Sertoli cells from immature rats : in vitro stimulation of steroid metabolism by FSH.

Sertoli cells from 10 day old rats convert androstenedione to testosterone and 5α-androstane-3α,17β-diol, testosterone to 17β-hydroxy-5α-androstan-3-one and 5α-androstane-3α,17β-diol, and 17β-hydroxy-5α-androstan-3-one to 5α-andro-stane-3α,17β-diol after 72 hours $\text{in vitro}$. Conversions of androstenedione to testosterone and 5α-androstane-3α,17β-diol, and testosterone to 5α-androstane-3α,17β-diol were 2 to 3 times greater in FSH treated cultures. Steroid conversion was not stimulated significantly by LH or TSH. The results are interpreted as evidence that in young rats Sertoli steroid metabolism is stimulated by FSH, that Sertoli cells are an androgen target and that FSH may induce or facilitate Sertoli androgen responsiveness.     

Proton magnetic resonance spectra of 17ξ-Hydroxy-17ξ-methyl-5ξ-androstane C-3 ketone and c-3ξ alcohol isomers in chloroform-d and pyridine-d5

17α-Hydroxy-17β-methyl-5β-androstan-3-one, 17μ-methyl-5α-androstane-3α, 17α-diol, 17β-methyl-5α-androstane-3β, 17α-diol, 17α-methyl-5β-androstane-3β, 17β-diol, 17β-methyl-5β-androstane-3α, 17α-diol and 17β-methy1–5β-androstane-3β, 17α-diol were synthesized for the first time. ¹H NMR spectra of all four 17ξ-hydroxy/17ξ-methyl C-3 ketones and all eight C-3 alcohols were recorded in chloroform-d and pyridine-d₅. Pyridine-induced chemical shifts are discussed. Thin-layer Chromatographic data are given.     

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.     

Synthesis of 5α-Androstane-3α,16α,17β-triol from 3β-hydroxy-5-androsten-17-one

5α-Androstane-3α, 16α 17β-triol was synthesized from 3β-hy-droxy-5-androsten-17-one. The procedure Involved catalytic hydrogenation of 3β-hydroxy-5-androsten-17-one to 3β-hydroxy-5α-androstan-17-one. This was followed by conversion of the 3β-hydroxy group to 3α-benzoyloxy group by the Mitsunobu reaction. Further treatment with isopropenyl acetate yielded 5α-androsten-16-ene-3α, 17-diol 3-benzoate 17-acetate. This was then converted to 3α, 17-dihydroxy-5α-androstan-16-one 3-benzoate 17-acetate via the unstable epoxide intermediate after treatment with $\text{m}$-cloroperoxybenzoic acid. LiAlH₄ reduction of this compound formed 5α-androstane-3α, 16α, 17β-trlol. ¹H and ¹³C NMR of various steroids are presented to confirm the structure of this compound.     

Steroid metabolism by mouse submaxillary glands. I. in vitro metabolism of testosterone and 4-androstene-3,17-dione

Tritiated 4-androstene-3,17-dione and testosterone were incubated with submaxillary gland homogenates of 6 month old male mice. In 15 and 180 minute incubations fortified with NADPH, submaxillary tissue converted 4-androstene-3,17-dione predominantly to androsterone and, to a lesser extent, testosterone, 17β-hydroxy-5α-androstan-3-one and 5α-androstane-3α, 17β-diol. Testosterone was converted primarily to 5α-androstane-3α, 17β-diol when exogenous NADPH was available; trace amounts of 4-androstene-3,17-dione, 17β-hydroxy-5α-androstan-3-one and androsterone were also formed. When a NADPH-generating system was omitted from the incubation medium both 4-androstene-3,17-dione and testosterone were poorly metabolized by submaxillary tissue; the amounts of reduced metabolites accumulating were markedly reduced.     

Acetylation and hydroxylation of 5alpha-androstane-3beta,17beta-diol by prostate and epididymis

An unknown radiometabolite, formed in the canine prostate and epididymis after intra-arterial infusion of testosterone-4-¹⁴C in physiologic saline and extraction of the organs with ethyl acetate-acetone, was identified as the 3-monoacetate of 5α-androstane-3β, 17β-diol (3β-diol). Transformation of 3β-diol-¹⁴C to its identified 3-monoacetate derivative could also be demonstrated, if the incubation of the radiosubstrate with minced canine prostate was terminated by ethyl acetate extraction. The formation of polar products in high yield was noted. Whereas minced canine prostate actively converted 5α-androstane-3α,17β-diol-¹⁴C to 17β-hydroxy-5α-androstan-3-one-¹⁴C, the same preparation hydroxylated 3β-diol-¹⁴C predominantly at the 7ξ- and, to a lesser extent, at the 6ξ-positions. Partial identification of the hydroxylated radiometabolites was by crystallization of the CrO₃-oxidation products 5α-androstane-3,6,17-trione-¹⁴C and 5α-androstane-3,7,17-trione-¹⁴C to constant SA and by GLC/MS of the latter derivative. NADPH-supplementation of the preparation enhanced the yield of hydroxylated products derived from 3β-diol-¹⁴C in a 1 hr incubation from 22% to 41%. Analogous supplemented incubations of benign hyperplastic human prostate and canine epididymis produced polar metabolites (in 12.5% and 76% yields, respectively) which gave rise to similar proportions of the same androstanetrione epimers on CrO₃-oxidation.     

Metabolism of 17β-hydroxy-2-hydroxymethylene-5α-androstan-3-one in the rabbit

An acidic metabolite, 2α-carboxy-5α-androstane-3α, 16α, 17αtriol and two neutral metabolites, 2α-hydroxymethyl-5α-androstane-3α, 17α-diol, and 2α-hydroxymethyl-5α-androstane-3α, 16α, 17α-triol have been identified in the urine of rabbits orally dosed with 17β-hydroxy-2-hydroxymethylene-5α-androstan-3-one. 2α-Hydroxymethyl-5α-androstane-3α, 16α, 17α-triol was previously obtained from the urine of rabbits dosed with 17β-hydroxy-2α-methyl-5α-androstan-3-one. The acidic metabolite was the major urinary excretion product.     

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.     

The synthesis of 17-substituted 2α-chloro-5α-androstan-3-ols

This paper describes the synthesis of 2α-chloro-3α-hydroxy-5α-androstan-17-one and 2α-chloro-5α-androstane-3α,17β-diol and their 3-epimers. The epimers were characterized by nmr spectroscopy.     

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.     

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.     

Synthesis and pyrogenic effect of 3α,7α-dihydroxy-5β-androstan-17-one and 3α-hydroxy-5β-androstane-7,17-dione

The first chemical synthesis of 3α,7α-dihydroxy-5β-androstan-17-one and 3α-hydroxy-5β-androstane-7,17-dione is reported. In this method, the 17β-side chain of commercial chenodesoxycholic acid was degraded in 6 steps after selective protection of the hydroxyl groups : 3α-OH by a $\text{tert}$-butyldimetfaylsilyl group and 7α-OH by an acetoxy group. The capacity of 3α,7α-dihydroxy-5β-androstan-17-one and 3α-hydroxy-5β-androstane-7, 17-dione to release a pyrogen by human leukocytes was investigated by two independent methods : supernatants from leukocytes incubated with a steroid are injected to rabbits whose fever is measured, or tested by the Limulus Test (a pyrogen detection technique). The 7-keto substituted etiocholanolone still possessed pyrogenic activity, while the 7α-hydroxyl substituted one did not.     

A DNA-binding fraction of mouse kidney 3-ketosteroid reductase: Comparison with androgen receptors

Since approximately 1% of 3-ketosteroid reductase (which metabolizes dihydrotestosterone [17β-hydroxy-5α-androstan-3-one] to 5α-androstane-3α,17β-diol or 5α-androstane-3α,17β-diol) from mouse kidney cytosol adheres to DNA under conditions that allow virtually complete androgen receptor binding, these two DNA-binding activities were compared in cytosol extracts of mouse kidney and hypothalamus-preoptic area. This DNA-binding fraction of 3-ketosteroid reductase was distinguished from androgen receptor in several ways: (1) its pattern of elution from DNA-cellulose with steps of increasing NaC1 concentration differed from that for receptors from wild-type kidney; (2) it was influenced differently by the mutation Tfm, both in level and in DNA-cellulose elution pattern; (3) in mouse kidney cytosol it was relatively stable at moderate (25°C) temperatures which rapidly inactivated ligand-free androgen receptors in the same cytosols; (4) the DNA-binding was not proportional to androgen receptor levels between two wild-type tissues, the hypothalamus-preoptic area and kidney. By these criteria, a simple relationship of androgen receptors and a DNA-binding fraction of 3-ketosteroid reductase activity is unlikely.     

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.     

Reactions of 4β,5-epoxy-5β-androstan-3-ones with hydrogen fluoride in pyridine

4β,5-Epoxy-5β-androstane-3,17-dione ($\text{1a}$), 17β-hydroxy-4β,5-epoxy-5β-androstan-3-one ($\text{1b}$) and 17β-acetoxy-4β,5-epoxy-5β-androstan-3-one ($\text{1c}$) were treated with anhydrous hydrogen fluoride in pyridine (70% solution) at 55° and yielded the corresponding 4-en-4-ols e.g. 4-hydroxy-4-androstene-3, 17-dione ($\text{2a}$).As the reaction temperature was lowered each epoxide formed a second product which, at ?75°, was the major component of the reaction mixture and was identified as the 5α-fluoro-4α-ol derivative of the parent enone, e.g. 4α-hydroxy-5-fluoro-5α-androstane-3,17-dione ($\text{3a}$). These fluorohydrins are thermally unstable, losing hydrogen fluoride.The acetates of the fluorohydrins were also prepared, characterized, and shown to be more stable than the parent alcohols.     

The identification and characterization of the c19o3 steroid metabolites of 5α-androstane-3β, 17β-diol produced by the canine prostate: 5α-androstane-3β, 6α, 17β-triol and 5α-androstane-3β, 7α, 17β-triol

This study has identified the polar metabolites of 5α-androstane-3β, 17β-diol(3β-diol) produced by the canine prostate. The major metabolite is 5α-androstane-3β, 7α, 17β-triol (7α-triol) accounting for approximately 80% of the total polar metabolites of 3β-diol. The remaining 20% is accounted for exclusively by another triol, 5α-androstane-3β, 6α, 17β-triol(6α-triol). This study has also characterized two enzymatic hydroxylases responsible for respective triol formation: 5α-androstane-3β, 17β-diol 6α-hydroxylase (6α-hydroxylase) and 5α-androstane-3β, 17β-diol 7α-hydroxylase (7α-hydroxylase). Both of these irreversible hydroxylases are located in the particulate fraction of the prostate and can utilize either NADH or NADPH as cofactor. Several $\text{in vitro}$ steroid inhibitors of these hydroxylases were identified including cholesterol, estradiol and diethylstilbestrol. Neither of the hydroxylases were found to be decreased by castration (3 months) when expressed as activity/DNA. Using a variety of C₁₉ androstane substrates, 6α- and 7α-triol were found to be major components of the total 3β-hydroxy-5α-androstane metabolites produced by the canine prostate.     

Biotransformation studies of prednisone using human intestinal bacteria Part II: Anaerobic incubation and docking studies

Anaerobic incubation of prednisone 1 with human intestinal bacteria (HIB) afforded nine metabolites: 5β-androst-1-ene-3,11,17-trione 3, 3α-hydroxy-5α-androstane-11,17-dione 4, 3β,17α,20-trihydroxy-5α-pregnan-11-one 5, 3α,17α-dihydroxy-5α-pregnane-11,20-dione 6, 3α,17α-dihydroxy-5β-pregnane-11,20-dione 7, 3β,17β-dihydroxy-5α-androstan-11-one 8β, 3β,17α-dihydroxy-5α-androstan-11-one 8α, 3α,17β-dihydroxy-5α-androstan-11-one 9β, and 3α,17α-dihydroxy-5α-androstan-11-one 9α. The structures of these metabolites (3–9) were elucidated using several spectroscopic techniques. Computer-aided prediction of potential biological activities of the isolated prednisone metabolites (3–9) revealed potential inhibition of prostaglandin E2 9-ketoreductase (PGE2 9-KR). Docking studies applied to PGE2 9-KR allowed recommendation of the metabolites 4, 8β, and 8α for further pharmacological study as PGE2 9-KR inhibitors.     

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.     

Clinical analysis on steroids. XII. Occurrence of D-homoannulation during the hot acid hydrolysis of 5β-pregnane-3α,20α-diol disulfate

Two D-homosteroids were isolated from the hydrolyzate of 5β-pregnane -3α,20α-diol disulfate (II) when it was refluxed in 3N hydrochloric acid. The structures of these steroids have been elucidated as 17α-methyl-D-homo-5β-androstane-3α, 17aβ-diol (VI) and 17α-methyl-17aγb-chloro-D-homo-5β-androstan-3α-ol (VIII) by instrumental analyses. The former was identical with a synthetic specimen derived from 5β-pregnane-3α,20β-diol di-sulfate (IV) by uranediol rearrangement. The main hydrolyzates obtained were 17α-ethyl-17β-methyl-18-nor-5β-androst-13-en-3α-ol (V) and 5β-pregnane-3α, 20α-diol (III).     

Comparative placental steroid synthesis. II. C19 steroid metabolism by guinea-pig placentas and fetal adrenals in vitro

Placental homogenates from guinea-pigs at 16, 20, 35 and 55 days gestation were incubated with 7α-³H-dehydroepiandrosterone and 4-¹⁴C-androstenedione and analyzed for conversion products by reverse isotope dilution methods. ¹⁴C-3α-Hydroxy-5α-androstan-17-one, ¹⁴C-androstane-3α, 17β-diol and ³Handrost-5-ene-3β, 17β-diol were isolated from homogenates incubated with substrates for 2 hours. ³H, ¹⁴C-Testosterone was isolated from preparations incubated for 15 minutes or with high substrate: tissue ratios. Androst-4-ene-3, 17-dione, 5α-androstane-3, 17-dione, 5β-androstanedione derivative and C₁₈ steroid formation could not be demonstrated. These results demonstrate the capacity of guinea-pig placentas to convert dehydroepiandrosterone and androstenedione to testosterone and to derivatives reduced in ring A (5α) and at carbon 17. The activity of the Δ⁵-3β-hydroxysteroid dehydrogenase enzyme system appears to have been rate limiting.Homogenates of adrenals from 44–55 day old fetuses converted 4-¹⁴C-pregnenolone to androst-4-ene-3, 17-dione and 6β- and 11β-hydroxyandrostenedione. A guineapig fetal-placental unit is postulated, with steroid metabolic characteristics different from the human unit. Both permit reduction of fetal adrenal cortisol production and placental removal of C₁₉ steroids.