Steroid dynamics in the rabbit

Male rabbits were infused at a constant rate with 3H-androstenedione/14C-estrone (n = 5) or 3H-testosterone/14C-estradiol-17 beta (n = 3) for 3 1/2 hr and blood samples were obtained over the last hour and analyzed for radioactivity as androstenedione (A), testosterone (T), estrone (E1), estradiol-17 beta (E2 beta) and estradiol-17 alpha (E2 alpha). The mean value for the metabolic clearance rate of androstenedione (MCRA) was 85 +/- 10 l/day/kg, which was significantly greater than the mean MCRE1 59 +/- 10 l/day/kg. MCRT, 42 +/- 8 l/day/kg, and MCRE2 beta, 45 +/- 9 l/day/kg were not different. The conversion ratio of androstenedione to testosterone (CRA,T) was greater than CRT,A but for the estrogens, CRE2 beta, E1 was greater than CRE1,E2 beta. CRE2 beta, E2 alpha was greater than CRE1,E2 alpha. The overall aromatization of androstenedione to estrone, the fraction of 3H-androstenedione infused into the blood and measured as 3H-estrone in blood [( rho]A,E1BB) was 0.0005 +/- 0.0001 and for [rho]T,E2 beta BB was 0.0012 +/- 0.0006. In the rabbit both sex hormone binding globulin (SHBG) and albumin binding may effect the MCRs, and peripheral aromatization of androgens occurs to a far lesser degree than in humans and primates.     

Androgen and estrogen dynamics: stability over a two year interval in peri-menopausal women

As part of a study on hormones and bone density in peri-menopausal women, metabolic clearance rates (MCR), and interconversions of androgens and estrogens and the peripheral aromatization of androgens were measured twice 2 yr apart. Measurements of clearance rates and interconversions were made from blood samples obtained during constant infusions of [3H]androgens and [14C]estrogens. Measurements of peripheral aromatization were made from the estrogen glucuronides in a pooled 4-day urine collection timed from the start of the infusions. The women were divided into 3 groups: Group A (n = 15) were having menstrual cycles throughout the 2 yr interval; Group B (n = 11) were having menstrual cycles at the time of Study 1 but had been amenorrheic for at least 1 yr at the time of Study 2; Group C (n = 28) were amenorrheic for at least 1 yr at the time of Study 1 and had remained amenorrheic through Study 2. The MCRs for testosterone, androstenedione, estrone and estradiol were not different for Study 1 and Study 2 in any of the groups. The interconversions of the androgens were similar in both studies for all groups. The conversion of estrone to estradiol decreased in Group A, otherwise the interconversions of the estrogens did not vary between the studies for the other groups. The peripheral aromatization of androstenedione, but not of testosterone, was significantly greater at study 2 compared to Study 1 for all groups. We conclude that the MCRs and interconversions of androgens and of estrogens are stable over time, but that the peripheral aromatization of androstenedione increases over a 2 yr interval. This increase may be menopausal and/or age related.     

Androgen and estrogen dynamics in the female baboon (Papio anubis)

Androgen and estrogen dynamics were studied in 5 female baboons (Papio anubis) using constant infusions of [3H]androstenedione/[14C]estrone and [3H]testosterone/[14C]estradiol. Blood samples were obtained prior to the infusions and both blood and plasma was used for measurements of androstenedione (A), testosterone (T), dihydrotestosterone (DHT), estrone (E1), estradiol (E2). Plasma was used for measurements of sex-hormone binding globulin (SHBG), and the percents of T and E2 free, bound to SHBG, and to albumin. Blood samples obtained during the infusions were analyzed for radioactivity as purified androgens and estrogens. Metabolic clearance rates (MCR), and transfer factors ([rho]BB; fraction of steroid infused which is converted to and measured in blood as product) and blood production rates were calculated from whole blood data. All urine was collected for 96 h and an aliquot analyzed for radioactivity as the glucuronides of estrone and estradiol and the % peripheral aromatization calculated. The MCR's, calculated in whole blood, of A, E1, E2 and T were 53 +/- 6 1/day/kg, 39.3 +/- 3 1/day/kg, 29.9 +/- 5.2 1/day/kg and 10.1 +/- 2.3 1/day/kg, respectively. Each MCR was different (P less than 0.05) from the others. The PB of E1 was 15 +/- 2 micrograms/day and was not different from that of E2 (12 +/- 3 micrograms/day). The PB of A, 231 +/- 55 micrograms/day, was greater than that of T, 13 +/- 5 micrograms/day. The interconversions of both the androgens (18.9 +/- 3.4% vs 3.9 +/- 1.0%) and the estrogens (48.8 +/- 10.7% vs 4.0 +/- 0.8%) favored the oxidative pathway, i.e. conversion of 17-OH to 17-oxo steroids. The conversion ratio of A to DHT was greater than that of T to DHT (16.4 +/- 2.1% vs 5.3 +/- 0.7%), and A is a more important source of DHT than is T. The percent of T bound to SHBG (80.7 +/- 0.9%) was greater than percent of E2 (36.9 +/- 9.8%) and inversely the percents of T bound to albumin and free (17.5 +/- 0.8% and 1.65 +/- 0.16%) were less than the respective percents for estradiol (60.5 +/- 9.5% and 2.40 +/- 0.27%). The mean SHBG concentration was 54 +/- 6 nM. The peripheral aromatization of androstenedione, 1.36 +/- 0.05%, was greater than of testosterone, 0.18 +/- 0.02%. This difference is, in part, due to the lack of SHBG-binding of androstenedione. The general pattern of androgen and estrogen dynamics is similar to that in women. This similarity is due, in part, to the presence of SHBG in both baboons and women.     

Steroid metabolism in the gonads of a patient with testicular feminization. II. Metabolism of c19- and c18-steroids in vitro.

The metabolism of C19- and C18-steroids, in particular, the aromatization of androstenedione and testosterone, the interconversion of androgens to estrogens and the 5alpha-reductase activity of a right abdominal (r) and a left inguinal (l) testis of a patient with testicular feminization, are reported. Aromatization and 5alpha-reductase activity were also evaluated in tissue from the left ductus diferens (ld). The following results were obtained: 1. aromatization of androstenedione to estrone 2.52% (r), 0.02% (l), 0.94% (ld); 2. aromatization of testosterone to estradiol 0.58% (r), 2.88% (l); 3. conversion of androstenedione to testosterone 95.65% (r), 98.07% (l); 4. conversion of testosterone to androstenedione 33.14% (r), 53.65% (l); 5. conversion of estrone to estradiol85.29% (r), 100% (l), 6. conversion of estradiol to estrone 33.12% (r), 32.33% (l); 7.5alpha-reduction of testosterone to 5alpha-dihydrotestosterone 12.01% (r), 13.64% (l) and 4.10% (ld). A lack of 5alpha-reductase activity was not found in the tissues examined as stated in the literature. Estrogen production in these testes was demonstrated by the aromatization of androstenedione and testosterone to estrone and estradiol and is reflected in the difference of the estradiol concentration measured in spermatic and peripheral blood of the same patient (168 versus 33 pg/ml).     

Sexual differentiation in quail: Conversion of androgen to estrogen mediates testosterone-induced demasculinization of copulation but not other male characteristics

Previous research has shown that administration of either testosterone or estradiol to male quail embryos will demasculinize behavior and morphology. Six experiments in which embryos were treated were conducted to test the hypothesis that this testosterone-induced demasculinization is due to conversion of testosterone to estrogen (aromatization). In Experiment 1, dihydrotestosterone propionate, a nonaromatizable androgen, failed to demasculinize copulatory behavior, but did demasculinize crowing, strutting, and proctodeal glands. In Experiment 2, injection of the aromatizable androgens testosterone propionate (TP), testosterone, or androstenedione demasculinized copulatory behavior, the nonaromatizable androgen androsterone failed to have such an effect, and all androgens demasculinized proctodeal glands. In Experiment 3, Silastic implants of testosterone demasculinized all male characteristics, whereas implants of androsterone demasculinized only proctodeal glands. In Experiment 4, the antiestrogen tamoxifen prevented TP from demasculinizing copulatory behavior, but had no such effect with respect to crowing and strutting. In Experiments 5 and 6, the aromatization inhibitor 1,4,6-androstatrien-3,17-dione (ATD) prevented TP but not estradiol benzoate from demasculinizing copulatory behavior. Thus (1) in quail, testosterone-induced demasculinization of copulatory behavior is due to androgen aromatization, whereas testosterone-induced demasculinization of crowing, strutting, and proctodeal glands is not; (2) the distinct components of normal male reproductive behavior exhibit different patterns of steroid specificity during the organizational period, as was previously shown for the activational period; (3) the steroid specificity of crowing, strutting, and proctodeal glands changes between the organizational and activational periods. During organization, there is little specificity, whereas during activation, these characteristics respond only to androgens, never to estrogens. This difference suggests that developmental changes have occurred in the underlying biochemical substrates.     

Equine testicular aromatase: substrates specificity and kinetic characteristics.

1. In the stallion, estrogens were synthesized and sulfated in vivo by the testis. 2. The equine testicular enzyme aromatized androgens and 19-norandrogens with similar velocity, but not 16 alpha-hydroxytestosterone or epitestosterone in contrast to the human placental aromatase. 3. One single enzyme was implicated in the aromatization of androstenedione, testosterone, 19-norandrostenedione and 19-nortestosterone by ETMES. 4. During the process of androstenedione aromatization by ETMES, 19-hydroxyandrostenedione and 19-oxoandrostenedione were released and 4-hydroxyandrostenedione was a competitive inhibitor causing an additional irreversible enzyme inactivation which is what occurs with HPMES. 5. Dihydrotestosterone was a potent competitive inhibitor of aromatase activity.     

Androgen synthesis and aromatization by equine corpus luteum microsomes

Whereas mare corpus luteum does not produce androgens or estrogens in vivo, the incubation of mare corpus luteum microsomes with progesterone and NADPH resulted in 17 alpha-hydroxyprogesterone and estrogen production with a small yield of androstenedione. In the presence of an aromatase inhibitor (4-hydroxyandrostenedione), 17 alpha-hydroxyprogesterone and androstenedione were accumulated. Aromatization of testosterone and androstenedione occurred via stereospecific loss of the 1 beta, 2 beta hydrogen atoms and was inhibited by MgCl2, KCl, and EDTA. The Km of estrogen synthetase from equine corpus luteum for testosterone was 18.5 +/- 2.7 nM and for androstenedione was 11.5 +/- 1.5 nM. 19-Norandrogens were aromatized with a slightly higher efficiency than were androgens, but the affinity of the aromatase was lower for 19-norandrogens than for androgens. Our results suggest that aromatases from equine testis and corpus luteum are closely related enzymes. On the other hand, the question arises as to the relationship among the cell origin, the synthetizing abilities, and in vivo production of the corpus luteum in different mammalian species.     

Increases in serum estrogen levels during major illness are caused by increased peripheral aromatization

Although serum testosterone levels decrease acutely in critically ill patients, estrogen levels rise. We hypothesized that increased rates of aromatization of androgens to estrogens underlie the increase in serum estrogen levels. Eleven men and three women (age 42-69 yr) were prospectively studied before and again after elective coronary artery bypass graft surgery (CABG). Each patient received priming doses of [(14)C]androgen and [(3)H]estrogen that were immediately followed by peripheral infusions for 210 min. Eight men and three women received androstenedione (A(4))/estrone (E(1)) and three men received testosterone (T)/estradiol (E(2)). Adipose tissue biopsies were obtained in another six men before and after CABG to evaluate levels of P450 aromatase mRNA. Serum T levels decreased postoperatively in all 17 men (P < 0.001), whereas E(1) levels rose (P = 0.004), with a trend toward a rise in E(2) (P = 0.23). Peripheral aromatization rates of androgens to estrogens rose markedly in all 14 patients (P < 0.0001). Estrogen clearance rates rose (P < 0.002). Mean serum A(4) levels increased slightly postoperatively (P = 0.04), although no increase in A(4) production rates (PRs) was observed. T PRs decreased in two of three men, whereas clearance rates increased in all three. Adipose tissue P450 aromatase mRNA content increased postoperatively (P < 0.001). We conclude that the primary cause of increased estrogen levels in acute illness is increased aromatase P450 gene expression, resulting in enhanced aromatization of androgens to estrogens, a previously undescribed endocrine response to acute illness. Both increased T clearance and decreased T production contribute to decreased serum T levels. Animal studies suggest that these opposing changes in circulating estrogen and androgen levels may be important to reduce morbidity and mortality in critical illness.     

Bioavailability and metabolism of oral and percutaneous dehydroepiandrosterone in postmenopausal women

To study the bioavailability of dehydroepiandrosterone (DHEA) administered by the oral and percutaneous routes, three groups of 12 postmenopausal women aged 60-70 years received two capsules of 50mg of DHEA orally before breakfast daily for 14 days or applied 4 g of a 10% DHEA cream or gel at the same time of the day on a 30 cm x 30 cm surface area on the thighs. Detailed serial blood sampling over 24h was performed following 1st and 14th DHEA administration for measurement of DHEA and nine of its metabolites by liquid chromatography tandem mass spectrometry (LC-MS/MS) or gas chromatography mass spectrometry (GC-MS). Serum levels of estrone (E1) and estradiol (E2) did not change following DHEA administration by any of the three formulations, while serum androstenedione (4-dione), testosterone, DHEA sulfate (DHEA-S), E(1)-S, androsterone glucuronide (ADT-G) and 3alpha-androstanediol-G (3alpha-diol-G), increased in all cases, the effect on these parameters being more important after oral than percutaneous administration due to the metabolism of DHEA into these metabolites in the gastrointestinal tract and liver. No qualitative differences in DHEA metabolism are observed between the oral and percutaneous routes of DHEA administration while the levels of all steroids remain on a plateau during the 24h period during chronic percutaneous DHEA administration. The present data show that DHEA is transformed into active androgens and estrogens in peripheral intracrine tissues with no or minimal release of the active steroids E(1), E(2) or testosterone in the circulation. Moreover, DHEA is preferentially transformed into androgens rather than into estrogens. Most importantly, the present data show that changes in serum DHEA following oral or percutaneous DHEA administration are not a valid parameter of DHEA action since the increase in serum DHEA is at least 100% greater than the increase in the formation of active androgens and estrogens and thus much higher than the potential physiological effects.     

Androgen conversion in osteoarthritis and rheumatoid arthritis synoviocytes--androstenedione and testosterone inhibit estrogen formation and favor production of more potent 5alpha-reduced androgens

In synovial cells of patients with osteoarthritis (OA) and rheumatoid arthritis (RA), conversion products of major anti-inflammatory androgens are as yet unknown but may be proinflammatory. Therefore, therapy with androgens in RA could be a problem. This study was carried out in order to compare conversion products of androgens in RA and OA synoviocytes. In 26 OA and 24 RA patients, androgen conversion in synovial cells was investigated using radiolabeled substrates and analysis by thin-layer chromatography and HPLC. Aromatase expression was studied by immunohistochemistry. Dehydroepiandrosterone (DHEA) was converted into androstenediol, androstenedione (ASD), 16alphaOH-DHEA, 7alphaOH-DHEA, testosterone, estrone (E1), estradiol (E2), estriol (E3), and 16alphaOH-testosterone (similar in OA and RA). Surprisingly, levels of E2, E3, and 16alpha-hydroxylated steroids were as high as levels of testosterone. In RA and OA, 5alpha-dihydrotestosterone increased conversion of DHEA into testosterone but not into estrogens. The second androgen, ASD, was converted into 5alpha-dihydro-ASD, testosterone, and negligible amounts of E1, E2, E3, or 16alphaOH-testosterone. 5alpha-dihydro-ASD levels were higher in RA than OA. The third androgen, testosterone, was converted into ASD, 5alpha-dihydro-ASD, 5alpha-dihydrotestosterone, and negligible quantities of E1 and E2. 5alpha-dihydrotestosterone was higher in RA than OA. ASD and testosterone nearly completely blocked aromatization of androgens. In addition, density of aromatase-positive cells and concentration of released E2, E3, and free testosterone from superfused synovial tissue was similar in RA and OA but estrogens were markedly higher than free testosterone. In conclusion, ASD and testosterone might be favorable anti-inflammatory compounds because they decrease aromatization and increase anti-inflammatory 5alpha-reduced androgens. In contrast, DHEA did not block aromatization but yielded high levels of estrogens and proproliferative 16alpha-hydroxylated steroids. Androgens were differentially converted to pro- and anti-inflammatory steroid hormones via diverse pathways.     

The effects of ovariectomy and progesterone on peripheral aromatization in the female rhesus monkey

We investigated the acute effects of surgery, i.e. ovariectomy, the long-term effects of ovariectomy, and the effects of progesterone on the peripheral aromatization of androstenedione in rhesus monkeys (Macaca mulatta). For the acute effects of surgery, 7 rhesus monkeys were given a pulse of [³H]androstenedione/[¹⁴C]estrone 2 weeks before and immedately after ovariectomy. In each case all urine was collected for 4 days and analyzed for radioactivity as estrone glucuronide and the peripheral aromatization calculated from the isotope ratios. Similarly, 5 monkeys were studied before and 18 months after ovariectomy. The acute effects of surgery resulted in a significant decrease in the peripheral aromatization of androstenedione to estrone from a mean±SE of 0.94 ± 0.26 to 0.61 ± 0.19%, P = 0.0452. Conversely, the long-term effects of ovariectomy resulted in a significant increase in peripheral aromatization from 0.38 ± 0.06 to 0.67 ± 0.12%, P = 0.0207. In 7 monkeys the peripheral aromatization was measured before and 10 days after the administration of progesterone, 100 mg in oil. There was no difference in peripheral aromatization before, 0.62 ± 0.04% and after progesterone, 0.58 ± 0.05%, P = 0.10. We conclude that the acute stress of ovariectomy, or possibly the loss of ovarian aromatizing tissue, results in a decline in peripheral aromatization, but ovariectomy will have the long-term effect of an increase in aromatization, and that the presence or absence of progesterone does not play a role.     

Androgen conversion in osteoarthritis and rheumatoid arthritis synoviocytes – androstenedione and testosterone inhibit estrogen formation and favor production of more potent 5α-reduced androgens

In synovial cells of patients with osteoarthritis (OA) and rheumatoid arthritis (RA), conversion products of major anti-inflammatory androgens are as yet unknown but may be proinflammatory. Therefore, therapy with androgens in RA could be a problem. This study was carried out in order to compare conversion products of androgens in RA and OA synoviocytes. In 26 OA and 24 RA patients, androgen conversion in synovial cells was investigated using radiolabeled substrates and analysis by thin-layer chromatography and HPLC. Aromatase expression was studied by immunohistochemistry. Dehydroepiandrosterone (DHEA) was converted into androstenediol, androstenedione (ASD), 16αOH-DHEA, 7αOH-DHEA, testosterone, estrone (E1), estradiol (E2), estriol (E3), and 16αOH-testosterone (similar in OA and RA). Surprisingly, levels of E2, E3, and 16α-hydroxylated steroids were as high as levels of testosterone. In RA and OA, 5α-dihydrotestosterone increased conversion of DHEA into testosterone but not into estrogens. The second androgen, ASD, was converted into 5α-dihydro-ASD, testosterone, and negligible amounts of E1, E2, E3, or 16αOH-testosterone. 5α-dihydro-ASD levels were higher in RA than OA. The third androgen, testosterone, was converted into ASD, 5α-dihydro-ASD, 5α-dihydrotestosterone, and negligible quantities of E1 and E2. 5α-dihydrotestosterone was higher in RA than OA. ASD and testosterone nearly completely blocked aromatization of androgens. In addition, density of aromatase-positive cells and concentration of released E2, E3, and free testosterone from superfused synovial tissue was similar in RA and OA but estrogens were markedly higher than free testosterone. In conclusion, ASD and testosterone might be favorable anti-inflammatory compounds because they decrease aromatization and increase anti-inflammatory 5α-reduced androgens. In contrast, DHEA did not block aromatization but yielded high levels of estrogens and proproliferative 16α-hydroxylated steroids. Androgens were differentially converted to pro- and anti-inflammatory steroid hormones via diverse pathways.     

Chronic treatment with corticotropin increases the capacity of rabbit adrenocortical cells to convert pregnenolone into androgens

The present study was conducted to evaluate whether the previously demonstrated enhancement in adrenocortical androgen secretion in rabbits chronically treated with ACTH results, in addition to an increased pregnenolone production, from a more efficient conversion of this precursor of steroidogenesis into androgens. To this end, the adrenocortical cells from 14 control and 14 ACTH-treated rabbits (ACTH 1-24,200 micrograms s.c. daily for 12 days) were incubated either in the presence of different concentration of ACTH or with pregnenolone added in amounts from 0.5 to 250 micrograms. The total steroidogenic potency (maximal response to ACTH) was significantly enhanced for cells from ACTH-treated animals, as was the ACTH-induced production of dehydroepiandrosterone (DHEA), DHEA-sulfate, androstenedione and testosterone. In addition the production of these androgens from given amounts of exogenous pregnenolone was also significantly increased. The maximal capacity of adrenocortical cells to convert pregnenolone into androgens averaged (for ACTH-treated vs control group) 130 +/- 34 vs 43 +/- 10 pmol for DHEA, 138 +/- 43 vs 46 +/- 14 pmol for DHEA-sulfate, 99 +/- 31 vs 10 +/- 2 pmol for androstenedione and 8.0 +/- 2.6 vs 2.4 +/- 0.3 pmol for testosterone (P less than 0.001 for all androgens). The addition of ACTH to adrenocortical cells incubated with pregnenolone did not modify the maximal capacity of conversion of pregnenolone into androgens, which was in both experimental groups similar to that documented in the absence of ACTH. Thus, while an acute stimulatory effect of ACTH on adrenocortical steroidogenesis is devoid of any influence on the activity of the post-pregnenolone pathway of androgen synthesis, the chronic exposure of adrenocortical cells to ACTH lead to increased activity of steroidogenic pathway involved in the conversion of pregnenolone into androgens.     

Comparative studies of androgen metabolism in theca and granulosa cells of human follicles in vitro

In eight separate experiments, theca and granulosa were isolated from human follicles (5–25 mm in diameter), and their capacities to metabolize radiolabelled testosterone in 24 hour cultures were assessed. Theca metabolized testosterone primarily to androstenedione, however significant aromatization to estradiol-17β and to estrone was also observed. Granulosa metabolized testosterone primarily to estradiol-17β and estrone, while smaller quantities were converted to androstenedione. In seven of these experiments, the intermediate of aromatization, 19-hydroxytestosterone, was identified. In six of these experiments, theca, when compared to granulosa, produced more androstenedione but less estradiol-17β and estrone. 5α-Reduced androgens were non-detectable or produced in small quantities. In a single experiment, metabolism of androstenedione was compared to metabolism of testosterone by both theca and granulosa. Theca metabolized androstenedione to testosterone in smaller quantities than testosterone to androstenedione. Granulosa metabolized androstenedione to testosterone in higher quantities than testosterone to androstenedione. Both theca and granulosa aromatized androstenedione more readily than testosterone.     

The effects of l-thyroxine and dexamethasone on steroid dynamics in male cynomologous monkeys

Male cynomologous monkeys (M. fascicularis) were infused with [3H]androgens, [14C]estrogens and [3H]cortisol before and after the administration of l-thyroxine, (l-T4) 150 micrograms/day for 6 wk, dexamethasone 8 mg every 8 h for 3 doses and dexamethasone 1.0 mg/day for 8 days. Blood samples were obtained before each of the infusions and analyzed for endogenous T, A, E1, E2 and F concentrations, % free T and % free E2, sex hormone-binding globulin (SHBG) and cortisol binding globulin (CBG) capacity. When l-T4 was being administered, T4 and triiodothyronine (T3) concentrations were also measured. Blood samples were obtained during the infusions and analyzed for radioactivity as testosterone (T), androstenedione (A), dihydrotestosterone (DHT), estradiol (E1), estrone (E2), and cortisol (F). All urine was collected for 96 h and an aliquot of the pooled urine was analyzed for radioactivity as estrone and estradiol glucuronide. The administration of l-T4 for 6 wk to 3 monkeys resulted in a marked rise in T4 and T3 levels, from 4.8 +/- 0.4 micrograms/dl and from 136 +/- 6 to 515 +/- 71 ng/dl, respectively. MCRT, MCRE2 and MCRE1 did not change, but MCRA values increased slightly and MCRF increased 2-3 fold. [rho]T.E2 did not change but [rho]A.E1BM showed a slight but significant increase. The inter-conversions between the androgens and between the estrogens were not altered. There was a 2-3-fold increase in SHBG and a decrease in %FT but no change in %FE2 or CBG. The concentrations of T, A and DHT rose but there was no trend in the levels of the estrogens. The administration of dexamethasone 8 mg every 8 h for 3 doses or 1 mg/day for 8 days caused no changes in the MCRs for T, A, E1 and E2 but did cause a significant decrease in MCRF. Measurement of splanchnic and peripheral tissue extractions before and after acute dexamethasone administration in 1 monkey showed that the decrease in MCRF was the result of a marked decrease, 11-2%, in splanchnic extraction of F. The extractions of T and E2 were relatively unaffected. The concentrations of T and F fell but E2 remained the same. % FT and % FE2 rose slightly and the concentrations of SHBG and CBG were unchanged. The androgen interconversions and estrogen interconversions were not affected but [rho]T,E2BM and [rho]A,E1BM showed slight decreases.(ABSTRACT TRUNCATED AT 400 WORDS)     

Competitive product inhibition of aromatase by natural estrogens

In order to better understand the function of aromatase, we carried out kinetic analyses to asses the ability of natural estrogens, estrone (E₁), estradiol (E₂), 16-OHE₁, and estriol (E₃), to inhibit aromatization. Human placental microsomes (50 μg protein) were incubated for 5 min at 37°C with [1β-³H]testosterone (1.24 × 10³ dpm ³H/ng, 35–150 nM) or [1β-³H,4-¹⁴C]androstenedione (3.05 × 10³ dpm ³H/ng, ³H/¹⁴C = 19.3, 7–65 nM) as substrate in the presence of NADPH, with and without natural estrogens as putative inhibitors. Aromatase activity was assessed by tritium released to water from the 1β-position of the substrates. Natural estrogens showed competitive product inhibition against androgen aromatization. The K_i of E₁, E₂, 16-OHE₁, and E₃ for testosterone aromatization was 1.5, 2.2, 95, and 162 μM, respectively, where the K_m of aromatase was 61.8 ± 2.0 nM (n = 5) for testosterone. The K_i of E₁, E₂, 16-OHE₁, and E₃ for androstenedione aromatization was 10.6, 5.5, 252, and 1182 μM, respectively, where the K_m of aromatase was 35.4 ± 4.1 nM (n = 4) for androstenedione. These results show that estrogens inhibit the process of andrigen aromatization and indicate that natural estrogens regulate their own synthesis by the product inhibition mechanism in vivo. Since natural estrogens bind to the active site of human placental aromatase P-450 complex as competitive inhibitors, natural estrogens might be further metabolized by aromatase. This suggests that human placental estrogen 2-hydroxylase activity is catalyzed by the active site of aromatase cytochrome P-450 and also agrees with the fact that the level of catecholestrogens in maternal plasma increases during pregnancy. The relative affinities and concentration of androgens and estrogens would control estrogen and catecholestrogen biosynthesis by aromatase.     

Synthesis and aromatization of 19-norandrogens in the stallion testis

The results of the measurement of 19-nortestosterone in the testiscular artery and vein of the stallion, the very low levels of this steroid in the peripheral blood of geldings and the similar patterns of increase in the peripheral levels of 19-nortestosterone and testosterone after hCG stimulation, show that 19-nortestosterone, like testosterone, is essentially synthesized in the testis. This testicular origin was confirmed by the ability of testicular tissue to synthesize 19-norandrogens from [4-14C]androgens in vitro. 19-Nortestosterone was 50% conjugated in the peripheral blood and almost entirely conjugated after biosynthesis in vitro. The sequence of appearance of steroids in the peripheral blood after a single injection of 10,000 IU hCG suggests that, in the equine testis, 19-norandrogens are produced by a specific C10-19 desmolase (estrene synthetase), stimulable by hCG. 19-Nortestosterone was aromatized into estradiol-17 beta by stallion testicular microsomes. The affinity of the aromatase for 19-nortestosterone was very low compared to that for testosterone. At low and presumably physiological levels, and at a high testosterone/19-nortestosterone ratio, testosterone did not inhibit 19-nortestosterone aromatization by more than 53%. Thus, 19-nortestosterone may be aromatized in vivo in the testis in spite of the endogenous concentrations of androgens. However, the low velocity of 19-nortestosterone aromatization by testicular microsomes at roughly physiological concentrations suggests that 19-norandrogen aromatization may only participate slightly in the testicular estrogen production. These results suggest that in the equine testis, two aromatizing enzyme systems may exist: one which aromatizes both androgens and 19-norandrogens, and a minority system more specific for 19-norandrogens.     

Cytochrome P450 aromatase (CYP19) in the non-human primate brain: distribution, regulation, and functional significance

In adult male primates, estrogens play a role in both gonadotropin feedback and sexual behavior. Inhibition of aromatization in intact male monkeys acutely elevates serum levels of luteinizing hormone, an effect mediated, at least partially, within the brain. High levels of aromatase (CYP19) are present in the monkey brain and regulated by androgens in regions thought to be involved in the central regulation of reproduction. Androgens regulate aromatase pretranslationally and androgen receptor activation is correlated with the induction of aromatase activity. Aromatase and androgen receptor mRNAs display both unique and overlapping distributions within the hypothalamus and limbic system suggesting that androgens and androgen-derived estrogens regulate complimentary and interacting genes within many neural networks. Long-term castrated monkeys, like men, exhibit an estrogen-dependent neural deficit that could be an underlying cause of the insensitivity to testosterone that develops in states of chronic androgen deficiency. Future studies of in situ estrogen formation in brain in the primate model are important for understanding the importance of aromatase not only for reproduction, but also for neural functions such as memory and cognition that appear to be modulated by estrogens.     

Androgen aromatization by luteinized bovine granulosa cells in tissue culture

Luteinized bovine granulosa cells in tissue culture contained an active 19-hydroxylase aromatase enzyme system which converted exogenous androstenedione and testosterone to oestradiol-17beta; no oestrone was detected. In the absence of exogenous androgens, the cells failed to synthesize oestrogens due to a limited capacity to synthesize androgen precursor. Theca-lutein cells, present in those CL which synthesize oestrogens, may provide androgen precursor for aromatization by the granulosa-lutein cells.     

A simple spectrophotometric method of assay of forward motility of goat spermatozoa

Adult male sand rats (Psammomys obesus) were caught in the Béni-Abbès area. The highest testicular contents of androgens (ng/testis) were observed in autumn and in winter (testosterone: 7.6 +/- 1.1; androstenedione: 0.76 +/- 0.11) and the lowest in early summer (June) (testosterone: 1.5 +/- 0.3; androstenedione: 0.20 +/- 0.05). Values had increased by late July. Annual variations of the testosterone metabolic clearance rate (litres/24 h/100 g body wt) were similar to those of testicular androgens; values were high in winter (6.7 +/- 0.7) and lowest in June (3.2 +/- 0.3). The onset of testicular endocrine activity in sand rats was concomitant both with the highest temperatures and the start of reduction in photoperiod; its regression occurred when temperature and photoperiod were increasing.