Metabolism of testosterone in the anterior pituitary gland and the central nervous system of the European starling (Sturnus vulgaris)

Aromatase inhibition abolishes courtship behaviours in the ring dove (Streptopelia risoria) and reduces androgen and progesterone receptors in the hypothalamus and anterior pituitary gland

The aim of this study was to determine in the ring dove, the effects of aromatase inhibition on the expression of aggressive courtship and nest-soliciting behaviours in relation to the distribution of cells containing immunoreactive androgen (AR) and progesterone (PR) receptor in the hypothalamus and pituitary gland. Isolated sexually experienced ring doves were transferred in opposite sex pairs to individual breeding cages, and then injected with the aromatase inhibitor, fadrozole (four males and four females), or saline vehicle (four males and four females) for 3 days at 12 hourly intervals. Saline-injected control males displayed aggressive courtship behaviours (bow-cooing and hop-charging) and nest-soliciting throughout the study, and control females displayed nest-soliciting. By day 3, fadrozole treatment resulted in the disappearance of all these behaviours and in a decrease or disappearance of AR and PR in the anterior pituitary gland, and in the nucleus preopticus paraventricularis magnocellularis (PPM), nucleus preopticus medialis (POM), nucleus hypothalami lateralis posterioris (PLH), and ventral, lateral and dorsal nucleus tuberalis in the hypothalamus (VTu, LTu, DTu). In the nucleus preopticus anterior (POA), fadrozole treatment decreased AR in both sexes and decreased PR in females but not in males. Cells containing co-localized nuclear AR and PR were found in all hypothalamic areas examined, and in the anterior pituitary gland. Fadrozole is suggested to reduce the local availability of estrogen required indirectly for the induction of AR, and except in cells containing PR in the male POA, for the direct induction of PR. It is suggested that aggressive courtship behaviour is terminated by "cross talk" between aromatase-independent PR and aromatase-dependent AR co-localized in neurons in the POA. Aromatase-independent PR may increase in the male POA in response to visual cues provided by a partner. Aromatase-dependent PR in the POM, and basal hypothalamus may play a role in the facilitatory effect of progesterone on estrogen-induced nest-orientated behaviours.

Seasonal variation in androgen-metabolizing enzymes in the diencephalon and telencephalon of the male European starling (Sturnus vulgaris)

In seasonally breeding songbirds, seasonal fluctuations occur in serum testosterone (T) concentrations and reproductive behaviours. Many T-dependent behaviours are regulated by the activity of androgenic and oestrogenic metabolites within specific brain regions. Male European starlings breed in spring when circulating T concentrations peak. T and its metabolites act within portions of the diencephalon to regulate the pituitary-gonadal axis and to activate courtship and copulation. Song in male starlings is critical for mate attraction during the breeding season and is regulated by steroid-sensitive nuclei in the telencephalon and diencephalon. Outside the breeding season, T is undetectable, however, males continue to sing at high levels. This suggests that singing outside of the breeding season might not be T-dependent as it appears to be in the spring. Alternatively, singing when T is low might continue to be regulated by T due to increased sensitivity of the brain to the action of the steroid. This increased sensitivity could be mediated by changes in intracellular T metabolism leading to increased production of active or decreased production of inactive metabolites. To explore the relationship between T-metabolism and reproductive behaviour, we analysed seasonal changes in the activity of four brain T-metabolizing enzymes: aromatase, 17beta-hydroxysteroid dehydrogenase (17beta-HSDH), 5alpha-reductase (all three convert T into active metabolites) and 5beta-reductase (converts T into an inactive metabolite) in the diencephalon and telencephalon. In the anterior and posterior diencephalon, the highest aromatase was observed in spring when this region is critical for courtship and copulation. In the telencephalon, aromatase was highest and 5beta-reductase was lowest throughout the winter months well prior to the reproductive season and these enzymes presumably maximize T-activity within this region. Although these data do not indicate whether the metabolic changes occur specifically within song nuclei, these findings are compatible with the idea that singing in male starlings outside the breeding season may be regulated by steroids despite the presence of low serum T concentrations. Overall, seasonal changes in T-metabolizing enzymes appear to play a significant role in seasonal changes in behaviour and reproductive physiology.

Changes in central steroid receptor expression, steroid synthesis, and dopaminergic activity related to the reproductive cycle of the ring dove

This review examines possible neural mechanisms involved in the expression of parental behavior in the ring dove, Streptopelia risoria. This avian species has proved an excellent animal model for studies concerning endocrine-behavior interactions for many years. Studies were performed to localize the expression of central androgen and progesterone receptor in both sexes. Expression of androgen receptor (androgen receptor immunoreactivity, AR-ir) was widespread but increased, similarly in both sexes, with increasing day-length. Progesterone receptor-immunoreactivity (PR-ir) was more localized in several discrete areas of the hypothalamus. Similarly, no sex differences were observed in PR-ir, and expression increased in birds maintained on long days. AR-ir demonstrated dramatic changes over the breeding cycle, being greatest in courting birds and almost undetectable in parenting birds of both sexes brooding their young. PR-ir showed a differential expression over the breeding cycle relative to its hypothalamic localization. PR-ir decreased in the tuberal hypothalamic area in brooding birds of both sexes; whereas in the preoptic area, PR-ir was maintained. Significant increases in dopaminergic activity during the parenting phase of the breeding cycle occurred in specific neural regions including the PVM and DMA. Studies demonstrated the ability of the diencephalon of both sexes of the ring dove brain to synthesize progesterone, with indications that in the male brooding dove, synthesis is increased. Finally, a model is presented that proposes a mechanism whereby these central systems may interact to result in the expression of full parental behavior in both sexes of the ring dove.

Immunohistochemical localization of 3 beta-hydroxysteroid dehydrogenase and 5 alpha-reductase in the brain of the African lungfish Protopterus annectens

The localization of the enzymes responsible for the biosynthesis of neurosteroids in the brain of dipnoans has not yet been determined. In the present study, we investigated the immunohistochemical distribution of 3 beta-hydroxysteroid dehydrogenase (3 beta-HSD) and 5 alpha-reductase (5 alpha-R) in the brain and pituitary of the African lungfish Protopterus annectens by using antibodies raised against type I human 3 beta-HSD and type I human 5 alpha-R. The 3 beta-HSD and 5 alpha-R immunoreactivities were detected in cell bodies and fibers located in the same areas of the lungfish brain, namely, in the pallium, thalamus, hypothalamus, tectum, and periaqueductal gray. Identification of astrocytes, oligodendrocytes, and neurons with antisera against glial fibrillary acidic protein, galactocerebroside and neurofilaments revealed that, in the lungfish brain, 3 beta-HSD immunolabeling is expressed exclusively by neurons, whereas the 5 alpha-R-immunoreactive material is contained in both neurons and glial cells. In the pituitary gland, 3 beta-HSD- and 5 alpha-R-like immunoreactivity was localized in both the pars distalis and the pars intermedia. The present study provides the first immunocytochemical mapping of two key steroidogenic enzymes in the brain and pituitary of a lungfish. These data strongly suggest that neurosteroid biosynthesis occurs in the brain of fishes, as previously shown for amphibians, birds, and mammals.

Neuroactive steroids and the constraint of memory

Different normo- and pathophysiological conditions are associated with large variations in plasma and brain concentrations of neuroactive steroids. In an attempt to specify the possible role of these steroids in memory processes, we examined the ability of pregnanolone, a positive modulator of the gamma-aminobutyric acid type A (GABAA) receptor complex, to sustain state dependence in rats. Animals treated with either saline or different doses of pregnanolone were trained to complete a fixed ratio 10 (FR10) schedule of lever presses for milk reward within 120 s, and were tested for the retention of this response 48 h later while treated with the same or a different treatment. The data indicate that saline-to-drug as well as drug-to-saline state changes produced robust failures to recall the response. Furthermore, animals trained with pregnanolone showed transfer of the response when tested with the benzodiazepine chlordiazepoxide and vice versa. The partial benzodiazepine inverse agonist N-methyl-beta-carboline-3-carboxamide (FG-7142) antagonized the states produced by both pregnanolone and chlordiazepoxide. State changes constitute a mechanism of action that may operate endogenously; the release of neuroactive steroids in response to various physiological conditions may act to contain but also to constrain memories associated with these events, rendering these memories inaccessible on other occasions. The apparent memory impairment that can so be produced may render the effects of past experience available in a manner that is appropriately selective.

Avian neurosteroids. I. Pregnenolone biosynthesis in the quail brain

The present study was carried out to determine steroid biosynthesis from cholesterol in the brain of adult male Japanese quails. As an initial step of the experiments, the concentrations of pregnenolone, dehydroepiandrosterone and their sulfate esters in the brain and plasma extracts were measured by specific radioimmunoassays (RIAs). To exclude the possibility that these steroids in the brain are derived from peripheral steroidogenic glands, hypophysectomized and sham-operated birds were used in this experiment. The pregnenolone concentration was much larger in the brain than in the plasma in these two groups. Hypophysectomy led to decreases in the plasma and brain pregnenolone concentrations, but the change in the brain was less pronounced than that in the plasma. Although pregnenolone sulfate ester, dehydroepiandrosterone and its sulfate ester were also detected in brain extracts, those levels were low in both hypophysectomized and sham-operated birds. The biochemical demonstration of cholesterol metabolism was further conducted in intact mitochondria. When mitochondrial fractions obtained from the whole brain were incubated with cholesterol at 37 degrees C, the pregnenolone level in mitochondria increased as a function of incubation time. Finally, Western immunoblot analysis using a purified IgG with polyclonal antibodies against the purified bovine adrenal cytochrome P450scc was performed after SDS-gel electrophoresis of homogenates of the hypothalamus and preoptic area. A protein recognized the antibody as a band of electrophoretic mobility in the proximity of reference bovine P450scc. These results suggest that the brain produces pregnenolone from cholesterol in adult male Japanese quails. Most accumulation of pregnenolone in the brain may be independent of the peripheral endocrine gland system.

5 beta-reductase and other androgen-metabolizing enzymes in primary cultures of developing zebra finch telencephalon

Enzymes in the avian brain irreversibly catalyze the conversion of androgens into either active metabolites (aromatase and 5 alpha-reductase) or inactive metabolites (5 beta-reductase), 5 beta-reductase is thought to influence the formation of active metabolites by reducing the concentration of androgenic substrate available for these reactions. However, because these enzymes have different regional, cellular and subcellular distributions in brain, the traditional method to measure enzyme activity in brain homogenates may be inaccurate because of artificial mixing of enzymes. Recently, we have prepared primary cell cultures from the telencephalons of developing zebra finches. Cell cultures offer the advantage that enzyme activity can be measured in live cells in which the relative distribution of enzymes may more closely reflect that found in vivo. We have previously reported that aromatase is expressed at high levels in these cultures, and that it is active in both neurons and in glia. Here we report on the activities of 5 alpha- and 5 beta-reductase in these cell cultures. Along with aromatase, 5 beta-reductase was expressed at high levels in these mixed cell cultures, including cultures highly enriched in glia. This suggests that 5 beta-reductase is present in non-neuronal cells in brain, possibly co-localized with aromatase. However, despite the presence of 5 beta-reductase, aromatase was detected reliably in vitro even when the concentration of substrate was low. Thus, 5 beta-reductase does not prevent the synthesis of estrogen in the telencephalon of developing zebra finches. By contrast, 5 alpha-reductase activity was very low or absent in these cultures.(ABSTRACT TRUNCATED AT 250 WORDS)

Biochemical characterization and seasonal changes in the concentration of testosterone-metabolizing enzymes in the European great tit (Parus major) brain

Homogenates of diencephala obtained from brains of European great tits (Parus major) were incubated in the presence of tritiated testosterone (T) as precursor, and four metabolites produced from this steroid were formally identified and quantified. Conversion into 5 beta-dihydrotestosterone (5 beta-DHT) constituted the major metabolic pathway of T. Smaller amounts of 5 alpha-dihydrotestosterone (5 alpha-DHT), 5 beta-androstane-3 alpha, 17 beta-diol (5 beta-DIOL), and estradiol (E2) were also produced. The metabolism of T was time-dependent, and it varied as a function of the initial precursor concentration. The kinetics of 5 beta- and 5 alpha-reductases, as well as aromatase, followed the Michaelis-Menten model. It was found that 5 beta-reductase has a low apparent affinity for T, but is present in large concentrations. In contrast, the apparent affinity for T and the concentration of aromatase were approximately 3.9 times higher and 130 times smaller, respectively, than those of 5 beta-reductase. Intermediate values were found for 5 alpha-reductase. The validated assay was used to measure seasonal changes in the in vitro metabolism of T in the anterior (AH) and posterior (PH) hypothalamus and the cerebellum (CER) of free-living juvenile and adult male great tits. The production of 5 beta-DHT was low during the winter period in the PH of adult males, whereas the 5 beta-DIOL production was low in both parts of the hypothalamus at this time of the year. During autumn the production of these metabolites showed a transitory decrease in both parts of the hypothalamus of the juveniles. The production of 5 beta-reduced metabolites by the CER was high at all times of the year. In juveniles, the CER production of 5 beta-DHT did not change seasonally, whereas 5 beta-DIOL production peaked during summer. In the CER of adults, maximum production of both metabolites occurred during summer. Generally, less T was converted into 5 beta-reduced metabolites by the PH than by either the AH or the CER. E2 production was observed only in the AH and PH. With one exception (summer; AH), E2 production was high in both parts of the hypothalamus of adults throughout the year. In both AH and PH of juveniles, E2 production was low during summer. In these birds, it increased between summer and autumn in both parts of the hypothalamus, and also between autumn and winter in the PH. The production of 5 alpha-DHT did not change as a function of the season, the age of the birds, or the brain region.(ABSTRACT TRUNCATED AT 400 WORDS)

Purification of 5 beta-reductase from hepatic cytosol fraction of chicken

From the cytosol fraction (supernatant fluid at 105,000 g) of chicken liver, 4-en-3-oxosteroid 5 beta-reductase (EC 1.3.1.23) was purified by ammonium sulfate precipitation, followed by Butyl Toyopearl, DEAE-Sepharose, Sephadex G-75 and hydroxylapatite column chromatographies. The enzyme activity was quantitated from amount of the 5 beta-reduced metabolites derived from [4-14C]testosterone. During the purification procedures, 17 beta-hydroxysteroid dehydrogenase which was present in the cytosol fraction was separated from 5 beta-reductase fraction by the Butyl Toyopearl column chromatography. By the DEAE-Sepharose column chromatography, 3 alpha- and 3 beta-hydroxysteroid dehydrogenases were able to be removed from 5 beta-reductase fraction. The final enzyme preparation was apparently homogeneous on SDS-polyacrylamide gel electrophoresis. Purification was about 13,600-fold from the hepatic cytosol. The molecular weight of this enzyme was estimated as 37,000 Da by SDS-polyacrylamide gel electrophoresis and also by Sephadex G-75 gel filtration. For 5 beta-reduction of 4-en-3-oxosteroids, such as testosterone, androstenedione and progesterone, NADPH was specifically required as cofactor. Km of 5 beta-reductase for NADPH was estimated as 4.22 x 10(-6) M and for testosterone, 4.60 x 10(-6) M. The optimum pH of this enzyme ranged from pH 5.0 to 6.5 and other enzymic properties of the 5 beta-reductase were examined.

In vitro metabolism of testosterone on hepatic tissue of chicken (Gallus domesticus)

Among the subcellular fractions of chicken liver homogenates, the microsomal and cytosol fractions were most active in metabolism of testosterone with mutually different enzymological features. On the other hand, the nuclear and mitochondrial fractions had far lower activity of metabolizing the steroid. Metabolism by the cytosol fraction: the following steroids were identified as the metabolites of testosterone. 5 beta-Dihydrotestosterone (17 beta-hydroxy-5 beta-androstan-3-one), 5 beta-androstane-3 alpha,17 beta-diol and its 3 beta-epimer, 3 alpha-hydroxy-5 beta-androstan-17-one and its 3 beta-epimer and 5 beta-androstanedione. Metabolism by the microsomal fraction: from testosterone under aerobic condition, androstenedione was obtained as the major metabolite, besides the minor polar metabolites, production of which diminished when incubated in the atmosphere of carbon monoxide. From the results, testosterone was accepted to be firstly converted by the cytosol fraction into 5 beta-dihydrotestosterone which was then reduced to 5 beta-androstane-3 alpha,17 beta-diol and its 3 beta-epimer. These diols were further converted partially to 3 alpha -and 3 beta-hydroxy-5 beta-androstan-17-ones. These pathways were supported by the results of our incubation study with 5 beta-dihydrotestosterone and 5 beta-androstanedione as substrates. By the microsomes, testosterone was aerobically and anaerobically transformed to androstenedione as the major metabolite. Throughout our incubation experiments, no 5 alpha-reduction of a delta 4-3-oxo-steroid was detected in the chicken liver.

Aggressive behavior in birds: an experimental model for studies of brain-steroid interactions

1. Although testosterone (T) stimulates aggressiveness in males of many vertebrate species, it is now known that the full expression of T actions in the central nervous system requires aromatization to estradiol (E2) and subsequent binding of formed E2 to its receptor. 2. We have recently confirmed these as rate-limiting steps in the control of sex-related and individual differences in aggressiveness of the Japanese quail (Coturnix coturnix japonica). 3. In this review, we describe some of the neuroendocrine factors which control aggression with a focus on our recent studies in quail.

Accumulation of estrogen in a vocal control brain region of a duetting song bird

Tritiated estradiol (E) was injected into bay wrens (Thryothorus nigricapillus), a tropical species in which females sing complex vocal duets with males. Autoradiographic analysis revealed that males and females have equal proportions of cells labeled by estradiol or its metabolites (E target cells) in a telencephalic region involved in song: the caudal nucleus of the ventral hyperstriatum (HVc). Other forebrain song regions failed to show labeling by E. E or its metabolites were accumulated, however, by cells in the midbrain song region ICo (the intercollicular nucleus) and in hypothalamic regions. This pattern of accumulation in the song system differs from that observed in a previous study in which bay wrens were injected with tritiated testosterone (T); T or its metabolites were accumulated by cells in HVc, RA (robust nucleus of the archistriatum), MAN (magnocellular nucleus of the neostriatum), ICo, and nXII (hypoglossal (nucleus). Such comparison suggests that cells in HVc have different steroid accumulation properties from those in other song regions. Bay wrens differ from zebra finches (Poephilia guttata), in which HVc contains very few E target cells. The wrens are more similar to canaries (Serinus canarius), because both species have E target cells in HVc, and females of both species are able to sing. The interspecies comparison raises the question of whether the ability of HVc cells to accumulate E or its metabolites in both species constitutes a precondition for the bisexual potential for song production.

Androgen metabolism in the male hamster--2. Aromatization of androstenedione in the hypothalamus and in the cerebral cortex; kinetic parameters and effect of exposure to different photoperiods

It has been demonstrated that exposure of the hamster to a short photoperiod (light on less than 12 h/day) induces an increased sensitivity of the hypothalamic-pituitary axis to the feedback effect of testosterone. It was consequently felt of interest to investigate whether the photoperiod might act by increasing the formation of estrogens in the CNS and/or in the anterior pituitary. The aromatase activity was studied utilizing a sensitive in vitro assay that measures the amount of 3H2O formed during the conversion of [1 beta-3H]androstenedione to estrone. First of all it has been investigated whether the aromatizing enzymes, previously found in the hypothalamus, were present also in the cerebral cortex and in the anterior pituitary; secondly, the kinetic parameters of the enzyme were determined; finally, the possible variation of the central aromatase activity in hamsters exposed to a long or to a short photoperiod was investigated. The results obtained indicate that both in the hypothalamus and in the cerebral cortex the aromatization of androstenedione is linear with respect to time of incubation and tissue concentration; moreover, in the two structures, the enzyme demonstrated a similar Michaelis-Menten constant (0.03 and 0.08 microM respectively). From a quantitative point of view, the hypothalamus seems to possess an aromatizing activity higher than that of the cerebral cortex. Exposure of the hamsters to a short photostimulation for 60 days resulted in a significant regression of the reproductive system (decreased testicular weight and serum LH levels) and in a decrease of the aromatase activity of the hypothalamus. There was no effect of the photoperiod on the aromatase of the cerebral cortex. Since androgens are known to stimulate the aromatase, the present data might be tentatively interpreted by suggesting that the variation in the formation of estrogens during the short photoperiod might be the consequence of the decreased serum testosterone levels typical of the hamster in the quiescent gonadal period.

Testosterone metabolism and its testosterone-dependent activation in the uropygial gland of quail

The in vitro metabolism in the uropygial gland of the male quail results into large yields of 5 beta-reduced and/or 17 alpha-hydroxylated metabolites. This metabolism was studied in glands of sexually quiescent quails five days after a single intra-muscular injection of testosterone to the birds. This treatment led to an increased production of inactive metabolites (epitestosterone and its 5 beta-reduced metabolites) and to a decrease of unmetabolized testosterone. Thus testosterone controls its own metabolism and by this way means to modulate its action in the uropygial gland of quail.

Androgen metabolism in the male hamster--1. Metabolism of testosterone in the pituitary gland and in the brain of animals exposed to different photoperiods

It is known that the metabolism of testosterone in the brain and in the anterior pituitary is different in mammalian and in photoperiodic avian species. In many mammalian species, testosterone is mainly metabolized to 5-alpha-reduced compounds (e.g. 17-beta-hydroxy-5-alpha-androstan- 3-one, 5 alpha-DHT and 3-alpha,17-beta-dihydroxy-5-alpha-androstane, 5-alpha,3-alpha-diol) and, to a smaller extent, to 4-androstene-3,17-dione (androstenedione), while in birds, androstenedione is the main testosterone metabolite and the conversion to the 5-alpha-reduced compounds is quantitatively negligible. In avian species, testosterone is also converted to 5-beta-reduced steroids (mainly 17-beta-hydroxy-5-beta-androstan-3-one, 5-beta-DHT and 3-alpha,17-beta-dihydroxy-5-beta-androstane, 5-beta,3-alpha-diol), and there is also evidence that in these species testosterone metabolism in the central structures may be influenced by the photoperiod. Since the hamster is a mammal whose reproductive cycle is controlled by day length, it has been analyzed whether: (a) the central structures of the hamster (cerebral cortex, hypothalamus and anterior pituitary) metabolize testosterone in vitro following a mammalian (5-alpha-reduced derivatives) or an avian (androstenedione and 5-beta-reduced compounds) pattern; and (b) the metabolism of testosterone in the same structures may be modified by the exposure to different photoperiods (LD 14:10 or LD 8:16). The present data indicate that no one of the hamster structures examined produces the 5-beta-reduced derivatives. Moreover, the formation of the 5 alpha-DHT is quantitatively low, and is not affected by the photoperiod. In contrast, androstenedione is formed in quite high yields and the exposure of the animals to 60 days of short photostimulation increases the formation of this steroid in the pituitary gland, but not in the brain structures. From these data, it appears that the central structures of the hamster metabolize testosterone with a pattern which is intermediate between that of birds and mammals.

A comparison of aromatase, 5 alpha-, and 5 beta- reductase activities in the brain and pituitary of male and female quail (C. c. japonica)

In numerous vertebrate species including Japanese quail (Coturnix coturnix japonica), actions of testosterone (T) on neuroendocrine target tissues are mediated in part by conversion to estrogenic and androgenic metabolites. In order to assess which pathways were favored in each identified androgen target area in quail brain and whether there were discernible sex differences, we developed an assay for simultaneously quantifying aromatase, 5 alpha-, and 5 beta-reductase. In addition, we made the first definitive identification of aromatase in quail pituitary and compared all three enzyme activities in the pituitary of males and females. Enzymes were measured in tissue homogenates by the conversion of [3H]androstenedione to [3H]estrone, [3H]5 alpha-androstanedione, and 5 beta-androstanedione. Aromatase activity was restricted to limbic tissues (anterior hypothalamus greater than posterior hypothalamus greater than septum greater than archistriatum containing nucleus taenia) while hyperstriatum, cerebellum, and midbrain containing nucleus intercollicularis were aromatase-negative. Quail pituitary aromatized androgen at rates equivalent to anterior hypothalamus/pre-optic area (aHPOA). 5 alpha- and 5 beta-reductase were present in all tissues tested. Aromatase was significantly higher in aHPOA and pituitary of males, whereas 5 alpha-reductase was significantly higher in female pituitary. These data suggest that a complex of androgen-metabolizing enzymes controls the neuroanatomic (spatial) distribution of active hormone in neuroendocrine tissues and that quantitative differences between males and females may account for sex differences in behavior.

Aromatase and 5 alpha-reductase in the teleost brain, spinal cord, and pituitary gland

The distribution of aromatase and 5 alpha-reductase was investigated in the brain, spinal cord, and pituitary of adult goldfish (Carassius auratus) and toadfish (Opsanus tau) of both sexes. Tissue homogenates were incubated with [3H]androstenedione in the presence of an NADPH-generating system and, following validation of assay conditions, radiolabeled products (estradiol, estrone, 5 alpha-androstanedione), were measured as an index of enzyme activity. Neuroendocrine tissue of both species produced exceptionally large amounts of estrogen, thus confirming previously observed differences between teleosts and other vertebrates. By contrast, 5 alpha-reductase levels resembled the vertebrate norm. In general, aromatase was concentrated in the pituitary and various forebrain regions, especially the hypothalamus/preoptic area; however, estrogen yields from the medulla and anterior spinal cord of toadfish were high compared to adjacent midbrain, hindbrain, and cord regions. This same neural region in toadfish, but not in goldfish, is known to control a sex dimorphic behavior, the courtship boatwhistle. In contrast to aromatase, 5 alpha-reductase was more uniformly distributed throughout the brain, although somewhat higher activity was obtained in the pituitary. High levels of aromatase in the neuroendocrine tissues of teleosts recommend them as animal models for further studying the enzyme, its regulation, and its role in governing androgen-dependent responses in central targets.

Effect of progesterone on the sexual behavior of the male Japanese quail

The reduced metabolites of testosterone produced in the central nervous system of birds are known to be involved in the regulation of male sexual behavior. Since progesterone may compete with testosterone for 5 alpha- and 5 beta-reduction, it may also interfere with the sexual behavior of birds. In order to test this hypothesis, progesterone was administered to male quail either transferred from short days to long days or kept in short days and treated with testosterone. Sexual behavior and crowing were scored at intervals for 21 days and the size of the cloacal gland was measured at the same times. On Day 21, the birds were killed and their testes were weighed. The administration of a large dose (1 mg/day) of progesterone depressed the sexual behavior of the birds stimulated either by long days or by the administration of testosterone. It is suggested that progesterone may compete with testosterone for the active sites of 5 alpha- and 5 beta-reductase; alternatively, its effect may be due to an antiandrogenic activity.

Hormonal mediation of reproductive behavior

Reproductive capability requires synchronization of both endocrine and behavioral components of reproduction. The classic view of reproductive behavior was that there was simply direct stimulation of a behavioral response by the appropriate gonadal steroid. However, it has become clear with recent developments in the field of behavioral endocrinology that the relationship of hormonal and behavioral processes is complex. In addition to the complexity of the mechanisms involved, other factors, both social and environmental, influence both the endocrine and behavioral responses. This paper provides an overview of selected issues within the field of behavioral endocrinology which deal with mechanisms of hormonal induction of behavior at various stages of the life cycle and with factors that interact with these processes.

Brain testosterone metabolism in thyroidectomized and thyroxine-treated chickens

The metabolism of testosterone to reduced derivatives was studied in the pituitary gland, the hypothalamus, and the hyperstriatum dorsale of thyroidectomized, sham-operated, and thyroxine (T4)-injected immature cockerels. The levels of plasma thyroid hormones were markedly reduced (P less than 0.001) in thyroidectomized cockerels whereas thyroidectomized or sham-operated birds injected daily with 100 micrograms/kg thyroxine had significantly elevated (P less than 0.001) levels in comparison with sham-operated control birds. Each tissue was found to produce significant amounts of 5 beta-androstane-17 beta-ol-3-one (5 beta-DHT), 5 beta-androstane-3 alpha, 17 beta-diol (5 beta-3 alpha-diol), and androstenedione. Irrespective of thyroid state 5 beta-DHT and 5 beta-3 alpha-diol were produced to the greatest extent by the hyperstriatum dorsale whereas androstenedione was maximally produced in the pituitary gland. In comparison with the hyperstriatum dorsale and the hypothalamus only small quantities of 5 beta-DHT were produced in the pituitary gland. In the hyperstriatum dorsale of thyroidectomized birds both 5 beta-DHT (P less than 0.05) and 5 beta-3 alpha-diol (P less than 0.1) were formed to a greater extent than in sham-operated birds. This effect was reversed by administration of T4 to the operated birds which reduced the levels to those measured in the sham-operated controls. Similarly, injection of T4 into sham-operated birds decreased (P less than 0.05) the production of 5 beta-DHT in the hypothalamus while in the pituitary gland injection of T4 into thyroidectomized birds reduced the production of androstenedione (P less than 0.05). It was concluded that in the cockerel thyroid hormone is likely to play a role in the metabolism of testosterone. The physiological significance of 5 beta-reductase activity in the neuroendocrine tissues is discussed.

Partial characterization of testosterone-metabolizing enzymes in the quail brain

The properties of 5 beta-reductase, 5 alpha-reductase and aromatase, 3 testosterone metabolizing enzymes, were studied in the quail brain by an in vitro incubation technique. The results describe the changes in time of metabolite production and the effects of temperature, enzyme and cofactor concentrations. The apparent Km and Vmax were evaluated for the 3 enzymes. Aromatase and 5 alpha-reductase have a higher affinity but a lower capacity than 5 beta-reductase. The kinetics of the latter enzyme are complex and suggest the presence of two types of enzymes. These characteristics fit in well with the role probably played by the enzymes in vivo.

Developmental profile of plasma androgens in cockerels genetically selected for mating frequency

Plasma levels of androstenedione (AE), testosterone (T), and dihydrotestosterone (DHT) were measured at 1, 56, 112, and 168 days of age by radioimmunoassay in lines of cockerels divergently selected for male mating frequency. Values for total androgen (total A = AE + DHT + T) were also computed. No significant differences in mean hormone values were found between lines at any age. Hormone patterns throughout development were also similar for both lines. Plasma AE and T increased between Days 1 and 56, stabilized through Day 112, and rose again prior to 168 days of age. In contrast, DHT levels were low throughout Day 112 and rose significantly by Day 168. Total A in the high mating line was low throughout Day 112 with significant increases occurring by Day 168. In the low mating line, total A was low on Day 1, increased significantly by Day 56, and it remained unchanged through Day 112. Peak values occurred by Day 168. Within line correlation analyses between AE, T, DHT, and total A revealed a more uniform hormonal state throughout development in the high mating line than in the low mating line. Because no differences were found between the mating lines in baseline levels of individual androgens or in concentration patterns of androgens up through the attainment of sexual maturity, it appears that neither posthatch baseline levels nor posthatch temporal androgen concentrations control male sexual behavior in the mating lines of birds.

Sexual differences in the Japanese quail: behavior, morphology, and intracellular metabolism of testosterone

Three experiments were carried out to study whether differences in the intracellular metabolism of testosterone (T) can explain sexually differential responses to T in Japanese quail. In the first experiment, a series of dose-response curves in which length of Silastic testosterone implants was related to effects on several behavioral and physiological variables was established. In Experiment 2, adult males and females were assigned to six experimental groups: intact males and females (I-males and I-females), castrated males and females implanted subcutaneously with 40-mm Silastic implants of T (T-males and T-females), and castrated males and females without hormone treatment (CX-males and CX-females). No CX-bird (male or female) and no I-female exhibited male sexual behavior. However, I-males and T-males regularly copulated during the behavioral tests. No crowing was ever heard in CX-animals and I-females. T-females crowed less than T-males and their crowing sounded weaker than those of males. The cloacal glands of T-females were less developed than those of males. Radioimmunoassay of T and 5 alpha-DHT showed that T-males and T-females have similar plasma levels of androgens. No striking differences were observed in the way testosterone is metabolized by the pituitary gland and central nervous tissues of males and females. By contrast, the production of 5 alpha-dihydrotestosterone (5 alpha-DHT) and 5 alpha-androstane-3 alpha, 17 beta-diol (5 alpha, 3 alpha-diol) was higher in the cloacal glands of males than in those of females. These sex differences were not detected between T-males and T-females. In experiment 3, the cloacal gland of males produced more 5 alpha-reduced metabolites than those of females. The pituitary gland of females also produced more 5 beta-androstane-3 alpha, 17 beta-diol (5 beta, 3 alpha-diol). In syringeal muscles, the production of 5 beta-dihydrotestosterone (5 beta-DHT) and 5 beta, 3 alpha-diol was higher in females compared to males.

Is the 5 alpha-reductase of the hypothalamus and of the anterior pituitary neurally regulated? Effects of hypothalamic deafferentations and of centrally acting drugs

The following experiments have been performed in order to verify whether the conversion of testosterone into its 5 alpha-reduced metabolites, 5 alpha-androstane-17 beta-ol-3-one (DHT), 5 alpha-androstane-3 alpha,17 beta-diol (3 alpha-diol) and 5 alpha-androstane-3 beta,17 beta-diol (3 beta-diol), in the hypothalamus and in the anterior pituitary is controlled by neural stimuli. Long-term castrated male rats have been submitted to anterior and total deafferentations of the hypothalamus and to the administration of the following centrally acting drugs: reserpine, p-chlorophenylalanine pCPA and atropine sulphate. The possible involvement of the central opioid system has also been investigated utilizing morphine and naloxone. Neither hypothalamic deafferentations, nor the treatment with reserpine, pCPA, atropine, morphine or naloxone produce any significant modification in the metabolism of testosterone in the hypothalamus. Hypothalamic deafferentations and treatments with reserpine, morphine and naloxone are also ineffective in changing the pattern of testosterone metabolism in the anterior pituitary. On the contrary, atropine and pCPA seem to affect the conversion of testosterone in the gland, both drugs producing an increased formation of DHT and 3 alpha-diol but not of 3 beta-diol. It is concluded that the 5 alpha-reductase-3-hydroxysteroid-dehydrogenase system of the hypothalamus does not appear to be controlled either neurally by inputs coming from other brain structures, or by variations of the neurotransmitter content in the hypothalamus itself. Serotonin and acetylcholine seem to participate in the control of testosterone metabolism at pituitary level, even if it is not clear whether their action takes place directly on the gland, or is mediated through some hypothalamic factor(s). Moreover, it does not appear that brain opioids are involved in the control of the enzymatic complex under consideration either in the hypothalamus or in the anterior pituitary.

Hormonal specificity and activation of sexual behavior in male zebra finches

Castrated zebra finches receiving one of six hormone treatments were given three weekly tests with different females and their sexual behavior was contrasted with that of two control groups consisting of intact or castrated males given implants of cholesterol. The six hormone treatments were: two aromatizable androgens, testosterone (T) and androstenedione (AE); two nonaromatizable androgens, androsterone (AN) and dihydrotestosterone (DHT); an estrogen, estradiol (E); or a combination of E + DHT. Half the males receiving DHT received the 5 alpha-isomer, half received the 5 beta-isomer. Castration significantly reduced the proportion of males which courted females, total courtship displays, high-intensity courtship displays, beak wiping activity, and significantly increased the latencies to show these behaviors compared to intact males. Castrated males never attempted to mount a female. All of these measures of courtship and copulatory behavior were restored to normal levels only by treatments providing both estrogenic and alpha-androgenic metabolites (i.e., T, AE, E + alpha DHT). AE was clearly the most effective of these, raising behavior significantly above normal on several measures. AN treatment was more effective than alpha DHT on all measures and not significantly different from intact birds on some. Treatment with E, alpha DHT, beta DHT, or E + beta DHT was totally ineffective. Surprisingly, females only solicited males whose hormone treatments provided estrogenic metabolites. Not only did they solicit males given aromatizable androgens, which showed high rates of courtship activity, they also solicited males given E or E + beta DHT, some of which never even courted. Castration and hormone treatment also affected body and syringeal weight, but in opposite directions. Castration increased body weight while decreasing syringeal weight. Hormone treatments providing alpha-androgenic metabolites decreased body weight and increased syrinx weight. Treatments supplying estrogen as well were slightly more effective.

5 beta- and 5 alpha-reductases for 4-ene-3-ketosteroids in golden hamster ovaries at different stages of development

Ovarian homogenates from 10-, 23- 128- and 60-day-old golden hamsters were incubated with [14C]-4-androstene-3,17-dione or [7-3H]-progesterone in the presence of NADPH and enzyme activities and metabolism of progesterone were estimated. A rapid increase in uterine weight was found around 28 days of age. The activity of 5 alpha-reductase was very high in the ovaries of 23-day-old hamsters (647 +/- 117 (SD) nmol/g tissue/h), high in those of 28-day-old hamsters (135 +/- 4) and low in those of 10- and 60-day-old animals (20 +/- 16, 39 +/- 11). However, the activity of 5 beta-reductase was high in all ovaries of golden hamsters at different stages of development (84-132 nmol/g tissue/h). The major C-21-17-hydroxysteroids and C19-steroids formed from progesterone by the ovaries of 23-day-old hamsters were 5 alpha-steroids such as 3 alpha, 17-dihydroxy-5 alpha-pregnan-20-one and androsterone, whereas those by the ovaries of 28- and 60-day-old hamsters were 4-ene-3-ketosteroids and 5 beta- and 5 alpha-steroids such as 17-hydroxy-4-pregnene-3,20-dione. 3 alpha, 17-dihydroxy-5 alpha- and 5 beta-pregnan-20-one, 4-androstene-3,17-dione, testosterone and androsterone. The formation of oestradiol-17 beta and oestrone from progesterone was found only in the ovaries of 38- and 60-day-old hamsters. These results show that similarly high levels of 5 beta-reductase are present in all ovaries from suckling, immature and adult golden hamsters and that high levels of 5 alpha-reductase are formed only in ovaries from immature hamsters, especially those with small uterus. The active 5 alpha-reduction of 4-ene-3-ketosteroids may be responsible for the decrease in the formation of oestrogens in immature hamster ovaries.

Metabolic control of the behavioural action of androgens in the dove brain: testosterone inactivation by 5 beta-reduction

In vitro studies of androgen metabolism in the dove brain show that testosterone is rapidly converted to 5 beta-reduced metabolites (5 beta-dihydrotestosterone and the two corresponding 3 alpha/3 beta diols). The preoptic region and the anterior ventromedial and posterior hypothalamus which are target areas for androgen action on behaviour and the neuroendocrine system show significantly less 5 beta-reduction than adjacent parolfactory, septal and striatal areas not directly involved in androgen action. In contrast to 5 alpha-reduction and aromatization, which lead to the formation of active metabolites in the dove brain, 5 beta-reduction is likely to be part of a testosterone (T) inactivation mechanism because: (a) intrahypothalamic implants of 5 beta-dihydrotestosterone were ineffective for male behaviour in the dove; (b) 5 beta-reduced metabolites of T were not detected in hypothalamic cell nuclei following intramuscular injection of tritiated testosterone, and were rapidly eliminated from brain cells; (c) the 4 beta-diols were also found to be a major product of T catabolism in the liver, a site of androgen inactivation. Long-term androgen deficit induced by castration increased 5 beta DHT formation in the preoptic area, but not in an adjacent parolfactory area. The increase was reversed by exogenous testosterone and oestradiol-17 beta indicating that the 5 beta-reduction pathway in an androgen-sensitive brain area is influenced by hormonal conditions. It is suggested that 5 beta-reduction is a testosterone inactivation pathway involved in the regulation of brain sensitivity to androgens.