Ontogeny of testosterone-inducible brain aromatase activity

Testosterone recruits new aromatase-imunoreactive cells in neonatal quail brain

It was shown earlier that, in Japanese quail the mechanism controlling the induction by testosterone of aromatase activity develops between embryonic days 10 and 14. The cellular processes underlying this activation have, however, not been investigated in detail. Here, we demonstrate that the increase in aromatase activity observed in neonates treated with testosterone propionate between postnatal days 1 and 3 results from the recruitment of additional populations of aromatase-immunoreactive cells that were not expressing the enzyme at detectable levels before. This recruitment concerns all brain nuclei normally expressing the enzyme even if it is more prominent in the ventromedial hypothalamus than in other nuclei.

Experience modulates both aromatase activity and the sensitivity of agonistic behaviour to testosterone in black-headed gulls

In young black-headed gulls (Larus ridibundus), exposure to testosterone increases the sensitivity of agonistic behaviour to a subsequent exposure to this hormone. The aim of this paper is twofold: to analyze whether social experience, gained during testosterone exposure, mediates this increase in hormonal sensitivity (priming), and whether this in turn is mediated by an increase in central aromatase activity. To this end, we performed three experiments. In the first juvenile gulls were exposed to two consecutive treatments with testosterone (T1 and T2), with more than a week interval in between. During T1, half of the birds were housed in social isolation (Iso) and the other half in groups (Soc). All birds were re-housed in a new social situation during the second treatment. The increase in social behaviour during T2 was significantly more rapid in Soc than Iso birds. In experiment 2 we show that 17beta-estradiol treatment facilitates the behaviour measured in experiment 1. In experiment 3 we used a set-up comparable with that of experiment 1, but birds were sacrificed early in the T2 period. Aromatase activity in the preoptic area and the hypothalamus was measured using the tritiated water releasing method. In some parts of the preoptic area and hypothalamus aromatase activity was higher in Soc birds relative to Iso birds. The results indicate that social experience can modulate the increase of social behaviour to testosterone via modulation of aromatase activity and independently of actual hormone levels.

Sex- and age-related variation in neurosteroidogenic enzyme mRNA levels during quail embryonic development

Brain can synthesize steroids de novo from cholesterol and this biochemical feature is a conserved property of vertebrates. There is growing evidence indicating that neurosteroids might participate in sexual differentiation of the brain. Therefore, in this study we investigated the presence, the sex differences, and the development-dependent variation of mRNAs coding for key neurosteroidogenic enzymes, namely cytochrome P450 side-chain cleavage enzyme (P450scc), 3beta-hydroxysteroid-dehydrogenase/Delta5-Delta4-isomerase (3beta-HSD), cytochrome P450 17alpha-hydroxylase/c17, 20-lyase (P450c17), and aromatase in embryonic prosencephali. Our results indicated that 3beta-HSD mRNA levels were sexually dimorphic and developmental age-dependent. In particular, 3beta-HSD mRNA levels were higher in females than in males at E7, whereas, this dimorphism was reversed at E9 and E15. In females, the relative levels of 3beta-HSD mRNA were highest at E7, whereas, in males they were significantly higher at E9 and E15 than at E7 and at E11. This sexual dimorphism was a peculiar feature of the prosencephalon, it could not be observed before gonadal sexual differentiation and it was not paralleled by a dimorphism in the brain content of progesterone. The level of mRNA coding for P450scc and for P450c17 did not show obvious developmental- or sex-related variation. Aromatase mRNA varied as a function of the embryonic age but not of the sex. These results, taken together, are suggestive of a potential role of some neurosteroidogenic enzymes in the development of quail brain and suggest that sexual differences in the hormonal environment may occur during brain development.

Sexual versus individual differentiation: the controversial role of avian maternal hormones

Avian embryos are exposed not only to endogenous sex steroids, which are produced by their gonads and have a key role in sexual differentiation, but also to maternal steroids transferred into the egg yolk, which can modulate the development of individual differences in behavior. Studies of maternal hormones have primarily focused on ultimate questions (evolutionary trade-offs, functional significance), whereas proximate mechanistic questions have been largely ignored. A central problem that must be addressed is how exposure to maternal hormones affects the individual phenotype without interfering with sexual differentiation. Separate effects could result from the action of different hormones, at different doses or at different times, on different targets.

Male Japanese quails with female brains do not show male sexual behaviors

During embryonic development, gonadal steroid hormones (androgens and estrogens) are thought to organize the sexual differentiation of the brain in the heterogametic sexes of higher vertebrates (males in mammals, females in birds). Brain differentiation of the homogametic sexes is thought to proceed by default, not requiring sex hormones for sex-specific organization. In gallinaceous birds such as the Japanese quail, female brain organization is thought to develop via estrogen-dependent demasculinization of a default male brain phenotype. We performed male donor-to-female host (MF), female-to-male (FM), male-to-male (MM), and female-to-female (FF) isotopic, isochronic transplantation of the forebrain primordium in Japanese quail embryos before gonadal differentiation had occurred; brain chimeras had a forebrain (including the hypothalamus) originating exclusively from donor cells. MM, FF, and MF chimeras all showed sexual behavior governed by the genetic sex of the host. In contrast, FM chimeras (genetically female forebrain, all other tissues genetically male) showed no mounting and only rudimentary crowing behavior. Although MM, FF, MF, and FM chimeras all showed host-typical production of steroid hormones during embryonic life, only FM chimeras were hypogonadal, had atypical low levels of circulating testosterone in adulthood, and showed reduction (crowing) or absence (mounting) of reproductive behaviors. Morphological features of the medial preoptic nucleus (a sexually dimorphic brain area) also were not male-like in FM males. These data demonstrate a brain-intrinsic, genetically determined component that organizes the sex-typical production of gonadal hormones in adulthood and call for a reevaluation of the mechanisms underlying brain sexual differentiation in other higher-vertebrate species.

Ontogeny of aromatase and tyrosine hydroxylase activity and of aromatase-immunoreactive cells in the preoptic area of male and female Japanese quail

The aromatization of testosterone into oestrogens plays a key role in the control of many behavioural and physiological aspects of reproduction. In the quail preoptic area (POA), aromatase activity and the number of aromatase-immunoreactive (ARO-ir) cells are sexually differentiated (males > females). This sex difference is implicated in the control of the sexually dimorphic behavioural response of quail to testosterone. We analysed the ontogenetic development of this sex difference by measuring aromatase activity and counting ARO-ir cells in the POA of males and females from day 1 post hatch to sexual maturity. We investigated in parallel another enzyme: tyrosine hydroxylase, the rate limiting step in catecholamine synthesis. Between hatching and 4 weeks of age, aromatase activity levels were low and equal in males and females. Aromatase activity then markedly increased in both sexes when subjects initiated their sexual maturation but this increase was more pronounced in males so that a marked difference in aromatase activity was present in 6 and 8 week-old subjects. Tyrosine hydroxylase activity progressively increased with age starting immediately after hatching and there was no abrupt modification in the slope of this increase when birds became sexually mature. No sex difference was detected in the activity of this enzyme. The number of ARO-ir cells in the POA progressively increased with age starting at hatching. No sex difference in ARO-ir cell numbers could be detected before subjects reached full sexual maturity. The analysis of the three-dimensional organization of ARO-ir cells in the POA revealed that, with increasing ages, ARO-ir cells acquire a progressively more lateral position: they are largely periventricular in young birds but they are found at higher density in the lateral part of the medial preoptic nucleus in adults. These data indicate that aromatase activity differentiates sexually when birds reach sexual maturity presumably under the activating effects of the increased testosterone levels in males. The number of ARO-ir cells, however, begins to increase in a non sexually differentiated manner before the rise in plasma testosterone in parallel with the increased tyrosine hydroxylase activity. Whether this temporal coincidence results from a general ontogenetic pattern or from more direct causal links remains to be established.

Steroid metabolising enzymes in the determination of brain gender

The neurotrophic effects of oestrogen formed in the brain are important in brain sexual differentiation of the central nervous system and behaviour. Aromatase, converting testosterone to oestradiol-17beta, is a key enzyme involved in brain development. In primary cell cultures of foetal hypothalamus, we have found that male neurones consistently have higher aromatase activity than in the female. Using a specific antibody to the mouse aromatase, immunoreactivity was localized in the neural soma and neurites in hypothalamic cultures. Additionally more male foetal hypothalamus neurones express aromatase than in the female. Testosterone increases aromatase activity in parallel with a greater number of aromatase-immunoreactive neurones. Testosterone also increases soma size, neurite length, and branching of cultured hypothalamic neurones. The neuronal aromatase activity appears to be sensitive to the inductive effects of androgen only during the later stages of foetal development. Endogenous inhibitors of the aromatase are also likely to have a regulatory role. This work suggests that regulation of a network of aromatase neurones, sensitive to the hormonal environment of the hypothalamus, may determine when oestrogens are available for neurotrophic effects underlying brain differentiation.

Gender-specific steroid metabolism in neural differentiation

1. Both the neuroendocrine system and the brain mechanisms underlying gender-specific behavior are known to be organized by steroid sex hormones, androgen and estrogen, during specific sensitive phases of early fetal and perinatal development. The factors that control these phasic effects of the hormones on brain development are still not understood. Processes of masculinization and defeminization are thought to be involved in the sex differentiation of mammalian reproductive behavior. 2. The P450 aromatase, converting androgen to estrogen, is a key enzyme in the development of neural systems, and the activity of this enzyme is likely to be one of the factors determining brain sex differentiation. 3. We have examined the localization and regulation of brain aromatase using the mouse as a model. Measurement of testosterone conversion to estradiol-17 beta, using a sensitive radiometric 3H2O assay, indicates that estrogens are formed more actively in the male mouse brain than in the female during both the prenatal and the neonatal periods. In primary cell cultures of embryonic mouse hypothalamus there are sex differences in aromatase activity during early and late embryogenesis, with a higher capacity for estrogen formation in the male than the female. These sex differences are regionally specific in the brain, since on gender differences in aromatase activity are detectable in cortical cells. 4. Aromatase activity in the mouse brain is neuronal rather than glial. Using a specific antibody to the mouse aromatase, immunoreactivity is restricted to neuronal soma and neurites in hypothalamic cultures. There are more neurons containing expressed aromatase in the male hypothalamus than in the female. Therefore, gender-specific differences in embryonic aromatase activity are neuronal. 5. Testosterone increases aromatase activity specifically in hypothalamic neurons, but has no effect on cortical cells. The neuronal aromatase activity appears to be sensitive to the inductive effects of androgen only in the later stages of embryonic development. Androgen also increases the numbers of aromatase-immunoreactive neurons in the hypothalamus. 6. This work suggests that the embryonic male hypothalamus and other androgen target areas contain a network of neurons which has the capacity to provide estrogen for the sexual differentiation of brain mechanisms of behavior. The phasic activity of the key enzyme, aromatase, during development is influenced by androgen. What determines the developmental action of androgen and the other factors involved in the regulation and expression of this neuronal enzyme still have to be established.

Brain aromatase activity and plasma testosterone levels are elevated in aggressive male mice during early ontogeny

Testosterone (T) and estradiol (E2) are involved in intraspecific aggressive behavior. Both steroids exert their effects on behaviour via the hypothalamus and the amygdala (Am) of the central nervous system (CNS). In these brain areas T is converted to E2, by the enzyme aromatase. Both the levels of brain aromatase activity (AA) and the effects of T and E2 on aggressive behavior in adulthood depend on steroidal organization of the CNS during ontogeny. In this study we measured plasma T and in vitro brain AA of males fetuses and neonates derived from two strains of wild house mice, which had been genetically selected for aggression, based upon attack latency. There were no differences in preoptic area (POA) AA levels between selection lines on either embryonic day (E) 17 or 18, or the day after birth (day 1). In the non-aggressive long attack latency (LAL) males the POA AA increases with age, i.e. was higher on E18 than on E17, which is correlated with brain weight (BrW). This was in contrast to aggressive short attack latency (SAL) fetuses, which only showed a slight, but not significant differences between embryonic days or a correlation with BrW. Neonatally, the POA AA of LAL males tended to decrease in contrast to SAL males. However, SAL neonates had a higher AA in the amygdala (Am) than LAL neonates, whereas no differences exist in the anterior hypothalamus. Thus, a differential brain AA distribution exists in SAL and LAL pups.(ABSTRACT TRUNCATED AT 250 WORDS)

Aromatase-immunoreactive cells in the quail brain: effects of testosterone and sex dimorphism

We previously demonstrated that testosterone (T) increases aromatase activity (AA) and that AA is sexually dimorphic (males > females) in the quail preoptic area (POA). The precise anatomical localization of these effects is, however, impossible to obtain by biochemical assays even when samples are dissected by the Palkovits punch technique. We were recently able to set up an immunocytochemical (ICC) procedure that permits visualization of aromatase-immunoreactive (ARO-ir) cells in the quail brain. This showed that the ARO-ir cells of the quail POA actually outline the sexually dimorphic medial preoptic nucleus (POM). This ICC technique was used here to analyze the sex dimorphism of the quail preoptic aromatase and the localization of T effects on ARO-ir cells. In Experiment 1, the number of ARO-ir cells was counted in one section every 100 microns throughout the rostral to caudal extent of the POM of castrated birds that had been treated with increasing doses of T (5, 10, or 20 mm long Silastic implants). These T-treatments produced a dose-related increase in the sexual behavior of the birds and they increased the number of ARO-ir cells in POM, in the septal regions, and in the bed nucleus of the stria terminalis (BNST). The effect had a particularly large amplitude in the part of the POM located under the anterior commissure (AC). In Experiment 2, the same procedure was used to reanalyze the sex difference of the preoptic aromatase system. This showed that the POM of adult males contains more stained cells than the POM of females but only in a restricted region located just under and rostral to the AC. No significant sex difference was observed in the septum or in the BNST. In Experiment 3, the number of ARO-ir cells was determined in the POM of males and females that had been gonadectomized and treated with a same dose of T (40 mm implants). No sex difference in the number of ARO-ir cells could be detected in these conditions. This suggests that the sex difference in AA that had been previously observed in T-treated birds results either from a difference in aromatase concentration or activity in a similar number of positive cells or from a difference in the number of ARO-ir cells that is very discrete from the anatomical point of view.(ABSTRACT TRUNCATED AT 400 WORDS)

Aromatase-immunoreactivity is localised specifically in neurones in the developing mouse hypothalamus and cortex

Local formation of oestrogens from androgens by aromatase cytochrome P-450 within brain cells is crucial for the sexual differentiation of the mammalian CNS. Aromatase activity has been detected in several brain regions of the developing rodent brain. In the present study, we used a mouse-specific, peptide-generated, polyclonal aromatase antibody to determine whether neurones and/or glial cells in the developing brain are involved in androgen aromatization and if aromatase-immunoreactive (Arom-IR) cells exhibit a sex-specific distribution and regional-specific morphological characteristics. For these experiments, gender-specific cell cultures were prepared from embryonic day 15 mouse hypothalamus and cortex. Specificity of the immunoreaction was confirmed by Western-blot analysis and by inhibition of aromatase activity using tissue homogenates from mouse ovaries and male newborn hypothalamus and from male hypothalamic cultures with known aromatase activity, respectively. Arom-IR cells were found in both hypothalamic and cortical cultures. Double-labeling experiments revealed that Arom-IR cells co-stained only for the neuronal marker MAP II, but never for glial markers. Therefore aromatase immunoreactivity is specifically neuronal. Regional differences in the morphology of Arom-IR neurones were observed between both brain regions. In hypothalamic cultures, IR-neurones represented a heterologous population of phenotypes (magnocellular, small bipolar and multipolar neurones with long processes showing varicose-like structures or without processes). Cortical Arom-IR neurones were always oval in shape with short or no IR-processes. Sexual dimorphisms in numbers of Arom-IR neurones were found in the hypothalamus with significantly higher cell numbers in male cultures.(ABSTRACT TRUNCATED AT 250 WORDS)

Gender-specific brain formation of oestrogen in behavioural development

Steroid sex hormones have an organisational role in the development of brain mechanisms underlying gender-specific behaviour. Although peaks in gonadal androgen occur at developmental stages that coincide with sensitive periods for the differentiation of both structural sex differences in the brain and sexual behaviour, the factors that control the phasic effects of steroids are still not understood. Aromatase, converting androgen to oestrogen, is a key enzyme in development, and regulation of the activity of this enzyme is likely to be one of the factors determining availability of oestrogen effective for brain differentiation. Measurement of testosterone metabolism in vitro shows that in the mouse oestrogens are formed actively in the neonatal brain during male development. In cultured cells of the embryonic mouse hypothalamus there are sex differences in hypothalamic aromatase activity both during early embryonic and later perinatal development, with a higher capacity for oestrogen formation in the male than in the female. The sex differences are regionally specific, since no differences in aromatase activity are detectable in cultured cortical cells between male and female. Aromatase activity is neuronal rather than astroglial. Using a specific antibody to the mouse aromatase, immunoreactivity is also restricted to neuronal soma and neurites in hypothalamic cultures. Therefore, gender-specific differences in aromatase regulation are probably restricted to neurons. Testosterone increases oestrogen formation specifically in cultured hypothalamic neurones, but has no effect on cortical cells. Although there is a sex difference in early embryonic neuronal aromatase, aromatase activity appears to be sensitive to androgen only in later embryonic development. What determines the phasic sensitivity of the developing brain aromatase system to androgen has still to be determined.

Inhibition of hypothalamic aromatase activity by 5 Beta-dihydrotestosterone

Abstract A variable amount of circulating testosterone that reaches brain cells is converted to biologically inactive 5beta-reduced metabolites, namely, 5beta-dihydrotestosterone (5beta-DHT) and 5beta-androstane-3alpha,17beta-diol (5beta,3alpha-diol). In avian species, the production of inactive 5beta-DHT and 5beta,3alpha-diol is highest during embryonic and post-hatching life. In the present study, we have investigated the possibility that 5beta-reduction may not only correspond to a steroid inactivation pathway, but that 5beta-reduced metabolites of testosterone may exert direct inhibitory effects on enzymatic pathways producing biologically active steroids. When added to hypothalamic homogen-ates prepared from adult male doves, 5beta-DHT but not 5beta,3alpha-diol inhibits the activity of the aromatase enzyme, which converts testosterone to 17beta-oestradiol. During the first days after hatching, when the production of 5beta-reduced metabolites is high, the hypothalamic aromatase is also inhibited by 5beta-DHT. We conclude that a high 5beta-reductase activity during sensitive periods for sexual differentiation may protect the avian brain from the differentiating effects of circulating androgens by inhibiting the production of oestrogen.

Testosterone metabolism in the avian hypothalamus

Many central actions of testosterone (T) require the transformation of T into several metabolites including 5 alpha-dihydrotestosterone (5 alpha-DHT) and estradiol (E2). In birds as in mammals, 5 alpha-DHT and E2, alone or in combination, mimic most behavioral effects of T. The avian brain is, in addition, able to transform T into 5 beta-DHT, a metabolite which seems to be devoid of any behavioral or physiological effects, at least in the context of reproduction. By in vitro product-formation assays, we have analyzed the distribution, sex differences and regulation by steroids of the 3 main T metabolizing enzymes (aromatase, 5 alpha- and 5 beta-reductases) in the brain of the Japanese quail (Coturnix c. japonica) and the zebra finch (Taeniopygia guttata castanotis). In the hypothalamus of quail and finches, aromatase activity is higher in males than in females. It is also decreased by castration and increased by T. The activity of the 5 alpha-reductase is not sexually differentiated nor controlled by T. The 5 beta-reductase activity is often higher in females than in males but this difference disappears in gonadectomized birds and no clear effect of T can be observed at this level. The zebra finch brain also contains a number of steroid-sensitive telencephalic nuclei [e.g. hyperstriatum ventrale, pars caudale (HVc) and robustus archistriatalis (RA)] which play a key role in the control of vocalizations. These nuclei also contain T-metabolizing enzymes but the regulation of their activity is substantially different from what has been observed in the hypothalamus. Aromatase activity is for example higher in females than in males in HVc and RA and the enzyme in these nuclei is not affected by castration nor T treatment. In these nuclei, the 5 alpha-reductase activity is higher in males than in females and the reverse is true for the 5 beta-reductase. These sex differences in activity are not sensitive to gonadectomy and T treatment and might therefore be organized by neonatal steroids. We have been recently able to localize aromatase-immunoreactive (AR-ir) neurons by ICC in the brain of the quail and zebra finch. Positive cells are found in the preoptic area, ventromedial and tuberal hypothalamus. AR-ir material is found in the perikarya of cells and fills the entire cellular processes including axons. At the electron microscope level, immunoreactive material can clearly be observed in the synaptic boutons. This observation raises questions concerning the mode of action of estrogens produced by central aromatization of T.

Developmental sex differences in brain aromatase activity are related to androgen level

Sex differences in the metabolism of testosterone (T) in the developing brain of quail were examined using an in vitro microassay. During each developmental stage (day before hatching, hatching and 2 days after hatching) aromatase activity was higher in hypothalamic areas than in a control neostriatal area. There was no sex difference in oestradiol-17 beta (E2) formation in the late embryonic brain or at hatching. But aromatase activity in the male preoptic-anterior hypothalamic area was 50% higher than in females by day 2. No regional differences in brain 5 beta-reductase activity were detected at any of the developmental stages sampled. There was a sex difference in production of catabolic 5 beta-reduced metabolites. Male 5 beta-reductase activity declined continuously from high embryonic levels in all areas, whereas female enzyme activity showed an increase at hatching. In contrast to plasma progesterone, levels of T were higher in the male than in the female by day 1 after hatching. We suggest that elevated circulating T in the male after hatching may account for the sexual dimorphism in brain aromatase activity.

Effects of the nonsteroidal inhibitor R76713 on testosterone-induced sexual behavior in the Japanese quail (Coturnix coturnix japonica)

A new triazole derivative, R76713 (6-[4-chlorophenyl)(1H-1,2,4-triazol-1-yl)methyl]-1-methyl-1H- benzotriazole), was recently shown to inhibit aromatase selectively without affecting other steroid-metabolizing enzymes and without interacting with estrogen, progestin, or androgen receptors. This compound was tested for its capacity to intefere with the induction of copulatory behavior by testosterone (T) in castrated Japanese quail (Coturnix coturnix japonica). In a first experiment, R76713 inhibited (range 0.01 to 1 mg/kg) the activation of sexual behavior by T silastic implants and hypothalamic aromatase activity in castrated male quail in a dose-dependent manner. The 5 alpha- and 5 beta- reductases of T were not systematically affected. Stereotaxic implantation of R76713 in the medial preoptic area similarly blocked the behavior activated by systemic treatment with T, demonstrating that central aromatization of androgen is implicated in the activation of behavior. These inhibiting effects of R76713 on behavior were observed when implants were placed in the medial part of the nucleus preopticus medialis, confirming the implication of this brain area in the control of male copulatory behavior. Finally, the behavioral inhibition produced by R76713 could be reversed by simultaneous treatment with a dose of estradiol, which was not behaviorally effective by itself. This suggests that the behavioral deficit induced by the inhibitor was specifically due to the suppression of estrogen production. This also shows that the activation of copulatory behavior probably results from the interaction of androgens and estrogens at the brain level, as the two treatments separately providing these hormonal stimuli (T with the aromatase inhibitor on one hand and a low dose of estradiol on the other hand) had almost no behavioral effects but they synergized to activate copulation when given concurrently. These data confirm the critical role of preoptic aromatase in the activation of reproductive behavior and demonstrate that R76713 is a useful tool for the in vivo study of estrogen-dependent processes.

Immunocytochemical localization of aromatase in the brain

An immunocytochemical peroxidase-antiperoxidase procedure using a purified polyclonal antibody raised against human placental aromatase was used to localize aromatase-containing cells in the Japanese quail brain. Immunoreactive cells were found only in the preoptic area and hypothalamus, with a high density of positive cells being present in the sexually dimorphic medial preoptic nucleus, in the ventromedial nucleus of the hypothalamus and in the infundibulum. The positive material was localized in the perikarya and in adjacent cytoplasmic processes. Aromatase-containing cells were a specific marker for the sexually dimorphic preoptic nucleus. Treatment with testosterone produced a 6-fold increase in the aromatase activity of the preoptic area and a 4-fold increase in the number of immunoreactive cells in the medial preoptic nucleus. Thus, the increase in aromatase activity observed after testosterone administration is caused by a change in enzyme concentration.

Correlation between the sexually dimorphic aromatase of the preoptic area and sexual behavior in quail: effects of neonatal manipulations of the hormonal milieu

The aromatase of the preoptic area is significantly more active in males than in females. This sex dimorphism in enzyme activity is still found in birds that have been gonadectomized and treated with a same dose of testosterone. This suggests that the sex difference is not the result of a differential activation by the adult hormonal environment but rather is organized neonatally by steroid hormones. As the central aromatization of testosterone is a limiting step in the activation of copulatory behavior by testosterone, the lower aromatase activity in the preoptic area of females might be responsible, at least in part, for their lower sensitivity to the activating effects of testosterone on behavior. Three experiments were carried out to determine whether early manipulations of the hormonal environment, which are known to differentiate sexual behavior, also affect in a permanent way the aromatase activity in the preoptic area. Injection of estradiol benzoate into male embryos on day 9 of incubation decreased the preoptic aromatase activity in parallel to its demasculinizing effect on behavior. Unexpectedly the same treatment tended to increase enzyme activity in females so that the physiological relevance of the observed enzymatic change remains questionable. In two independent experiments, we confirmed that neonatal ovariectomy of female quail interferes with their behavioral differentiation. Females gonadectomized at 4 days post-hatch showed significantly more male-type sexual behavior as adult in response to testosterone than females gonadectomized at the age of 5 weeks. These experiments also confirmed that the preoptic aromatase activity is higher in males than in females but no evidence for an effect of the age of gonadectomy on the enzyme activity could be obtained. The sex difference and experimental modifications observed in the aromatase activity of the preoptic area were not seen in the posterior hypothalamus demonstrating that these effects are specific. The mechanisms controlling the sex difference in aromatase activity are discussed. The difference might be organized by the action of embryonic steroids as suggested by the changes observed in males injected with estradiol benzoate in egg. Alternatively, activational mechanisms cannot be ruled out at present. In one experiment, the activity of the preoptic aromatase was positively correlated with the sexual activity of the birds.(ABSTRACT TRUNCATED AT 400 WORDS)

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.

Sexual differentiation in quail: critical period and hormonal specificity

There is a discrepancy between results showing that male quail are demasculinized by exogenous estrogens only if the treatment is given before Day 12 of egg incubation and results showing that ovariectomy of females after hatching still affects their sexual differentiation which leads to the conclusion that female demasculinization by ovarian estrogens is a continuing process extending into posthatching life. The first experiment was performed to test different models which have been proposed to reconcile these apparently contradictory results. Male and female quail were treated with 0, 5, or 25 micrograms of estradiol benzoate (EB) on either Day 9 or Day 14 of embryonic life. Birds were castrated at the age of 4 days to avoid the confounding effects of postnatal gonadal hormones and were treated as adults with testosterone (T). Whereas EB-treatment demasculizined sexual behavior and cloacal gland growth of males when administered on Day 9, it was without effect on Day 14. This result confirms the presence of a "critical period" for sexual differentiation of behavior in embryonic life. However, the time course of sexual differentiation and the sensitivity to the demasculinizing actions of estrogens were not the same for different behavioral and morphological characteristics. Some dependent variables such as plasma levels of luteinizing hormone and crowing were still affected by the EB treatment on Day 14. These results show that the whole process of demasculinization is not retricted to the "critical period" ending on Day 12 of incubation. A second experiment was performed to determine if 5 beta-dihydrotestosterone (5 beta-DHT), a metabolite of testosterone, also exerts demasculinizing effects during embryonic life. A large dose of 5 beta-DHT (2 mg/egg) had no effects on behavior and morphology in males if administered on Day 9 of egg incubation. This suggests that 5 beta-DHT, which is a steroid devoid of behavioral effects in the adult bird, is also an inactive compound as far as sexual differentiation of the quail is concerned. The high 5 beta-reductase activity which was previously identified in the hypothalamus of the embryonic quail thus probably plays a protective role. By transforming testosterone into inactive nonaromatizable androgens, it prevents male embryos from being demasculinized by their endogenous testosterone acting through aromatization.