. The control of the hepatic cortisol sulfotransferase activity and of the individual hepatic steroid sulfotransferases of rats by gonads and gonadal hormones

Ovariectomy has relatively little effect on hepatic cortisol sulfotransferase activity (HCSA) in female rats, diminishing it only 30%. On the other hand, castration more than doubles HCSA in males. HCSA is due to 3 steroid sulfotransferases, STI, STII, and STIII. Its dimunition in ovariectomized rats is due to decreased STI and STII. Castration of males results in elevation of STII. Thus, ovaries appear to stimulate STI and STII production and testes appear to inhibit production of STII and perhaps STI. Studies with testosterone and estradiol-17beta support a role for sex hormones as mediators of gonadal effects on HCSA, by stimulating or inhibiting production of the individual enzymes. Estradiol-17beta administration reverses the effect of ovariectomy on HCSA. Testosterone administration to intact or castrated females decreases HCSA by 60-70%, due to disappearance of all STI and most STII activity. Thus, androgen administration appears to suppress both STI and STII production. In intact males testosterone administration elevates HCSA 70-80% due to increased STIII. Estradiol-17beta administration to intact or castrated males elevates HCSA 9-10-fold. In intact animals this is due to elevated STI and STII but not STIII. In castrates all three enzymes are elevated by the estrogen.     

Testosterone and persistence in mice

In view of previous studies showing that testosterone increases persistence of food searching in chicks, a single factorially-designed experiment was carried out to investigate whether a similar phenomenon occurs in male mice. Using a runway test, it was found that testosterone, injected into castrated mice, did increase persistence. It was also shown that intact males resembled more the testosterone-injected than control-injected castrates, and that females resembled neither intact males nor either group of castrates. A larger number of training trials was found to affect feeding latencies in a similar way to testosterone. Comparison of two strains differing in emotional reactivity (BALB/c and Porton) showed differences consistent with their reactivity levels.     

Estradiol induces hypothalamic progesterone receptors but does not activate mating behavior in male hamsters (Mesocricetus auratus) before puberty.

This study investigated pubertal changes in neural and behavioral responses to estradiol. Gonadectomized pre- and postpubertal male hamsters (Mesochcetus auratus) were treated with 0.00, 0.05, 0. 10, or 0.2 mg estradiol and tested 1 week later for sexual behavior with a receptive female. Estradiol activated behavior in postpubertal, but not prepubertal, males. In contrast, estrogen receptor α (ERα) and progesterone receptor (PR) immunoreactivity in forebrain nuclei that mediate mating behavior was similar in pre- and postpubertal males. Thus, absence of a behavioral response before puberty is not associated with reduced levels of steroid receptors. Because estradiol induced PR in prepubertal males these data also suggest that ERα is functional before puberty. Therefore, gonadal steroids facilitate male reproductive behavior only after as-yet-unidentified developmental processes occur during puberty. (PsycINFO Database Record (c) 2010 APA, all rights reserved)     

Effects of estrogen replacement on choline acetyltransferase and trkA mRNA expression in the basal forebrain of aged rats

Testosterone reversed the age-related increase in glial fibrillary acidic protein (GFAP) in the male rat cerebellum, a brain region not generally associated with gonadal steroid hormone sensitivity. This supports the hypothesis that a decrease in circulating testosterone contributes to age-related increase in GFAP. These data also suggest that reductions in circulating gonadal steroids during aging could render the brain more susceptible to neurodegeneration and that hormone replacement therapy might have value in neurodegenerative disease intervention.     

The hamster hippocampal slice: II. Neuroendocrine modulation.

Studied effects of exposing golden hamster hippocampal slices to the gonadal steroids estradiol and testosterone and to delta-9-tetra-hydrocannabinol (THC). At 10–20M, estradiol and testosterone acted as facilitatory neuromodulators on hippocampal slices obtained from male and diestrous female hamsters, respectively. At 10–21M, THC facilitated responses in hippocampal slices from males. Implications for the use of the hamster in investigations of the biobehavioral role of steroid modulation of brain excitability are discussed. (14 ref) (PsycINFO Database Record (c) 2010 APA, all rights reserved)     

Manipulation of gonadal hormones in neonatal rats alters the morphological response of cortical neurons to brain injury in adulthood.

The authors examined the effects of sex and neonatal hormones on the response of pyramidal cells (Layer III, parietal cortex) to injury of the medial frontal cortex in the adult rat. At birth, males were gonadectomized (GDX) or sham-operated. Females were given testosterone (T) or oil injections. In adulthood, rats that had been left intact at birth were GDX, and they then received bilateral medial frontal cortex lesions or sham surgery. Rats not exposed to T at birth exhibited losses of dendritic arbor (males GDX at birth) or dendritic spine density (oil-treated females). Compensation after cortical injury is dependent on the rat's sex and history of exposure to gonadal steroids. (PsycINFO Database Record (c) 2010 APA, all rights reserved)     

Testosterone and persistence of social investigation in laboratory rats.

In 5 experiments 92 mature male and 44 mature female Long-Evans rats were individually exposed in their home cages to sexually immature conspecifics. A prominent sex difference was observed in duration of social investigation prior to a criterion of neglect. When pups were 5 days of age, no sex difference was observed, but when pups were 8 days of age and older, mature males consistently investigated them for significantly longer intervals than did mature females. Furthermore, intact males investigated prepuberal conspecifics for significantly longer intervals than did castrated males, castrated females, or intact females; none of the latter 3 groups differed significantly from each other. Following testosterone treatment, castrated males investigated unfamiliar, prepuberal conspecifics for a significantly longer duration than did untreated castrated control Ss. Combined results support the conclusion that gonadal testosterone effects a greater perseveration of social investigation in males. (20 ref) (PsycINFO Database Record (c) 2010 APA, all rights reserved)     

Estradiol benzoate facilitates lordosis and ear wiggling of 4- to 6-day-old rats.

The effects of exogenous and endogenous steroids on components of female sexual behavior of neonatal male and female rats were investigated. In Experiment 1, 4-day-old rats were treated with 0, 0.1, 1.0, 10, or 100 μg/10 g body weight estradiol benzoate (EB) and were tested 44 hr later. In Experiment 2, male rats castrated within 24 to 48 hr of birth were compared with sham operated controls and castrates given steroid replacement. The results indicated that most 6-day-old pups will display lordosis and ear wiggling, therefore, the display of these responses is not dependent upon exogenous steroids. However, a fine-grain behavioral analysis revealed that EB treatment increased the frequency, duration, and intensity of lordosis and the frequency of ear wiggling in infant females, and it increased lordosis duration in males. Castration of infant males decreased the likelihood that male infants would display lordosis, whereas testosterone replacement restored behavior to control levels. These data question the concept that organizational and activational actions of estrogens occur during completely separable times in development and should provide new insights into the development of estrogen receptor function and the process of sexual differentiation of brain and behavior. (PsycINFO Database Record (c) 2010 APA, all rights reserved)     

Slide-binding characterization and autoradiographic localization of delta opioid receptors in rat and mouse brains with the tetrapeptide antagonist [3H]TIPP

Slide-binding and autoradiographic studies were performed on cryostat sections from brains of adult Sprague-Dawley rats and BALB C mice to describe the binding characteristics of the tetrapeptide [3H]TIPP, an antagonist with high specificity and affinity for the delta opioid receptors. Steady-state binding of [3H]TIPP to cryostat sections of brain paste was reached in 120-180 min of incubation. Specific [3H]TIPP binding resulted in maximal numbers of binding sites (Bmax) of 15.59 and 23.91 fmol/mg protein, and dissociation constants (Kd) of 0.46 and 0.85 nM for rat and mouse brain paste sections, respectively. TIPP displayed the highest affinity for delta opioid receptors in inhibiting specific [3H]TIPP binding, with IC50 values of 0.82 nM and 0.14 nM in rat and mouse brain sections, respectively. While DPDPE was also effective in displacing the specific binding of [3H]TIPP (IC50 = 3.18 +/- 0.53 nM and 0.63 +/- 0.42 nM in rat and mouse brain paste sections, respectively), other subclass-selective or nonopioid ligands were much less effective, or ineffective. Autoradiographic localization of [3H]TIPP binding revealed the characteristic distribution of delta opioid receptors in both species. In consequence of its antagonistic nature, and of its unnatural amino acid residue, which makes this ligand more resistant to biodegradation, [3H]TIPP is a superior ligand for evaluation of the binding characteristics and autoradiogaphic distribution of the delta opioid receptors.     

Gonadal steroids modulate the growth-associated protein GAP-43 (neuromodulin) mRNA in postnatal rat brain

Gonadal steroid hormone action during early postnatal life determines the growth and connectivity of certain neuronal populations in the hypothalamus. The results of recent studies indicate that steroid hormones modulate the growth-associated protein GAP-43 mRNA in the adult rodent hypothalamus. Since GAP-43 is concentrated in axonal growth cones and has been implicated in axonal elongation and synaptogenesis, the present study investigated the effect of various gonadal hormonal conditions on GAP-43 mRNA levels in postnatal rat brain. On postnatal day 1, male rats were castrated or sham-operated and injected with sesame oil. Additional intact female rats were also injected with oil, while a group of female pups were injected with testosterone propionate. On postnatal day 6, brains were frozen and 16-microns cryostat sections processed and hybridized with a 35S-labeled antisense riboprobe complimentary to GAP-43 mRNA. Slide-mounted sections were stringently washed, apposed to X-ray film and then dipped in liquid emulsion. Evaluation of slide and film autoradiograms revealed an extensive presence of GAP-43 mRNA in the medial preoptic nucleus, bed nucleus of the stria terminalis and cerebral cortex, while the intensity of hybridization signal in other brain regions including the striatum was low. Quantitative assessment of GAP-43 mRNA in the medial preoptic area revealed that the level of GAP-43 mRNA was highest in the sham-operated male, attenuated after male castration, low in the intact female and markedly augmented in the testosterone-treated female. The pattern of change in the bed nucleus of the stria terminalis and laminae II and III of the frontal cortex was similar to that observed in the preoptic area. The changes in hybridization signal were positively correlated with changes in serum testosterone levels as determined by RIA. The results of these studies indicate that GAP-43 mRNA levels in the medial preoptic area, bed nucleus of the stria terminalis and cerebral cortex are sexually dimorphic and modulated by changes in gonadal steroid hormone levels. The results further suggest that the differential regulation of GAP-43 mRNA by sex steroids in the male and female postnatal brain may influence the phenotype of forebrain neuronal circuitry and thereby determine the phenotype of adult neuronal function.     

3H]-SR 27897B: a selective probe for autoradiographic labelling of CCK-A receptors in the brain

The binding and distribution of radiolabelled SR27897B, a potent CCK-A antagonist, was characterized using in vitro receptor autoradiography. Rapid imaging and quantitative analysis of [3H]SR27897B binding was obtained in a very short period of time (5 days) with a highly sensitive radioimager ensuring very short exposure times for isotopes such as tritium. Tritiated SR27897B binding sites are localized almost exclusively in the area postrema and the medical part of the nucleus tractus solitarius and in this nucleus the rostral-caudal distribution of CCK-A sites differed from that of sulphated CCK8 receptors. Receptor binding properties analyzed on 15 microns serial coronal sections showed on site receptor occupancy in these two regions with high affinity and selectivity characteristic of the CCK-A receptor. These results precisely locate the SR27897B binding sites and provide further support for the absence of heterogeneity of the CCK-A receptors in the rat brain.     

Estrogen-dependent ontogeny of sex differences in somatostatin neurons of the hypothalamic periventricular nucleus

The sexually dimorphic profile of GH secretion is thought to be engendered by gonadal steroids acting in part on hypothalamic periventricular somatostatin (SOM) neurons. The present study set out to examine and characterize the development of sex differences in these SOM neurons. In the first series of experiments, we used in situ hybridization to examine SOM messenger RNA (mRNA) expression within the periventricular nucleus (PeN) of male and female rats on postnatal day 1 (P1), P5, and P10. Cellular SOM mRNA content was found to increase from P1 to P10 in both sexes (P < 0.01), but was 24% (P < 0.05) and 38% (P < 0.01) higher in males on P5 and P10, respectively. A second series of experiments examined the SOM peptide content of the PeN in developing rats and found increasing levels from P1 to P10, with a 44% higher SOM content in males compared with females on P10 (P < 0.05). The third series of experiments questioned the role of gonadal steroids in engendering sex differences in SOM mRNA expression by determining the effects of neonatal gonadectomy (GDX) and replacement of dihydrotestosterone or estradiol benzoate. The SOM mRNA content of PeN neurons in P5 males gonadectomized on the day of birth was the same as that in P5 females and was significantly reduced compared with that in sham-operated P5 males (P < 0.05). Male rats GDX on P1 and treated with estradiol benzoate from P1 to P5 had cellular SOM mRNA levels similar to those in intact males on P5, whereas dihydrotestosterone treatment had no effect. Treatment of intact males with an androgen receptor antagonist, cyproterone acetate, on P1 had no effect on cellular SOM mRNA on P5, whereas male rats given the aromatase inhibitor 1,4,6-androstatriene-3,17-dione from P1 to P5 had lower (P < 0.05) SOM mRNA levels than controls. In the final set of experiments, dual labeling immunocytochemistry showed that SOM neurons in the PeN of P5 rats did not contain estrogen receptor-alpha, but expressed androgen receptors in a sexually dimorphic manner. These results demonstrate that a sex difference in SOM biosynthesis, which persists into adulthood, develops between P1 and P5 in PeN neurons. Despite the absence of estrogen receptor-alpha in these neurons, the organizational influence of testosterone only occurs after its aromatization to estrogen.     

Do sex differences in the brain explain sex differences in the hormonal induction of reproductive behavior? What 25 years of research on the Japanese quail tells us

Early workers interested in the mechanisms mediating sex differences in morphology and behavior assumed that differences in behavior that are commonly observed between males and females result from the sex specificity of androgens and estrogens. Androgens were thought to facilitate male-typical traits, and estrogens were thought to facilitate female-typical traits. By the mid-20th century, however, it was apparent that administering androgens to females or estrogens to males was not always effective in sex-reversing behavior and that in some cases a "female" hormone such as an estrogen could produce male-typical behavior and an androgen could induce female-typical behavior. These conceptual difficulties were resolved to a large extent by the seminal paper of C. H. Phoenix, R. W. Goy, A. A. Gerall, and W. C. Young in (1959, Endocrinology 65, 369-382) that illustrated that several aspects of sexual behavior are different between males and females because the sexes have been exposed during their perinatal life to a different endocrine milieu that has irreversibly modified their response to steroids in adulthood. Phoenix et al. (1959) therefore formalized a clear dichotomy between the organizational and activational effects of sex steroid hormones. Since this paper, a substantial amount of research has been carried out in an attempt to identify the aspects of brain morphology or neurochemistry that differentiate under the embryonic/neonatal effects of steroids and are responsible for the different behavioral response of males and females to the activation by steroids in adulthood. During the past 25 years, research in behavioral neuroendocrinology has identified many sex differences in brain morphology or neurochemistry; however many of these sex differences disappear when male and female subjects are placed in similar endocrine conditions (e.g., are gonadectomized and treated with the same amount of steroids) so that these differences appear to be of an activational nature and cannot therefore explain sex differences in behavior that are still present in gonadectomized steroid-treated adults. This research has also revealed many aspects of brain morphology and chemistry that are markedly affected by steroids in adulthood and are thought to mediate the activation of behavior at the central level. It has been explicitly, or in some cases, implicitly assumed that the sexual differentiation of brain and behavior driven by early exposure to steroids concerns primarily those neuroanatomical/neurochemical characteristics that are altered by steroids in adulthood and presumably mediate the activation of behavior. Extensive efforts to identify these sexually differentiated brain characteristics over the past 20 years has only met with limited success, however. As regards reproductive behavior, in all model species that have been studied it is still impossible to identify satisfactorily brain characteristics that differentiate under early steroid action and explain the sex differences in behavioral activating effects of steroids. This problem is illustrated by research conducted on Japanese quail (Coturnix japonica), an avian model system that displays prominent sex differences in the sexual behavioral response to testosterone, and in which the endocrine mechanisms that control sexual differentiation of behavior have been clearly identified so that subjects with a fully sex-reversed behavioral phenotype can be easily produced. In this species, studies of sex differences in the neural substrate mediating the action of steroids in the brain, including the activity of the enzymes that metabolize steroids such as aromatase and the distribution of steroid hormone receptors as well as related neurotransmitter systems, did not result in a satisfactory explanation of sex differences in the behavioral effectiveness of testosterone. Possible explanations for the relative failure to identify the organized brain characteristics responsible for behavio