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

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

Progesterone metabolism by major salivary glands of rat--II. Parotid gland

The metabolism of [4-14C]progesterone in the parotid salivary glands of nonpregnant female, pregnant female and male rats were investigated in vitro. The metabolic activity of the male rats was significantly lower than in either of the female groups. The pregnant group was metabolically more active than the nonpregnant female group, but his differences was not statistically significant. I homogenates and soluble fractions the main metabolite was 20-alpha-hydroxy- 4-pregnen-3-one in female rats. In male rats the main metabolites were 20-alpha-hydroxy-4- pregnen-3-one and 3-alpha-hydroxy-5-alpha-pregnan-20-one in homogenates and 20-alpha-hydroxy-4- pregnen-3-one in soluble fractions. In the microsomal fractions of both sexes polar compounds predominated. The results indicated the presence of at least the following progesterone metabolizing enzymes in art parotid salivary glands; 3-alpha-, 3-beta-, 20-alpha- and 20-beta-hydroxysteroid dehydrogenase, 5-alpha-and 5-beta-steroid hydrogenase and 17-alpha-steroid hydroxylase activities. Ind the homogenates and soluble fractions of female rats 20-alpha-hydroxysteroid dehydrogenase activity was significantly higher than in males.     

Effects of ten steroids on acridine orange uptake and beta-N-acetylglucosaminidase levels in rat liver lysosomes.

Ten steroids have been compared for their ability to modify the rate of uptake of acridine orange by rat liver and by rat liver lysosomes in vivo. The short-term effects of the ten steroids on the specific activity of a lysosomal enzyme, beta-N-acetylglucosaminidase, were also compared. Five of the ten steroids were administered as tritium-labelled compounds and the concentration of steroids or metabolites was measured in rat liver and liver lysosomes at 2.5h and 3.75h after administration. Cortisone acetate, etiocholanolone (5-beta-androstan-3-alpha-01-17-one) and testosterone accelerate and increase the uptake of acridine orange by rat liver lysosomes. Deoxycorticosterone, corticosterone, triamcinolone (9-alpha-fluoro-11-beta, 17, 21-trihydroxy-16-alpha-methyl-pregna-1, 4-diene-3, 20-dione), estradiol-17-beta and progesterone appear to inhibit the uptake of acridine orange by rat liver lysosomes at 2.5 hours. Cortisol and dexamethasone (9-alpha-fluoro-11-beta, 17, 21-trihydroxy-16-alpha-methyl-pregna-1, 4-diene-3, 20-dione) had little effect. All steroids with the exception of etiocholanolone and deoxycorticosterone increase with the specific activity of beta-N-acetylglucosaminidase in the lysosomal fraction at 2.5h. None of the effects at 2.5h are due to lowered protein levels. Lysosomal concentrations of radioactivity following the administration of tritiated steroids were greated for the glucocorticoids, corticosterone and cortisol. Estradiol-17-beta, progesterone and testosterone showed much lower concentrations of radioactivity in isolated lysosomes. Most of the lysosomal radioactivity (73-96%) was associated with the soluble fraction of the disrupted lysosomes.     

Specific deuterium labelling and computerized gas chromatography -- mass spectrometry in studies on the metabolism in vivo of a steroid sulphate in the rat.

The metabolism of 3beta-hydroxy-5alpha-pregnan-20-one sulphate was studied in bile fistula rats and in isolated perfused livers. Computerized gas chromatography--mass spectrometry, in combination with specific deuterium-labelling, was employed to follow the metabolic transformations. Male animals excreted metabolites into bile more rapidly than females, a finding which could be correlated with the preferential formation of glucuronide conjugates in the male liver. The major metabolic pathway in male rats involved the steps: hydrolysis, 2alpha-hydroxylation, oxidoreduction at C-3 and glucuronide conjugation, yielding 2alpha, 3alpha-dihydroxy-5alpha-pregnan-20-one glucuronide as the major metabolite. Only traces of the injected steroid sulphate were detected in bile from male animals. In contrast, the administered compound was the major steroid excreted in bile of female rats, where the main metabolite was identified as 3beta,15beta-dihydroxy-5alpha-pregnan-20-one sulphate. A minor metabolite, 3beta,16alpha-dihydroxy-5alpha-pregnan-20-one, was found as a monosulphate in female rats and as both a disulphate and a glucuronide conjugate in male rats. The deuterium content of the sulphated 15beta-and 16alpha-hydroxylated metabolites was consistent with metabolic pathways involving direct hydroxylation of the injected steroid sulphate. The results obtained from the liver perfusions were essentially the same as those from the experiments with bile fistula animals. This indicates that all the observed metabolic reactions took place in the liver.     

Uptake and metabolism of androgens by bovine spermatozoa

Spermatozoa from bovine ejaculates and cauda epiditymidis were incubated with either tritiated 17 beta-hydroxy-5 alpha-androstane-3-one (DHT) or 5 alpha-androstane-3 alpha, 17 beta-diol (3 alpha-diol). Examination of the medium incubations demonstrated metabolic conversion of both DHT and 3 alpha-diol when these steriods were incubated with ejaculated sperm. In addition to this interconversion, the following metabolities were identified: 5 alpha-androstane-3 beta, 17 beta-diol, (3 beta-diol), androsterone and 5 alpha-androstane-3, 17-dione (5 alpha-A-dione). Incubations with cauda spermatozoa showed similar metabolic patterns. Androgen binding was exhibited by both sperm types. Examination of the washed cauda sperm pellet, following incubations with 3 alpha-diol showed that the incubated steroid was the most abundantly bound. DHT and 5 alpha-androst-16-en-3 alpha-ol (delta 16-3 alpha-ol1 were also detected. The major part of the radioactivity bound in the sperm pellet was identified as DHT when this steroid was used as the substrate; the remaining radioactivity consisted of 3 alpha-diol and delta 16-3 alpha-ol. Investigations of ejaculated sperm pellets gave similar results apart from the additional identification of 5 alpha-androst-16-en-3 one (delta 16-3-one) and 5 alpha-androst-16-en-3 beta-ol (delta 16-3 beta-ol (delta 16-3 beta-ol).     

The identification of some human metabolites of norgestrel, a new progestational agent

Norgestrel 1 (racemic 13-beta-ethyl-17-alpha-hydroxygon-4-en-3-one) a progestational agent with an angular ethyl group between Rings C and D, was studied by mass spectrometry to discover its structural characteristics. Synthesis of postulated metabolites of Norgestrel 1 for use in identification is described and structural formulas are given. Urine was used as a source to characterize fractions via mass spectra, and the fraction spectra are listed. The major metabolite was 13-beta-ethyl-17-alpha-ethynl-5-beta-gonan-3-alpha-1m-beta-diol 8c.     

Studies on anabolic steroids--4. Identification of new urinary metabolites of methenolone acetate (Primobolan) in human by gas chromatography/mass spectrometry

The metabolism of methenolone acetate (17 beta-acetoxy-1-methyl-5 alpha-androst-1-en-3-one), a synthetic anabolic steroid, has been investigated in man. After oral administration of a 50 mg dose of the steroid to two male volunteers, twelve metabolites were detected in urine either in the glucuronide, sulfate or free steroid fractions. Methenolone, the parent steroid was detected in urine until 90 h after administration. Its cumulative urinary excretion accounted for 1.63% of the ingested dose. With the exception of 3 alpha-hydroxy-1-methylen-5 alpha-androstan-17-one, the major biotransformation product of methonolone acetate, metabolites were excreted in urine at lower levels, through minor metabolic routes. Most of methenolone acetate metabolites were isolated from the glucuronic acid fraction, namely methenolone, 3 alpha-hydroxy-1-methylen-5 alpha-androstan-17-one, 3 alpha-hydroxy-1 alpha-methyl-5 alpha-androstan-17-one, 17-epimethenolone, 3 alpha,6 beta-dihydroxy-1-methylen-5 alpha-androstan-17-one, 2 xi-hydroxy-1-methylen-5 alpha-androstan-3,17-dione, 6 beta-hydroxy-1-methyl-5 alpha-androst-1-en-3,17-dione, 16 alpha-hydroxy-1-methyl-5 alpha-androst-1-en-3,17-dione and 3 alpha,16 alpha-dihydroxy-1-methyl-5 alpha-androst-1-en-17-one. Interestingly, the metabolites detected in the sulfate fraction were isomeric steroids bearing a 16 alpha- or a 16 beta-hydroxyl group, whereas 1-methyl-5 alpha-androst-1-en-3,17-dione was the sole metabolite isolated from the free steroid fraction. Steroids identity was assigned on the basis of the mass spectral features of their TMS ether, TMS enol-TMS ether, MO-TMS, and d9-TMS ether derivatives and by comparison with reference and structurally related steroids. The data indicated that methenolone acetate was metabolized into several compounds resulting from oxidation of the 17-hydroxyl group and reduction of A-ring substituents, with or without concomitant hydroxylation at the C6 and C16 positions.     

Synthesis of specifically deuterium-labelled pregnanolone and pregnanediol sulphates for metabolic studies in humans.

A synthesis is reported of 3beta-hydroxy-5alpha-pregnan-20-one sulphate and the disulphate and 3-monosulphate of 5alpha-pregnane-3beta,20alpha-diol, labelled specifically with deuterium in high isotopic purity for metabolic studies in humans. Base-catalyzed equilibration of 3beta-hydroxy-5alpha-25R-spirostan-12-one (hemcogenin, II) with deuterium oxide, followed by removal of the 12-keto group and degradation of the sapogenin side-chain afforded 3beta-hydroxy-5alpha-[11,11-2H2]pregn-16-en-20-one (VII). Further deuterium atoms were introduced at the 3alpha and 20beta positions by reductions with sodium borodeuteride and lithium aluminum deuteride, respectively. These reactions led to 3beta-hydroxy-5alpha-[3alpha,11,11-2H3]pregnan-20-one (X; isotopic purity 87.2%) and 5alpha-[3alpha,11,11,20beta-2H4]pregnane-3beta,20alpha-diol (XIV; isotopic purity 83.9%). The 3-sulphate of the pregnanolone and the 3,20-disulphate of the pregnanediol were prepared directly form the free alcohols, while the 3-monosulphate of the pregnanediol was obtained via 5alpha-[3alpha,11,11,20beta-2H4]pregnane-3beta,20alpha-diol 20-acetate (XVII).     

Steroids and hypertension. 1--Gas-liquid chromatography and gas chromatography mass spectrometry of 3,15- and 3, 16-dihydroxy-17-oxosteroids

In order to analyse and quantitate the urinary 16-oxysteroids known or thought to be associated with hypertension, we have established for six 16-oxy-C19 reference steroids the following parameters: elution volume on lipophilic gel columns, gas chromatographic retention data expressed as methylene unit values of trimethylsilyl ether and O-methoxime trimethylsilyl ether derivatives on OV-1 and OV-17 packed columns and on SE-30 capillary column, and mass spectra of these compounds. These reference steroids were: 3 alpha, 16 alpha-dihydroxy-5 alpha-androstan-17-one, 3 alpha, 16 alpha-dihydroxy-5 beta-androstan-17-one, 3 beta, 16 alpha-dihydroxy-5 alpha-androstan-17-one, 3 beta, 16 alpha-dihydroxy-5-androsten-17-one, 3 beta, 16 beta-dihydroxy-5-androsten-17-one, 3 beta, 17 beta-dihydroxy-5-androsten-16-one and 3 alpha, 15 alpha-dihydroxy-5 beta-androstan-17-one. The proposed method was shown to be applicable to the specific analysis of 16-oxy-C19-steroids in biological samples since it achieved the selective isolation of these compounds from other steroids and their quantitative elution in a single fraction. The analysis of the urinary steroids of two patients with arterial hypertension demonstrated an elevated rate of 3 beta, 16 alpha-dihydroxy-5-androsten-17-one.     

Utilization and metabolic effects of acetaldehyde and ethanol in the perfused rat liver

1. The formation of the two 16-unsaturated alcohols 5alpha-androst-16-en-3alpha-ol and 5alpha-androst-16-en-3beta-ol from [5alpha-(3)H]5alpha-androst-16-en-3-one has been demonstrated in boar testis homogenates. 2. The optimum yield (23%) of the 3alpha-alcohol was obtained in the presence of NADPH, whereas that for the 3beta-alcohol (74%) was obtained when NADH was the added cofactor. 3. The two alcohols were not interconvertible. 4. Prolonged storage of boar testis tissue at -20 degrees C abolished the ability to form all androst-16-enes except androsta-4,16-dien-3-one from [4-(14)C]progesterone. 5. The production of 5alpha-androst-16-en-3-one and the two alcohols from [7alpha-(3)H]androsta-4,16-dien-3-one only occurred when fresh tissue was used, whereas reduction of [5alpha-(3)H]5alpha-androst-16-en-3-one was unaffected by storage of testis at -20 degrees C. 6. NADPH was the preferred cofactor for the reduction of androsta-4,16-dien-3-one. 7. The previously established conversion of androsta-5,16-dien-3beta-ol into androsta-4,16-dien-3-one was shown to be reversible, NADH and NADPH being equally effective cofactors. 8. Pathways of biosynthesis of 5alpha-androst-16-en-3alpha- and 3beta-ols, with the C(19) 3-oxo steroids as intermediates, are presented.     

On the existence of receptors to the pheromonal steroid, 5 alpha-androst-16-en-3-one, in porcine nasal epithelium

The binding of the odorant, 5 alpha-androst-16-en-3-one, to porcine nasal tissues, has been investigated using methods normally employed for studying both cytosolic and membrane-bound receptors. 5 alpha-Androst-16-en-3-one was generally taken up more avidly by homogenates of olfactory (nervous) tissue than by respiratory tissue, but binding to the former was only partially prevented by prior heating or by excess ligand, suggesting some degree of specific binding. At low protein concentration, saturable binding was noted but these data were not reproducible. The binding of a non-odorant, DHA, was only 2% that of 5 alpha-androst-16-en-3-one. Using agarose gel electrophoresis, some evidence was obtained for binding protein(s) to the odorous 16-adrostene in porcine respiratory tissues, that were absent from previously heated tissue. Experiments with SDS-treated, or cell-membrane-enriched preparations, of nasal epithelium did not show improved binding of 5 alpha-androst-16-en-3-one. We conclude that the extreme hydrophobicity of 5 alpha-androst-16-en-3-one is probably responsible for the high degree of non-specific binding noted and for variability in results. This is discussed in relation to other known odorous ligand/receptors in olfactory tissue, particularly that of 5 alpha-androstan-3-one.     

Disposition and metabolism of 16 beta-ethyl-17 beta-hydroxy-4-estern-3-one (TSAA-291), a new antiandrogen, in rats.

Matabolic fate of a new antiandrogen, 16 beta-ethyl-17 beta-hydroxy-4-estren-3-one (TSAA-291), was studied in rats. 14C-TSAA-291 intramuscularly injected as an aqueous suspension was absorbed gradually to give an increase in the plasma level which attained a plateau at 0.5 h, persisted till 8 h and then declined with an approx. half-life of 3.6 days. The drug was widely distributed in tissues, with the concns. almost equal to or higher than that in the plasma. The 14C-drug was eliminated mostly as metabolites within 10 days after dosing with higher activities found in the feces than in urine. Biliary 14C effectively underwent enterohepatic cycling. Biliary metabolites of TSAA-291 were characterized by the combined use of deuterium labeling and GLC-MS analysis. The metabolites identified were as follows: the parent drug, monohydroxy TSAA-291 having the additional hydroxy function in the steroid skeleton, 17 beta-hydroxy-16 beta-(1 xi-hydroxyethyl)-4-estren-3-one, 16 beta-ethyl-17 beta-hydroxy-5 beta-estran-3-one, 16 beta-ethyl-17 beta-hydroxy-5 alpha-estran-3-one, 16 beta-ethyl-5 beta-estrane-3 alpha, 17 beta-diol, 16 beta-ethyl-5 alpha-estrane-3 alpha, 17 beta-diol, 16 beta-ethyl-3 alpha-hydroxy-5 beta-estran-17-one and 16 beta-ethyl-3 alpha-hydroxy-5 alpha-estran-17-one. Monoketodihydroxy and/or trihydroxy metabolites were also detected in the bile.     

Configurational analysis and relative binding affinities of 16-methyl-5alpha-androstane derivatives

The four possible isomers 16beta-hydroxymethyl-5alpha-androstane-3beta,17beta-diol 1, 16alpha-hydroxymethyl-5alpha-androstane-3beta,17beta-diol 2, 16beta-hydroxymethyl-5alpha-androstane-3beta,17alpha-diol 3 and 16alpha-hydroxymethyl-5alpha-androstane-3beta,17alpha-diol 4 with proven configuration were converted into the corresponding 16beta-methyl-5alpha-androstane-3beta,17beta-diol 5, 16alpha-methyl-5alpha-androstane-3beta,17beta-diol 6, 16beta-methyl-5alpha-androstane-3beta,17alpha-diol 7, 16alpha-methyl-5alpha-androstane-3beta,17alpha-diol 8, furthermore into the 16beta-methyl-17beta-hydroxy-5alpha-androstane-3-one 13, 16alpha-methyl-17beta-hydroxy-5alpha-androstan-3-one 14, 16beta-methyl-17alpha-hydroxy-5alpha-androstan-3-one 15 and 16alpha-methyl-17alpha-hydroxy-5alpha-androstan-3-one 16. The steric structures of the resulting epimers were determined by means of 1H-, and 13C-NMR spectroscopy. In this way, comparison was possible with the C-16 epimers 5, 6 and 13, 14 prepared earlier by a different route, and the series of isomers could be completed with the steric structures of 16beta-methyl-17alpha-hydroxy-5alpha-androstan-3beta-ol 7 and 16alpha-methyl-17alpha-hydroxy-5alpha 8 and with their 3-keto derivatives 15 and 16. The relative binding affinities of the 16-methyl-5alpha-androstane-3beta,17-diols 5, 6, 7, 8 and 17-hydroxy-16-methyl-5alpha-androstan-3-ones 13, 14, 15, 16 were studied. The introduction of a 16-methyl substituent into 5alpha-androstane molecules substantially decreases the binding affinity to the androgen receptor and 16alpha-methyl derivatives were always bound more weakly than the 16beta-methyl isomers.     

Microbial pathways leading to steroidal malodour in the axilla

Odorous steroids, specifically the 16-androstenes, 5alpha-androstenol and 5alpha-androstenone, are widely accepted as being contributors to underarm odour, but the precursors and pathways to these odorous steroids were unclear. This study demonstrated that the axillary microflora could only generate odorous 16-androstenes from precursors that already contain the C16 double bond, such as 5,16-androstadien-3-ol and 4,16-androstadien-3-one. In incubations containing 5,16-androstadien-3-ol, mixed populations of Corynebacterium spp., isolated from the axilla, could generate many different 16-androstene metabolites, several of which were odorous. Isolation of individual Corynebacterium strains, followed by pure culture incubations with 5,16-androstadien-3-ol, revealed organisms capable of efficient, rapid reactions. However, no single isolate could carry out a full complement of the observed biotransformations. 16-Androstene metabolites were identified by gas chromatography-mass spectrometry (GC-MS), either by comparison with known standards, or by prediction from molecular ion and fragmentation patterns. Based on detection of these metabolites, a metabolic map for axillary corynebacterial 16-androstene biotransformations was proposed, detailing potential enzyme activities. In summary, the formerly implicated 4,16-androstadien-3-one, 5alpha-androstenone and 5alpha-androstenol were detected, along with previously unreported hydroxy- and keto-substituted 16-androstenes, 16-androstatrienones and 16-androstatrienols. Additionally, many other metabolites with steroidal fragmentation patterns were present, but have remained unidentified.A key observation was that very low prevalences of microorganisms capable of biotransforming 16-androstenes were present on skin. For example, from a panel of 21 individuals, only 4 of 18 mixed populations of corynebacteria, and only 4 of 45 Corynebacterium isolates, could biotransform 5,16-androstadien-3-ol.This study has increased understanding of the metabolic pathways involved in steroidal malodour formation, and has demonstrated that the biotransformations are more complex than previously anticipated. However, it is clear that further research is required, both to assess the level of contribution of 16-androstenes to underarm odour, and to further elucidate the pathways and odour molecules formed by corynebacteria.     

Conversion of 5 alpha-pregnane-3,20-dione, 3 alpha-hydroxy-5 alpha-pregnan-20-one and 3 beta-hydroxy-5 alpha-pregnan-20-one to delta 16-C19 steroids by the reconstituted delta 16-C19-steroid synthetase system

The substrate specificity of the reconstituted delta 16-C19-steroid synthetase system, which catalyzes the formation of 5,16-androstadien-3 beta-ol or 4,16-androstadien-3-one from pregnenolone or progesterone, respectively, was studied. The reconstituted system consisted of a partially purified cytochrome P-450, NADPH-cytochrome P-450 reductase, cytochrome b5 and NADH-cytochrome b5 reductase all from pig testicular microsomes. It was found that 5 alpha-reduced C21 steroids such as 5 alpha-pregnane-3,20-dione, 3 alpha-hydroxy-5 alpha-pregnan-20-one and 3 beta-hydroxy-5 alpha-pregnan-20-one can be substrates for the enzyme system, resulting in the formation of 5 alpha-androst-16-en-3-one, 5 alpha-androst-16-en-3 alpha-ol and 5 alpha-androst-16-en-3 beta-ol, respectively. The results suggest that 5 alpha-reduced delta 16-C19 steroids might be synthesized from pregnenolone and progesterone via 5 alpha-reduced C21 steroids as intermediates. The pathways would bypass 5,16-androstadien-3 beta-ol and 4,16-androstadien-3-one which have been assumed as obligatory intermediates in the formation of 5 alpha-reduced delta 16-C19 steroids from pregnenolone and progesterone.     

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.     

Microbial transformation of 5alpha,6alpha-epoxy-3beta-hydroxy-16-pregnen-20-one by Trichoderma viride

Fermentation of 5alpha,6alpha-epoxy-3beta-hydroxy-16-pregnen-20-one (4) with Trichoderma viride under aerobic condition yielded 3beta,5alpha,6beta-trihydroxy-16-pregnen-20-one (5) and 3beta,5alpha,6beta,15beta-tetrahydroxy-16-pregnen-20-one (6). Each microbial metabolite was characterized by spectroscopic methods. Compounds 6 and 3beta,5alpha,15beta-trihydroxy-16-pregnen-6,20-dione (7) are reported for the first time.     

Synthesis of 3 beta,16 beta,19-trihydroxyandrost-5-en-17-one and 16 beta,19-dihydroxyandrost-4-ene-3,17-dione and their 19-oxo derivatives

3 beta,16 beta,19-Trihydroxyandrost-5-en-17-one (12) was synthesized from 5 alpha-bromo-3 beta-acetoxy-6 beta,19-epoxyandrostan-17-one (2) through acetoxylation at C-16 beta of the enol acetate 4 with lead tetraacetate and reductive cleavage of the epoxide ring with zinc dust yielding the 3 beta,16 beta-diacetoxy-19-hydroxy steroid 11, followed by hydrolysis of the acetoxy groups with sulfuric acid. Jones oxidation of compound 11 followed by the acid hydrolysis gave the 19-oxo steroid 15. 5 alpha-Bromo-3 beta-hydroxy-16 beta-acetoxy-6 beta,19-epoxyandrostan-17-one (8), obtained by selective hydrolysis of the 3-formate 5 with ammonium hydroxide, was oxidized with Jones reagent to afford the 3-oxo steroid 16, which was converted into the 19-hydroxy derivative 17 by treatment with zinc dust. 16 beta,19-Dihydroxyandrost-4-ene-3,17-dione (18) and its 19-oxo derivative 21 were obtained from compound 17 through a similar reaction sequence.     

Androgen metabolism by rat epididymis. Metabolic conversion of 3H 5alpha-androstane-3alpha,17beta-diol, in vitro

The epididymis of adult rats metabolizes 3H 5alpha-androstane-3alpah,17beta-diol (3alpha-diol) by experiments in vitro. After incubation of tissue slices at 37 degrees C for 2 hours, 2% of the radioactivity was found in the water-soluble fraction whereas 98% was found to be ether soluble (free steroids). Further investigation of the free steroids showed the following to be present: 3alpha-diol 39.9%, DHT (17beta-hydroxy-5alpha-androstan-3-one) 33.7%, androsterone (3alpha-hydroxy-5alpha-androstan-17-one) 9.2%, 3beta-diol (5alpha-androstane-3beta,17beta-diol) 2.6%, 5alpha-A-dione (5alpha-androstan-3,17-dione) 1.1%, delta 16-3alpha-ol (5alpha-androst-16-en-3alpha-ol) 1.0%, delta16-3beta-ol (5alpha-androst-16-en-3beta-ol) 2.6%, delta 16-3-one (5alpha-androst-16-en-3-one) 2.9%, and polar compounds 3.3%. When segments of the epididymis (caput and cauda) were incubated in the same way, qualitatively similar metabolites were formed but a greater amount of 3alpha-diol was metabolized by the cauda epididymis. This increase was mainly accounted for by an increased formation of delta 16 compounds (14.3% in cauda, 4.3% in caput). This is most probably due to the presence of larger numbers of mature spermatozoa, which, as we have previously shown, form delta16 steroids from 3alpha-diol and DHT (5).     

Synthesis of steroidal lactone by penicillium citreo-viride

The biotransformations of a series of steroids by the fungus penicillium citreo-viride A.C.C.C. 0402 have been investigated, and the conversion to the same product testolactone (1) was observed from progesterone (2), dehydroepiandrosterone (3), 4-androstene-3, 17-dione (4), 5-androstene-3, 17-diol (5) with the exception of pregnenolone (6) and 3beta-hydroxy-5, 16-pregnadien-20-one (7). The possible metabolic pathways of the biotransformations were also discussed in the paper and the fungus penicillium citreo-viride A.C.C.C. 0402 was isolated during screening stains from samples collected from Zhengzhou, Henan province of China.