Androgen metabolism by rat epididymis: 5. Metabolic conversion and nuclear binding after injection of 5α-androstane-3α,17β-diol, in vivo

The pattern of androgenic metabolites in blood, muscle, caput and cauda epididymidis has been investigated in functionally hepatectomized 24 hours castrated rats, 3 hours after the intra-muscular injection of 200 μCi of ³H -3α-diol. Identification of the radioactive metabolites showed only negligible differences between the epididymal regions. In both caput and cauda the main metabolite was DHT (17β-hydroxy-5α-androstane-3-one); 3α- and 3β-diol, androsterone (3α-hydroxy-5α-androstane-17-one), 5-A-dione (5α-androstane-3,17-dione), Δ¹⁶-3α-ol (5α-androst-l6-en-3α-ol), Δ¹⁶-3β-ol (5α-androst-l6-en-3α-ol) and Δ¹⁶-3-one (5α-androst-l6-en-3-one) were also present.$\text{Androsterone}$ and $\text{3α-diol}$ were the predominant metabolites in blood and muscle. No Δ¹⁶ compounds could be detected and in constrast to epididymis, more than 50% of the radioactivity was associated with polar compounds. From determination of total radioactivity, it was seen that retention by epididymis varied from two to four times that of muscle. Purification and identification of the radioactivity associated with the nuclear fraction demonstrated that DHT was the only nuclear bound androgen.It is suggested from these results that at least one effect of 3α-diol on the rat epididymis is exerted through its conversion to DHT.     

Androgen metabolism by rat epididymis. 2. Metabolic conversion of 3H-testosterone in vitro

The epididymis of adult rats metabolizes ³H-testosterone by experiments $\text{in}$$\text{vitro}$. After incubation of slices from epididymal tissue for 2 hrs at 37°C, 8% of the total radioactivity was found in the water-soluble fraction, whereas 92% in the ether soluble fraction (free steroids). The free steroids were examined further and the following metabolites identified: $\text{testosterone}$ (17β-hydroxy-4-androsten-3-one) 10,4%, $\text{androstendione}$ (4-androstene-3,17-dione) 6,2%, $\text{5α-A-dione}$ (5α-androstane-3,17-dione) 7,3%, $\text{DHT}$ (17β-hydroxy-5α-androstane-3-one) 39,3%, $\text{3α-diol}$ (5α-androstane-3α,17β-diol) 22,7%, $\text{3β-diol}$ (5α-androstane-3β,17β-diol) 4,6% and androsterone(3α-hydroxy-5α-androstan-17-one) 8,9%. The relative amount of each metabolite is given in per cent of the total radioactivity in the ether soluble fraction. When segments (caput, corpus, cauda) of epididymis were incubated in the same way, differences in steroid metabolism were demonstrated. Characteristic for caput epididymidis was high formation of DHT (58,4%) and 3α-diol (23,5%). Corpus epididymidis showed lower formation of DHT (50,6%) and 3α-diol (12,7%), but an approximately 3 times higher formation of 5α-A-dione (12,0%) than caput (3,4%) and cauda (3,5%). Cauda epididymis showed the lowest formation of DHT (38,3%), whereas 3α-diol (29,1%) and androsterone (11,4%) formation were relatively high. The ratio between 17β-hydroxy metabolites (DHT and androstanediols) and 17-keto metabolites were much higher in the caput (8,8) than in the corpus (3,2) and cauda (3,6), indicating a higher 5α-reductase activity in this segment.     

Neural uptake and metabolism of testosterone and dihydrotestosterone in the guinea pig

Neural tissues from adult, castrated male guinea pigs were examined for their capability to concentrate and metabolize [1,2-³H]testosterone (T) and [1,2-³H]dihydrotestosterone (DHT), both in vitro and in vivo. In vitro uptake of DHT and T was greater in the hypothalamus and anterior pituitary than in the cerebral cortex. With DHT as the substrate, the 800×g particulate concentration of this compound was highest in the hypothalamus, although in this tissue, particulate concentration was less than that of the cytoplasm. In the cerebral cortex 5α-androstane-3,17-dione was the most abundant metabolite, whereas 5α-androstane-3,17-dione, 5α-androstane-3α,17β-diol, and 5α-androstane-3β,17β-diol were all present in equivalent amounts in the hypothalamus and pituitary. Incubation with T resulted in the formation of DHT, 4-androstane-3,17-dione, and a compound with the mobility of 5α-(or 5β-)androstane-3,17-7-dione. The radioactivity associated with DHT was the most prevalent in the pituitary (1.3%), and least prevalent in the cerebral cortex (0.6%), and in all cases cytoplasmic concentration of this compound exceeded the concentration in the particulate fraction. Recrystallization failed to confirm the presence of estradiol-17β. Although there were no apparent tissue differences in the uptake of DHT or T 1 hour after their injection, intracellular distribution varied. In all tissues examined, that percentage of total radioactivity attributable to DHT was greatest in the 800×g particulate preparations, particularly in the hypothalamus. Thus neural tissues in the guinea pig, as in other species, exhibit differential uptake and metabolism of androgen through which physiological and behavioral effects may be mediated.     

Androgen metabolism by rat epididymis. 1. Metabolic conversion of 3 H-testosterone in vivo

The epididymis of adult rats metabolize ³H-testosterone by experiments $\text{in vivo}$. Thirty minutes after the injection of 100 μCi ³H-testosterone, some 10 per cent of the total radioactivity of the epididymis was found in the water-soluble fraction, whereas 90 per cent was found in the ether soluble fraction (free steroids). The free steroids were examined further and the following androgenic metabolites identified: $\text{testosterone}$ (17β-hydroxy-4-androsten-3-one) 8, 9%, $\text{androstendipne}$ (4-androstene-3, 17-dione, 2,7%,$\text{5α-A-dione}$ (5α-androstane-3, 17-dione) 6,5%, $\text{DHT}$ (17β-hydroxy-5α-androstan-3-one) 47, 2%, $\text{3β-diol}$ (5α-androstane-3β, 17β-diol) 4, 4%, $\text{3α-diol}$ (5α-androstane-3α,17β-diol) 20, 8% and $\text{androsterone}$ (3α-hydroxy-5α-androstan-3-one) 3,4%. The relative amount of each metabolite is given in per cent of total radioactivity in the ether soluble fraction.     

Testicular 3 alpha-hydroxysteroid oxidoreductase activity in the developing male rat.

In the testes, 17β-hydroxy-5α-androstan-3-one (dihydrotestosterone, DHT) is converted to 5α-androstane-3α,17β-diol (3α-diol) by the enzyme 3α-hydroxysteroid oxidoreductase (3α-HSO). This steroid has been shown to possess biological activity in the male rat. The secretion of 3α-diol is much greater in the prepubertal animal than in the adult. This study is designed to quantitate the activity of 3α-HSO in the cytosol fraction of testes from male rats throughout sexual development. Following homogenizatlon of whole testes, the 105,000 × g supernatant or cytosol fraction was incubated with ³H DHT and varying concentrations of unlabelled DHT in the presence of 0.25μm NADPH. The incubation was carried out at 34°C for 10 min at a pH of 7.4. The K_m of 3α-HSO in testicular cytosol was calculated to be 1.25μM. The specific activity of testicular cytosol 3α-HSO, expressed as pmoles of 3α-diol converted from DHT per min per mg testicular cytosol protein, was high in young rats from 10 to 22 days of age, and was followed by a decline between day 22 and 37, with activity remaining low throughout adulthood. Total testicular cytosol activity of 3α-HSO, expressed as nmoles of 3α-diol converted from DHT per min per pair of testes, gradually increased from day 10 to day 60 and remained high in the adult rat. In the post-pubertal period, a possible lack of available substrate, DHT, or possible endogenous testicular regulatory mechanisms acting on 3α-HSO activity might account for the actual decrease in 3α-diol concentration in the blood and testes of mature rats.     

Androgen regulation of progestin biosynthetic enzymes in FSH-treated rat granulosa cells in vitro

The influence of androgens on the FSH modulation of progestin biosynthetic enzymes was studied $\text{in vitro}$. Granulosa cells obtained from immature, hypophysectomized, estrogen-treated rats were cultured for 3 days in a serum-free medium containing FSH (20 ng/ml) with or without increasing concentrations (10^?9?10^?6 M) of 17β-hydroxy-5α-androstan-3-one (dihydrotestosterone; DHT), 5α-androstane-3α, 17β-diol (3α-diol), or the synthetic androgen 17β-hydroxy-17-methyl-4,9,11-estratrien-3-one (methyltrienolone; R1881). FSH treatment increased progesterone and 20α-hydroxy-4-pregnen-3-one(20α-OH-P) production by 10.2- and 11-fold, respectively. Concurrent androgen treatment augmented FSH-stimulated progesterone and 20α-OH-P production in a dose-related manner (R1881 > 3α-diol > DHT). In the presence of an inhibitor of 3β-hydroxysteroid dehydrogenase (3β-HSD), the FSH-stimulated pregnenolone (3β-hydroxy-5-pregnen-20-one) production (a 20-fold increase) was further enhanced by co-treatment with R1881, 3α-diol or DHT. Furthermore, FSH treatment increased 4.4-fold the activity of 3β-HSD, which converts pregnenolone to progesterone. This stimulatory action of FSH was further augmented by concurrent androgen treatment. In contrast, androgen treatment did not affect FSH-stimulated activity of a progesterone breakdown enzyme, 20α-hydroxysteroid dehydrogenase(20α-HSD). These results demonstrate that the augmenting effect of androgens upon FSH-stimulated progesterone biosynthesis is not due to changes in the conversion of progesterone to 20α-OH-P, but involves an enhancing action upon 3β-HSDΔ⁵, Δ⁴-isomerase complexes and additional enzymes prior to pregnenolone biosynthesis.     

In vitro conversion of 5alpha-reduced metabolites of testosterone by the seminal vesicles, ventral prostate glands and testes of adult rats

In order to ascertain the ability of rat seminal vesicles, testes and ventral prostate glands to interconvert 5α-reduced androgens, these three organs were incubated with either tritiated 17β-hydroxy-5αandrostan-3-one (5α-dihydrotestosterone,DHT), 5α-androstane-3α, 17βdiol (3α-diol) or 5α-androstane-3β, 17β-diol (3β-diol). The incubation environment utilized (Krebs-Ringer bicarbonate glucose buffer) was selected because the histologic appearance of the tissue at the conclusion of the incubation was indistinguishable from tissue fixed immediately after sacrifice of the animal, thereby approximating the physiologic conditions as closely as possible. In incubations of rat seminal vesicles, ³H.-3β-diol was not metabolized while 26.7 ± 3.8% of ³H-3α-diol appeared as DHT and 17.2 ± 1.5% of ³H-DHT was metabolized to 3α-diol. A small amount (7.5 ± 0.8%) of ³H-DHT was, however, converted to 3β-diol. In incubations of rat testes, the major metabolite, regardless of substrate, was 3α-diol. The conversion of 75.7 ± 2.1% of ³H-3β-diol to 3α-diol has demonstrated, for the first time, that this steroid can be metabolized by the rat testis. Rat ventral prostate glands metabolized $\text{18.5 ± 2.5\%}\text{of}{}^3\text{H-3β-}\text{diol}$ to DHT and 61± 2.9% of ³H-3α-diol to DHT. When ³H-DHT served as the substrate, 83.2 ± 1.5% remained unmetabolized. The prostate glands are, therefore, capable of metabolizing 3β-diol to DHT.     

Metabolism of tritiated C19 steroids by shionogi mouse mammary tumors

In the present report, the metabolism of dehydroepiandrosterone, 5-androstene-3β, 17β-diol and androstenedione has been studied in two different Shionogi tumors, one is androgendependent (“androgen sensitive”) and grows in intact male mice and the other is apparently androgen-independent (“androgen insensitive”) since the cells continue to grow in castrated antiandrogen (Flutamide) treated male animals. Our data clearly show that both the sensitive and insensitive tumors contain 3β-hydroxysteroid Δ⁵-Δ⁴ isomerase which causes the transformation of C₁₉ steroids into potent androgenic steroids. However, the androgen sensitive tumor is able to convert 5-androstene-3β, l7β-diol into 2-hydroxyestrogens while the rate of conversion is extremely low in the insensitive tumor. Most interestingly, the production of 5α-reduced steroids observed in both tissues was clearly higher in insensitive tumor homogenates.     

Androgen metabolism by rat epididymis. 3. Effect of castration and anti-androgens.

The in vivo and in vitro metabolism of 3H-testosterone by rat epididymis and the changes in epididymal weight have been studied after castration and treatment with anti-androgens. The utilization of 3H-testosterone was greatly reduced after castration as was the formation of 5alpha-reduced 17 beta-hydroxy metabolites. The formation of the 17 -keto metabolites was unaffected. Castration had no effect on the ratio between water and ether soluble radioactivity. Administration of testosterone propionate, necessary for giving normal stimulated prostate weight (150 mug/day), restored the metabolism of testosterone to approximately normal values. Estradiol benzoate and progesterone inhibited metabolism of testosterone in vitro and greatly reduced the formation of DHT (17 beta-hydroxy-5alpha-androstan-3-one) and 3 alpha-diol(5 alpha-androstane-3 alpha-17 beta-diol) by experiments both in vivo and in vitro. No effect of cyproterone acetate could be demonstrated on either the in vitro or in vivo metabolism of testosterone. Castration for 14 days reduced the epididymal weight to about 30% of that found in intact animals. Administration of testosterone propionate restored the epididymal weight to about 80% of normal. Estradiol benzoate and cyproterone acetate given to intact rats led to a decrease in the epididymal weight. Progesterone had no such effect. In 14 days castrated rats receiving testosterone propionate all three anti-androgens reduced the weight of the epididymis. In conclusion, our results show that the metabolic conversion of testosterone in epididymis to DHT and 3 alpha-diol is dramatically dependent on the hormonal status of the animal; castration or treatment with anti-androgens causes a reduced formation of the "active" androgens whilst testosterone replacement treatment restores the metabolism of testosterone to normal.     

In vitro conversion of testosterone-4-14C to androgens of the 5alpha-androstane series by a normal human ovary

In a previous communication (1) the identification of Δ⁴ -3-oxo-steroids and estrogens as metabolites of testosterone-4-¹⁴C incubated with normal post-ovulatory human ovaries was reported. Thin-layer chromatography of the extracts of those ovaries which contained no corpus luteum yielded zones of radioactivity which were not associated with any of these products. Detailed investigation of these zones from the extract of one of these glands resulted in identification of the following radiometabolites of the 5α-androstane series: 5α-androstane-3,17-dione, androsterone, 3β-hydroxy-5α-androstan-17-one, 17β-hydroxy-5α-androstan-3-one, 5α-androstane-3ga, 17β-diol and 5α-androstane-3β, 17β-diol. The capacity of a normal human ovary to produce these 5α-reduced androgens, especially the potent 17β-hydroxy-steroids, suggests a regulatory role of these compounds in ovarian function.     

Conversion of 20alpha-hydroxy-4-pregnen-3-one to 20alpha-hydroxy-5alpha-pregnan-3-one and 5alpha-pregnane-3alpha, 20alpha-diol by rat anterior pituitary

³H-20α-hydroxy-4-pregnen-3-one was incubated with anterior pituitaries from proestrous rats. The $\text{in vitro}$ metabolic products, identified by reverse isotopic dilution and purification to constant specific activity, were 20α-hydroxy-5α-pregnan-3-one (23.0%) and 5α-pregnane-3α,20α-diol (11.4%). These are qualitatively the same metabolites which result from $\text{in vitro}$ incubation of 20α-hydroxy-4-pregnen-3-one with medial basal hypothalamus. 68.8% of the recovered radioactivity remained as 20α-hydroxy-4-pregnen-3-one. These three compounds accounted for all of the recovered radioactivity.     

Androgen metabolism in sheep

³H-Testosterone (³H-T) plus ¹⁴C-androst-4-ene-3.17-dione (A-dione) and ³H-epi-testosterone (17α-hydroxy-4-androsten-3-one) (epiT) plus ¹⁴C-T were injected intravenously into two male sheep with bile fistulae, respectively. Urine and bile samples were collected at intervals for 4–8 hours and analyzed by the use of DEAE-Sephadex A-25 and Lipidex 5000 columns, TLC, and paper chromatography; the aglycones were identified by co-crystallization with authentic standards.Five fractions were obtained from urine and bile: unconjugated, glucosiduronates, sulfates, sulfo-glucosiduronates and disulfates. In urine, the major conjugates were glucosiduronates, while sulfates predominated in bile. About 80–90% of recovered radioactivity was found to be either glucosiduronates or sulfates. Among the metabolites identified, epi-T was the principal one, accounting for 10–15% of the administered doses. Conversion to 17α-hydroxysteroids thus appears to be a major route of metabolism of the androgens administered in sheep. Other metabolites in the glucosiduronate and sulfate fractions were androsterone, etiocholanolone (3α-hydroxy-5β-androstan-17-one), 5β-androstane-3α, 17β-diol, two unknown diols and polar metabolites. The results indicated that androgen metabolism is somewhat unusual in sheep, as compared with other animals and the human.     

Increased testicular 5α-androstane-3α, 17β-diol formation induced by treatment with [D-Ser(TBU)6, des-Gly-NH210]LHRH ethylamide in the rat

While the intact male adult rats respond to LH with a predominant increase of testicular and plasma testosterone levels, the response to LH stimulation in animals treated with the LHRH agoriist, [D-Ser(TBU)⁶, des-Gly-NH₂10]LHRH ethylamide is characterized by a major production of 5α-androstane-3α, 17β-diol. The marked increase of 5α-androstane-3α, 17β-diol levels in the presence of a 90% decrease of testosterone concentration strongly suggests that 5α-reductase and 3α-hydroxysteroid oxidoreductase activities are increased during testicular desensitization induced by treatment with the LHRH agonist.     

Ruizgenin,a new steroidal sapogenin diol from AgaveLecheguilla

From the leaves of Agavelecheguilla Torrey, two steroidal sapogenin diols have been isolated. Mass spectral, infra-red and nuclear magnetic resonance data of these two compounds showed them to be (25R) spirost-5-ene-2α, 3β-diol (yuccagenin) and (25R)-5β-spirostane-3β,6α-diol. The latter is a new compound to which the trivial name ruizgenin has been given.     

Biotransformation of progesterone by suspension cultures of Digitalis purpurea cultured cells

It has been shown that the cultured cells of Digitalis purpruea are capable of transforming progesterone (I) to 5α-pregnane-3,20-dione (II), 5α-pregnan-3β-ol-20-one (III), its glucoside (IV), 5α-pregnane-3β,20α-diol (V), its glucoside (VI), 5α-pregnane-3β,20β-diol (VII), its glucoside (VIII), Δ⁴-pregnen-20α-ol-3-one (IX), its glucoside (X), Δ-pregnen-20β-ol-3-one (XI) and its glucoside (XII). 5α-Pregnan-3β-ol-20-one glucoside (IV), 5α-pregnane-3β,20α-diol glucoside (VI), 5α-pregnane-3β,20β-diol glucoside (VIII), Δ⁴-pregnen-20α-ol-3-one glucoside (X) and Δ⁴-pregnen-20β-ol-3-one glucoside (XII) have been found for the first time as new metabolises by plant tissue cultures. A scheme for the biotransformation of progesterone (I) has been proposed, and the reduction and glucosidation activities distinctly have been observed in these cultured cells.     

Effects of castration and androgen treatment on androgen-receptor levels in rat skeletal muscles.

The effects of castration and dihydrotestosterone (DHT) treatment on levels of skeletal muscle androgen receptor (AR) were examined in three groups of adult male rats: 1) intact normal rats, 2) rats castrated at 16 wk of age, and 3) rats castrated at 16 wk of age and given DHT for 1 wk starting at week 17. All animals were killed at 18 wk of age. Castration caused a decrease (P < 0.05) in the weights of the levator ani and bulbocavernosus muscles. The administration of DHT to the castrated rats increased (P < 0.05) the weights of the levator ani and bulbocavernosus muscles. Castration caused a significant downregulation of AR levels in the bulbocavernosus (P < 0.05) but had no significant effect on AR levels in the levator ani muscle. DHT administration to the castrated group upregulated AR levels in the bulbocavernosus and levator ani muscles. The plantaris muscle did not significantly (P > 0.05) change for any of the treatments. These findings suggest that the effects of castration and androgen replacement differentially affect skeletal muscle mass and AR levels.     

Biotransformation of testosterone and other androgens by suspension cultures of Nicotiana tabacum “Bright yellow”

It has been shown that the cultured cells of Nicotiana tabacum “Bright Yellow” are capable of transforming testosterone to Δ⁴-androstene-3, 17-dione, 5α-androstan-17β-ol-3-one, 5α-androstane-3β, 17β-diol, its dipalmitate and 3- and 17-monoglucosides, epiandrosterone, its palmitate and glucoside, testosterone glucoside. 5α-Androstane-3β, 17β-diol dipalmitate and 3- and 17-monoglucosides, epiandrosterone palmitate and glucoside, and testosterone glucoside have been found for the first time as metabolites of testosterone in plant systems. Δ⁴-Androstene-3,17-dione was converted to testosterone. 5α-Androstan-17β-ol-3-one, which has been recognized as an active form of testosterone in mammals, was also detected. It has also been demonstrated that [4-¹⁴C]testosterone is actively incorporated in these transformations.     

The effect of progesterone analogues,naturally occurring steroids,and contraceptive progestins on hypothalamic and anterior pituitary Δ4-steroid (progesterone) 5α-reductase

The effects of a number of steroids on the conversion of progesterone to 5α-dihydroprogesterone by hypothalamic and pituitary progesterone 5α-reductase have been investigated. Using enzyme preparations from female rats and ³H-progesterone as substrate, 5α-reduced products (5α-dihydroprogesterone and 3α-hydroxy-5α-pregnan-20-one) were analyzed by reverse isotopic dilution analysis. The amount of total 5α-reduced products formed was compared in the presence and absence of the test steroid. Derivatives lacking the Δ⁴ and/or the 3-keto moiety were without effect. Corticosterone had no effect. 16β-Methylprogesterone inhibited progesterone 5α-reduction in both tissues by at least 65%, while the 2α-, 6α-, and 7α-methylated derivatives had lesser effects. 3-Oxo-4-pregnene-20β-carboxaldehyde and 21-fluoroprogesterone were potent inhibitors. 17-Hydroxyprogesterone was a competitive inhibitor (substrate) with Ki's of 0.27 μM (pituitary) and 0.29 μM (hypothalamus). Medroxyprogesterone exerted little inhibitory effect. Of the 19-norsteroids examined, only norethindrone appreciably inhibited the 5α-reduction. These results suggest that some natural Δ⁴-3-ketosteroids can modify enzymatic activity. Also, inhibitory analogues may be useful for studies on the role of this 5α-reduction of progesterone.     

Castration inhibits exercise-induced accumulation of Hsp70 in male rodent hearts

Intense exercise leads to accumulation of the inducible member of the 70-kDa family of heat shock proteins, Hsp70, in male, but not female, hearts. Estrogen is at least partially responsible for this difference. Because androgen receptors are expressed in the heart and castration leads to decreases in calcium regulatory proteins and altered cardiac function, testosterone (T) or its metabolites could also be involved. We hypothesized that removal of endogenous T production through castration would reduce cardiac Hsp70 accumulation after an acute exercise bout, whereas castrated animals supplemented with 5alpha-dihydrotestosterone (DHT) would show the intact male response. Fifty-four 8-wk-old male Sprague-Dawley rats were divided into intact, castrated, or castrated + DHT groups (n = 18/group). At 11 wk of age, 12 animals in each group undertook a 60-min bout of treadmill running at 30 m/min (2% incline) while the remaining 6 in each group remained sedentary. At 30 min or 24 h after exercise (n = 6/time point), blood and hearts were harvested for analysis. Serum T was undetectable in castrated and DHT-treated castrated rats, whereas serum DHT was significantly reduced in castrated animals only (approximately 60% reduction) (P < 0.05). Although there were no differences in constitutive levels of Hsp70 protein, exercise significantly increased cardiac hsp70 mRNA and protein in intact and DHT-supplemented rats, but not in castrated animals (P < 0.05). To examine whether castration eliminated the ability to respond to stress, another six intact and six castrated animals were subjected to a 15-min period of hyperthermia (core temperature raised to 42 degrees C) and killed 24 h later. As opposed to exercise, castrated animals subjected to heat shock exhibited increases in Hsp70 above nonshocked (i.e., sedentary) animals, similarly to intact males (P < 0.05). These data suggest that androgens, in addition to estrogen, play a role in the sexual dimorphism observed in the stress response to exercise but not heat shock.     

Androgens with activity at estrogen receptor beta have anxiolytic and cognitive-enhancing effects in male rats and mice

Testosterone (T) and its metabolites may underlie some beneficial effects for anxiety and cognition, but the mechanisms for these effects are unclear. T is reduced to dihydrotestosterone (DHT), which can be converted to 5α-androstane,3α,17β-diol (3α-diol) and/or 5α-androstane-3β,17β-diol (3β-diol). Additionally, T can be converted to androstenedione, and then to androsterone. These metabolites bind with varying affinity to androgen receptors (ARs; T and DHT), estrogen receptors (ERβ; 3α-diol, 3β-diol), or GABA_A/benzodiazepine receptors (GBRs; 3α-diol, androsterone). Three experiments were performed to investigate the hypothesis that reduced anxiety-like and enhanced cognitive performance may be due in part to actions of T metabolites at ERβ. Experiment 1: Gonadectomized (GDX) wildtype and ERβ knockout mice (βERKO) were subcutaneously (SC) administered 3α-diol, 3β-diol, androsterone, or oil vehicle at weekly intervals, and tested in anxiety tasks (open field, elevated plus maze, light–dark transition) or for cognitive performance in the object recognition task. Experiment 2: GDX rats were administered SC 3α-diol, 3β-diol, androsterone, or oil vehicle, and tested in the same tasks. Experiment 3: GDX rats were androsterone- or vehicle-primed and administered an antagonist of ARs (flutamide), ERs (tamoxifen), or GBRs (flumazenil), or vehicle and then tested in the elevated plus maze. Both rats and wildtype mice, but not βERKO mice, consistently had reduced anxiety and improved performance in the object recognition task. Androsterone was only effective at reducing anxiety-like behavior in the elevated plus maze and this effect was modestly reduced by flumazenil administration. Thus, actions at ERβ may be required for T's anxiety-reducing and cognitive-enhancing effects.