Progesterone decreases mating and estradiol uptake in preoptic areas of male monkeys.

Synthetic progestins such as medroxyprogesterone acetate (MPA) are used widely in the treatment of male sex offenders. In male cynomolgus monkeys (Macaca fascicularis) treated with testosterone (T), both MPA and progesterone (P) had comparable inhibitory effects on male sexual motivation and behavior. To determine if P, like MPA, decreases endogenous T levels, plasma T and P levels were analyzed in weekly blood samples (N=186) from eight intact males, each paired with a sexually receptive female before, during, and after treatment with subcutaneous Silastic P implants (336 behavior tests). P treatment decreased sexual activity but not plasma T levels. To ascertain if P, like MPA, acts by decreasing the nuclear uptake of T by brain, four P-treated and four control males were euthanized 60 min after intravenous injection of 3 mCi of [3H]T. The nuclear uptake of unchanged [3H]T and its metabolites [3H]E(2) and [3H]DHT was measured in samples of brain, pituitary gland, genital tract, and liver. P, unlike MPA, did not affect the nuclear uptake of [3H]androgens by brain, but reduced by 80% the nuclear accumulation of [3H]E(2) in tissue samples containing preoptic area and the anterior part of the bed nucleus of stria terminalis, although not in samples from hypothalamus or amygdala.

Estrogen in the medial preoptic area of male rats facilitates copulatory behavior.

Mating was studied in sexually experienced, gonadally intact male rats assigned to two surgical groups matched on the basis of mean mounting frequency during behavioral screening trials conducted prior to the study. Estradiol (E(2)) was delivered bilaterally into the medial preoptic area (MPO) of experimental males by means of hormone-coated implants, and fadrozole was given sc (0.25 mg/kg/day) via osmotic minipumps to block E(2) formation from testicular testosterone throughout the brain. Control males received blank bilateral implants in the MPO and sc fadrozole. After the completion of behavioral testing, immunocytochemical comparisons of the brains from experimental and control rats were made using the H222 antiestrogen receptor (ER) antibody, whose labeling is inhibited by the presence of E(2). The histology demonstrated that E(2) was confined exclusively to the MPO of experimental males but was absent throughout the brains of controls. In controls, mounting decreased significantly by the 7th day after surgery compared with presurgical levels and did not recover. In contrast, on all postsurgical days, the mounting frequency of the experimental group was significantly higher than that of controls. Although experimental males also showed an initial, significant postsurgical decline in mounting frequency, it recovered completely by the 28th postoperative day. Ejaculations declined significantly after surgery in both groups but, unlike in controls whose performance remained low, ejaculations in experimental males partially recovered and were significantly higher than in controls during the postoperative period. Results showed that ER-containing neurons in the MPO influence male rat copulatory behavior.

Conversion of testosterone to estradiol may not be necessary for the expression of mating behavior in male Syrian hamsters (Mesocricetus auratus).

Male sexual behavior is mediated in part by androgens, but in several species, mating is also influenced by estradiol formed locally in the brain by the aromatization of testosterone. The role of testosterone aromatization in the copulatory behavior of male Syrian hamsters is unclear because prior studies are equivocal. Therefore, the present study tested whether blocking the conversion of testosterone to estradiol would inhibit male hamster sexual behavior. Chronic systemic administration of the nonsteroidal aromatase inhibitor Fadrozole (2.0 mg/kg/day) for 5 or 8 weeks did not significantly increase mount latency or reduce mount frequency, intromission frequency, ejaculation frequency, or anogenital investigation relative to levels shown by surgical controls. However, Fadrozole effectively inhibited aromatase activity, as evidenced by the suppression of estrogen-dependent progesterone receptor immunoreactivity in the male hamster brain. The JZB39 anti-progesterone receptor antibody labeled significantly more neurons in brains of sham-treated hamsters than in brains of Fadrozole-treated hamsters. These data suggest that aromatization of testosterone to estradiol is not necessary for normal mating behavior in Syrian hamsters.

Effects of mating on c-fos expression in the brains of male macaques.

The c-fos polyclonal anti-c-fos antibody was used to examine the effects of mating on Fos expression in brain neurons of 11 male macaques. Behavior tests were for 30 min, five males were unmated, four were mated, and two were social controls. Mated males were killed 60 min after ejaculation. Social controls were paired with females, but mating did not occur. Fos immunoreactive (Fos-ir) neuronal nuclei were counted in nine brain regions extending from the medial preoptic to the mammillary body area of all males. In contrast to previous reports on nonprimate laboratory species, overall there was as much Fos-ir in unmated as in mated males. Moreover, there was significantly less Fos expression in four brain regions (known to contain steroid receptors), namely, ventromedial hypothalamus, arcuate nucleus, lateral mammillary area, and bed nucleus of stria terminalis, of mated than of unmated males. There were no significant differences between mated and unmated males in the 5 other brain regions studied. These findings may reflect taxonomic differences between primates and nonprimates, or result from greater neural activation in feral animals maintained in a laboratory than in domesticated, inbred laboratory species. The simplest interpretation would be that neural activity in the male primate is turned off by mating in some brain sites but not in others.

Colocalization of androgen receptors and mating-induced FOS immunoreactivity in neurons that project to the central tegmental field in male rats.

Bilateral lesions of the central tegmental field (CTF) in male rats virtually eliminate mating behavior. This study examined if mating-induced Fos expression (a measure of neuronal activation) and androgen receptors (AR) are colocalized in brain and spinal cord neurons which project to the CTF. Animals received unilateral injections of the retrograde tracer Fluorogold (FG) in the lateral part of the CTF (CTFl), and 10 days later were killed after ejaculating with females. Brains and spinal cords were examined for FG transport, AR-immunoreactivity (AR-ir), and Fos-immunoreactivity (Fos-ir). AR-ir and Fos-ir were visualized with fluorescence microscopy using cyanine-conjugated and fluorescein-conjugated secondary antibodies. The CTFl received projections from AR-containing neurons in forebrain structures (bed nucleus of stria terminalis, medial preoptic area, lateral and ventromedial hypothalamus), in the central amygdala and various mid- and hindbrain structures (dorsolateral tegmentum, superior and inferior colliculi, pedunculopontine nucleus), and in the lumbosacral spinal cord (lamina X). Some of the AR-containing neurons in bed nucleus of stria terminalis and in the dorsal part of the medial preoptic area with projections to the CTFl were activated by mating. Most AR-containing neurons in spinal lamina X with projections to the CTFl were also activated by mating. Information from spinal cord and pontine nuclei and from outputs descending from the forebrain may be relayed in the CTFl. Thus, as part of a network of hormone-sensitive neurons linking brain and spinal cord mechanisms for mating, the CTFl could participate in the integration of visceral and somatic information relevant for sexual behavior.

Fos induced by mating or noncontact sociosexual interaction is colocalized with androgen receptors in neurons within the forebrain, midbrain, and lumbosacral spinal cord of male rats.

This study was designed to determine the extent to which Fos immunoreactivity (induced either by mating or noncontact sociosexual interaction) and androgen receptor (AR) immunoreactivity are colocalized in brain and spinal cord of male rats. Some males (Mated) were allowed to mate to ejaculation; others (Social Controls) were placed with females but physical contact was prevented by a wire mesh screen; remaining males (Isolated) were placed alone in the test jar for the duration of the test period. After testing, brains and spinal cords were examined for AR and Fos immunoreactivity (ir). PG21 anti-AR and anti-c-fos primary antibodies were visualized by fluorescence microscopy using cyanine-conjugated and fluorescein-conjugated secondary antibodies. In both brain and spinal cord, the number of Fos-ir neurons varied according to group: Mated males > Social Controls > Isolated males. Fos was highly localized in subsets of AR-ir neurons within the medial preoptic nucleus, bed nucleus of the stria terminalis, dorsomedial nucleus of the amygdala, and central tegmental field. Fos was also localized in subsets of AR-ir neurons within the L5, L6, and S1 segments of the spinal cord. Spinal cord concentrations of AR-ir and Fos-ir neurons were greatest in Lamina X, and the vast majority of Fos-ir neurons in the dorsal part of Lamina X were also AR-ir. Thus, in both brain and spinal cord, androgen-sensitive neurons are active during mating, and transmission of sexually relevant information from cord to brain is probably accomplished via hormone-sensitive spinal neurons.

Androgen receptor and mating-induced fos immunoreactivity are co-localized in limbic and midbrain neurons that project to the male rat medial preoptic area.

Two studies were designed to document neuronal colocalization of androgen receptor immunoreactivity and mating-induced Fos immunoreactivity (AR-ir, Fos-ir) in brain of male rats and to examine the extent to which limbic and midbrain neurons that project to the preoptic area are androgen sensitive and activated by mating. Brains from male rats, killed 1 h after ejaculating with receptive females, were examined for Fos-ir and AR-ir and compared with those from control rats not given access to females. PG21 anti-AR and anti-c-fos primary antibodies were visualized by fluorescence microscopy using cyanine-conjugated and fluorescein-conjugated secondary antibodies. In mated males (Expt. 1), Fos-ir and AR-ir were colocalized in neurons of the medial preoptic nucleus (MPN), the dorsal medial amygdala (dMEA), the central tegmental field (CTF), the bed nucleus of the stria terminalis, the anterior hypothalamus, the lateral hypothalamus, and the ventral premamillary nucleus. In Expt. 2, male rats received a unilateral injection of the retrograde tracer FluoroGold (FG) in the preoptic area and four days later were killed after ejaculating with receptive females. Brains were subsequently examined for FG transport, Fos-ir and AR-ir. Fluorogold-containing neurons were present in dMEA and CTF as well as in other hypothalamic and limbic regions known to project to the MPN. In dMEA and CTF, nuclear colocalization of AR-ir and mating-induced Fos-ir was present in a proportion of FG-containing neurons. Sexually relevant information may be carried through the brain by an interconnected network of hormone-sensitive neurons.

Androgen receptors and estrogen receptors are colocalized in male rat hypothalamic and limbic neurons that express Fos immunoreactivity induced by mating.

Conversion of testosterone into estradiol is important for male rat sexual behavior, and both steroids probably contribute to mating. The distributions of neurons containing androgen receptors (AR) and estrogen receptors (ER) overlap, and many AR-immunoreactive (AR-ir) neurons express Fos immunoreactivity (Fos-ir) induced by mating. Because mating-induced Fos-ir in the male rat occurs mainly in AR-ir neurons, and because both steroids are important for mating, we hypothesized that (i) AR-ir and ER-ir are colocalized and that (ii) some of these neurons are activated during mating. We examined, in adjacent sections from the medial preoptic area (MPN) through the central tegmental field (CTF), the expression of ER-ir in: (i) AR-ir-containing neurons, and (ii) Fos-ir-expressive neurons. PG21 anti-AR, OA-11-824 anti-c-fos, H222 or 1D5 anti-ER primary antibodies were visualized, respectively, with cyanine-conjugated, fluorescein- or cyanine-conjugated, and fluorescein-conjugated secondary antibodies in male rats which were killed 1 h after ejaculating with a receptive female. In MPN, bed nucleus of the stria terminalis (BNST), and medial amygdala (MEA), 80-90% of ER-ir labeling occurred in AR-ir-positive neurons but only about 30% of AR-ir neurons were ER-ir-positive. No ER-ir was found in the CTF. This suggests the presence of three types of brain neurons sensitive to gonadal steroid hormones: neurons sensitive to androgens only, neurons sensitive to both androgens and estrogens, and neurons sensitive to estrogens only. About 50% of ER-ir labeling occurred in cells expressing mating-induced Fos-ir but only about 30% of Fos-ir neurons were ER-ir-positive. These findings suggest that, in the MPN, at least two different neuronal populations are activated during mating: the first contains AR-ir only and the second contains AR-ir and ER-ir. In the BNST and MEA, at least three hormonally sensitive populations are activated during mating: the two described above plus a third population which expresses ER-ir only.

Effects of progesterone on the sexual behavior of castrated, testosterone-treated male cynomolgus monkeys (Macaca fascicularis).

In male cynomolgus monkeys the synthetic progestin, medroxyprogesterone acetate (MPA), decreases testosterone (T) levels and sexual behavior, binds to progestin receptors in brain, and reduces by about 70% the uptake of [3H]androgens by both brain and genital tract tissues. To examine the behavioral effects of progesterone (P) itself, eight castrated, T-treated males were each tested twice weekly with an estrogenized female before, during, and after they were treated with two SC Silastic P implants. Data from six 4-week treatment periods were analyzed to facilitate comparisons with our previous data using MPA: i) baseline, ii) weeks 4-7 of P treatment, iii) weeks 8-11 of P treatment, iv) weeks 1-4 after P implants were removed, v) weeks 5-8 after P withdrawal, and finally vi) weeks 9-12 after P withdrawal (384 1 h behavior tests). Weekly blood samples (N = 192) were analyzed by radioimmunoassay to determine plasma levels of both T and P. P treatment, which resulted in high plasma P levels (about 44 ng/ml), produced decrements in measures of male sexual behavior and motivation that were both qualitatively and quantitatively similar to those produced by MPA treatment but, unlike MPA, P did not decrease plasma T levels or change them in any way (about 850 ng/100 ml throughout). The findings suggest that P implants may be preferable to weekly MPA injections in the treatment of male sex offenders because they require less patient compliance and may not have MPA's troubling side effects.

Androgen receptor immunoreactivity and mating-induced Fos expression in forebrain and midbrain structures in the male rat.

The distribution of androgen receptor immunoreactive-neurons, mapped with the PG21 anti-androgen receptor antibody, was compared in male rat brains with the distribution of Fos-immunoreactive neurons induced by mating. In gonadally intact, but not in castrated male rats, substantial numbers of androgen receptor-containing neurons were present in a variety of forebrain and midbrain regions. The PG21 antibody apparently had a higher affinity for occupied than for non-occupied androgen receptors. Androgen receptor-immunoreactive regions included the medial preoptic area and other forebrain areas previously identified as containing androgen receptors, the dorsal and ventral periaqueductal gray, and a midbrain region that included the lateral part of the central tegmental field, part of the caudal zona incerta, the subparafascicular nucleus of the thalamus and the peripeduncular nucleus. Fos-expressive neurons were essentially absent in non-mated males but were present in the brains of rats which mated to ejaculation. All brain regions in which androgen receptor-immunoreactive neurons were counted also expressed Fos immunoreactivity after mating, and there was considerable overlap between the distributions of androgen receptor- and Fos-immunoreactive neurons. In a second experiment, we used immunofluorescent techniques to document the intraneuronal co-localization of Fos with androgen receptor immunoreactivity in the medial preoptic area, medial amygdala, and central tegmental field. In these regions mating-induced Fos immunofluorescence was exclusively localized in androgen receptor-immunofluorescent neurons. However, not all androgen receptor neurons were Fos expressive, suggesting that only some androgen-sensitive neurons were activated during mating. These results are consonant with the view that hormone actions on forebrain and midbrain structures influence the neuronal activity correlated with mating.

Behavioral responses to Depo-Provera, Fadrozole, and estradiol in castrated, testosterone-treated cynomolgus monkeys (Macaca fascicularis): the involvement of progestin receptors.

Sexual motivation and behavior decreased in male cynomolgus monkeys given either Depo-Provera (medroxyprogesterone acetate, MPA), which reduces androgen uptake by brain, or the nonsteroidal aromatase inhibitor, Fadrozole, which virtually eliminates the conversion of testosterone (T) to estradiol (E2) in brain. This suggested that both unchanged T and E2 are important for the control of male primate sexual behavior, but combined treatment with MPA and Fadrozole did not have the anticipated summatory effects in intact males: the behavioral decrements when MPA-treated males were given Fadrozole were about half those observed when Fadrozole was given alone. The present study tested the hypothesis that Fadrozole suppressed the behavioral effects of MPA by preventing the induction by E2 of progestin receptors in the brain to which MPA binds. Eight castrated, T-treated males were each tested with an estrogenized female i) during baseline, ii) during MPA treatment, iii) during treatment with MPA and Fadrozole together, and iv) with E2 treatment added to condition (iii) (256 1-h behavior tests). All dosages were those used in previous studies. Sexual motivation, as reflected in mounting attempts and mounting attempt latencies, was further diminished by E2 treatment in males receiving both MPA and Fadrozole, but ejaculatory activity was not changed. Immunocytochemistry demonstrated that the distributions of progestin and androgen receptors were little affected by MPA treatment, and that progestin receptor immunoreactivity was almost completely abolished in the brains of males receiving both MPA and Fadrozole but present in those receiving additional E2 treatment, findings that supported the hypothesis.

Distribution of androgen receptor-like immunoreactivity in the brains of cynomolgus monkeys.

A polyclonal antibody, PA1, raised in a rabbit against fusion proteins containing fragments of the human prostatic androgen receptor (AR) was used to map the distribution of AR-like immunoreactivity in the brains of adult male and female cynomolgus monkeys. PA1 AR-immunoreactive (ARir) labeling occurred in the cell nuclei and, more weakly, in the cytoplasm of brain cells. The PA1 ARir labeling occurred primarily in brain regions previously shown on the basis of gonadal steroid autoradiography to contain androgen receptors. However, the distribution of PA1 ARir staining was substantially more restricted than that of autoradiographic labeling using 3H-androgens. The pattern of PA1 ARir labeling was closely similar between animals and occurred in the lateral septum, medial preoptic area, bed nucleus of stria terminalis, anterior, cortical, accessory basal and medial amygdala, several hypothalamic nuclei including the supraoptic, anterior, paraventricular, ventromedial and arcuate nuclei, and the premammillary nucleus. No significant sex differences were observed. With the exception of the supraoptic nucleus, reported not to be labeled by autoradiography, earlier autoradiographic findings and the current immunocytochemical results, although not congruent, have noteworthy similarities.

Intracerebral infusion of an aromatase inhibitor, sexual behavior and brain estrogen receptor-like immunoreactivity in intact male rats.

Copulatory behavior was studied in five groups of sexually experienced, gonadally intact male rats in which: (i) the nonsteroidal aromatase inhibitor Fadrozole (CIBA-Geigy CGS 16949A) was delivered bilaterally (0.756 microgram in 6.0 microliters saline in 24 h to each side) into the medial preoptic area (POM) together with normal saline given s.c. via osmostic minipumps (n = 10); (ii) normal saline was delivered bilaterally into POM together with the same dose of Fadrozole s.c. (n = 9); (iii) Fadrozole was delivered bilaterally into the lateral preoptic area together with normal saline given s.c. (n = 6); (iv) Fadrozole was delivered bilaterally into the cerebral cortex together with normal saline given s.c. (n = 6), and (v) unoperated controls (n = 14). Mounting and ejaculation were significantly decreased in rats receiving Fadrozole in POM compared with the behavior of rats in the other 4 groups. Few differences occurred between rats in the latter 4 groups, all of which continued to mate. The H222 and ER-715 anti-estrogen receptor (ER) antibodies were used to examine the distribution of ER immunoreactive (ERir) neurons in hypothalamic and limbic sites in gonadectomized controls and in some of the rats in groups i, ii and v. Since labeling of ERir neurons in rat brain with the H222 anti-ER antibody is reported to be inhibited by estrogen, it was used here to identify regions (with staining) where the aromatization of testosterone (T) into estradiol (E2) had been suppressed. Intense H222 ERir nuclear neuronal labeling was confined to the POM of males receiving Fadrozole in POM, and significantly more labeled neurons were found in the POM of these rats than in the POM of rats treated with saline in POM. In contrast, the ER-715 antibody, which is reported to stain neurons independently of hormonal status, labeled neuronal nuclei in hypothalamic and limbic regions of all groups, demonstrating the presence of ER. These findings show that conversion of T into E2 in the POM of the male rat is important for male rat copulatory behavior and that H222 ERir nuclear neuronal labeling can be used to identify the neurons in POM that were affected by Fadrozole.

Effects of testosterone and aromatase inhibition on estrogen receptor-like immunoreactivity in male rat brain.

The H222 and ER-715 anti-estrogen receptor (ER) antibodies were used to examine the distribution of ER immunoreactive (ERir) neurons in hypothalamic and limbic sites of: (i) castrated male rats; (ii) castrated males implanted s.c. with silastic capsules containing testosterone (T), and (iii) castrated males receiving T together with 0.25 mg/kg/day of the nonsteroidal aromatase inhibitor, fadrozole (CIBA-Geigy CGS 16949A), delivered s.c. by means of implanted osmotic minipumps. Because labeling of ERir neurons in rat brain with H222 anti-ER antibody is reported to decrease when estrogen is present, it was used here to determine whether or not estrogen derived from the aromatization of T would affect ERir neuronal labeling. Castrated males showed H222 ERir-positive neurons in the lateral septum, medial preoptic area, several subdivisions of the hypothalamus, amygdala, and bed nucleus of stria terminalis. In contrast, in T-treated castrates, H222 ERir labeling was either eliminated or greatly reduced in all brain areas with the exception of the lateral septum. In castrated male rats given T together with fadrozole, H222 ERir labeling was restored in all brain areas where it had been reduced by T treatment. The ER-715 antibody effectively labeled neurons in all brain regions independently of the treatment condition, indicating that ER was present in the brains of animals in all treatment groups. These findings point to functional differences in ER dynamics in brain areas implicated in the control of sexual behavior by male rats.(ABSTRACT TRUNCATED AT 250 WORDS)

The spatial organization of the peripheral olfactory system of the hamster. Part I: Receptor neuron projections to the main olfactory bulb.

The spatial organization of projections from olfactory receptor neurons to the main olfactory bulb (MOB) was studied in hamsters by using fluorescent stilbene isothiocyanates as retrograde tracers. Injections confined to small sectors of the MOB produce labeling of receptor neurons that is more restricted circumferentially (i.e., with respect to the medial-lateral and dorsal-ventral axes) than longitudinally (i.e., with respect to the rostral-caudal axis) along the mucosal sheet. This restricted labeling is also discontinuous, giving an initial impression that the peripheral input is only crudely organized with respect to the medial-lateral and dorsal-ventral axes of the nasal cavity. However, from analyses of serial sections, it is apparent that each set of mucosal segments shares convergent projections to a circumferential quadrant of the MOB with other segments that are positioned around a common domain of the nasal cavity airspace. The primary afferent projections to the MOB, thus, are organized rhinotopically (i.e., with respect to the three-dimensional position of receptor neurons in olfactory space) rather than mucosotopically.

The spatial organization of the peripheral olfactory system of the hamster. Part II: Receptor surfaces and odorant passageways within the nasal cavity.

The spatial organization of olfactory receptor surfaces and odorant passageways within the nasal cavity was studied in hamsters through descriptive and morphometric analyses of a complete stereotaxically defined series of coronal, sagittal, and horizontal sections through the snout. These analyses reveal that the caudal two-thirds of each cavity is divided into two longitudinally oriented medial and lateral channels. The olfactory mucosa that lines these two channels projects selectively onto the medial and lateral halves of the main olfactory bulb (MOB), respectively. Moreover, the ethmoturbinates of the caudal recesses create highly convoluted channels, lined by ventrally projecting mucosa, that lie ventral, lateral, and dorsal to a relatively smooth central channel lined by dorsally projecting mucosa. The rhinotopic map makes equivalent representations of medial and lateral olfactory space to the MOB but gives the smooth space lined by dorsally projecting mucosa a disproportionately larger representation on the MOB than the convoluted space lined by the more expansive ventrally projecting mucosa. Recent descriptions of the spatial distribution of probes for odorant receptor proteins conform closely to this organization, giving credence to the idea that rhinotopy is a basis for representing to the MOB the specific molecular features of odorant molecules.

Distribution of androgen receptor-like immunoreactivity in the brains of intact and castrated male hamsters.

The distribution of androgen receptor-like (AR) immunoreactivity was mapped in brains of (a) intact, sham-castrated and (b) castrated male hamsters. The pattern of AR-immunoreactive (AR-ir) staining was, in general, similar to that reported for gonadal steroid autoradiography of the male hamster brain. Moreover, with one exception, AR-like staining was similar in intact and castrated males, and occurred in the medial preoptic area, bed nucleus of stria terminalis, amygdala, hippocampus, thalamus, and several hypothalamic nuclei including the periventricular, supraoptic, and ventromedial nuclei, and median eminence. However, while AR-ir labeling was virtually absent in the lateral septum of intact males, it was clearly present in the lateral septum of castrated males. The view that androgen receptors in brain generally decline after castration received no support from this study.

Enhanced responses of nucleus accumbens neurons in male rats to novel odors associated with sexually receptive females.

One group of male rats was trained to associate novel odors with three different environmental conditions: the presence of (i) a sexually receptive female (RF), (ii) an unreceptive female (UF) and (iii) no other rat (NO). A second group of males received no training. Single units in nucleus accumbens (NAC) were then recorded in anesthetized animals and their responsiveness to various odors was tested. Odors that had been associated with receptive females during training evoked significantly more unit responses in NAC than did the same odors in untrained males. There were no differences between trained and untrained males in the numbers of units responsive to odors associated with unreceptive females and with the empty training chamber. In trained animals, both the percentage of responding units and the magnitude of olfactory-evoked responses were significantly larger with RF-associated odors than with either UF or NO odors. Both of these effects were more pronounced in rats that had ejaculated with females during training than in rats that had not. Findings demonstrated that pairing odors with the presentation of sexually receptive females enhanced the responsiveness of NAC neurons to those odors and indicated a role for NAC in associating environmental stimuli with natural reward processes.

Effects of the nonsteroidal aromatase inhibitor, Fadrozole, on sexual behavior in male rats.

The new nonsteroidal aromatase inhibitor, Fadrozole (CGS 16949A, CIBA-Geigy Corp.), was tested for its ability (i) to inhibit the conversion of testosterone (T) to estradiol (E2) in brain and (ii) to suppress male sexual activity. Sprague-Dawley rats were castrated and immediately given sc Silastic T-implants and osmotic minipumps delivering 2.5 mg/kg/day Fadrozole (N = 4), 0.25 mg/kg/day Fadrozole (N = 4), or water (N = 4 controls). T-implants were removed after 6 days and, 3 days later, 3H-T (1 microCi/g) was given as an iv bolus. No 3H-E2 was detected in hypothalamic or amygdaloid nuclear pellets from Fadrozole-treated males but this metabolite predominated in controls. However, nuclear concentrations of 3H-T and [3H]dihydrotestosterone were similar in all groups. In another group of males (N = 18), brain aromatase activity was reduced by more than 96% at the 0.25 mg/kg dose level. Additional castrated, T-implanted males received minipumps delivering 0.25 mg/kg/day Fadrozole (six males) or water (six behaviorally matched controls) and were tested weekly with receptive females. After 2 weeks, ejaculations were reduced by 77% compared with controls (P less than 0.01) and, after 4 weeks, intromissions were also significantly reduced (P less than 0.05) but less so (48%). Radioenzymatic estimates of plasma aromatase inhibitor levels remained elevated throughout Fadrozole treatment. These males were then given Silastic E2 implants: intromissions increased significantly in 1 week (P less than 0.01), but ejaculations remained below control values. Results supported the view that aromatization is important for sexual behavior in male rats and suggested that Fadrozole has utility for studying the mechanisms by which testosterone affects behavior.

Immunohistochemical labeling of androgen receptors in the brain of rat and monkey.

Androgen receptor antibodies have recently been developed using fusion proteins containing fragments of human prostatic androgen receptor. We have used a polyclonal antibody raised in rabbits to label androgen receptors in brain sections from male and female rats and monkeys. Free-floating frozen sections were incubated in primary antibody, and processed by the peroxidase-avidin-biotin complex method using biotinylated anti-rabbit IgG. Nickel intensified diaminobenzidine was used as the chromagen, and neurons were labeled in the amygdala, hippocampus, bed nucleus of stria terminalis, septum, preoptic area, in several hypothalamic nuclei including the supraoptic and paraventricular nuclei, in several brain stem motor nuclei and in cerebral cortex. Staining was most intense in cell nuclei but also occurred in cytoplasm and in some neuronal processes. Labeling was more restricted in monkey than in rat brain. Omitting the primary antibody or pre-incubating the primary antibody with rat prostatic cytosol for control purposes demonstrated the specificity of staining.