Metabolism of metandienone in man: identification and synthesis of conjugated excreted urinary metabolites, determination of excretion rates and gas chromatographic-mass spectrometric identification of bis-hydroxylated metabolites

After oral administration of metandienone (17 alpha-methyl-androsta-1,4-dien-17 beta-ol-3-one) to male volunteers conjugated metabolites are isolated from urine via XAD-2-adsorption, enzymatic hydrolysis and preparative high-performance liquid chromatography (HPLC). Four conjugated metabolites are identified by gas chromatography-mass spectrometry (GC/MS) with electron impact (EI)-ionization after derivatization with N-methyl-N-trimethyl-silyl-trifluoroacetamide/trimethylsilyl-imidazole (MSTFA/TMS-Imi) and comparison with synthesized reference compounds: 17 alpha-methyl-5 beta-androst-1-en-17 beta-ol-3-one (II), 17 alpha-methyl-5 beta-androst-1-ene-3 alpha,17 beta-diol (III), 17 beta-methyl-5 beta-androst-1-ene-3 alpha,17 alpha-diol (IV) and 17 alpha-methyl-5 beta-androstane-3 alpha,17 beta-diol (V). After administration of 40 mg of metandienone four bis-hydroxy-metabolites--6 beta,12-dihydroxy-metandienone (IX), 6 beta,16 beta-dihydroxy-metandienone (X), 6 beta,16 alpha-dihydroxy-metandienone (XI) and 6 beta,16 beta-dihydroxy-17-epimetandienone (XII)--were detected in the unconjugated fraction. The metabolites III, IV and V are excreted in a comparable amount to the unconjugated excreted metabolites 17-epimetandienone (VI), 6 beta-hydroxy-metandienone (VII) and 6 beta-hydroxy-17-epimetandienone (VIII). Whereas the unconjugated excreted metabolites show maximum excretion rates between 4 and 12 h after administration the conjugated metabolites III, IV and V are excreted with maximum rates between 12 and 34 h.     

Stereochemistry of olefinic bond formation in defensive steroids of Acilius sulcatus (Dytiscidae)

The defensive secretion of Acilius sulcatus contains a number of pregnane derivates: cortexone, 20alpha-hydroxy-4-pregnen-3-one, together with the unusual delta4,6 dienes, 6,7-dehydrocortexone, 20alpha-hydroxy-4,6-pregnadien-3-one and 4,6-pregnadien-3,20-dione. The synthesis of all these steroids except cortexone is described. Complete separation of the steroids of Acilius can be achieved by high-performance liquid chromatography on the reversed-phase column system. During biosynthesis of the Acilius steroids from cholesterol, introduction of the delta4 and delta6 bonds involves elimination of the 4beta and 7beta hydrogens, respectively. Possible mechanisms of formation of the delta4,6 steroids are discussed.     

Effect of glucocorticoids on the response of airway smooth muscle to catecholamine and resorcinol beta-agonists

The influence of hydrocortisone (11 beta, 17 alpha, 21-trihydroxy-pregn-4-ene-3,20-dione) or of methylprednisolone (6 alpha-methyl-11 beta, 17 alpha-21-trihydroxy-1,4-pregnadiene-3,20-dione) on the response of airway smooth muscle to a variety of beta-adrenergic bronchodilators was evaluated using incubated guinea pig tracheal rings, preconstricted with histamine. The adrenergic agonists chosen for this study included the nonselective beta 1- and beta 2-catecholamine, isoproterenol, the selective beta 2-catecholamine, rimiterol, and the selective beta 2-resorcinols, fenoterol and terbutaline. When the incubated rings were pretreated with 10-50 micrograms/mL of the steroids, there was a significant enhancement in smooth muscle sensitivity and reactivity to rimiterol and isoproterenol. Tracheal response to fenoterol or terbutaline, on the other hand, was not altered by the glucocorticoids. When used alone, neither steroid exerted an inotropic influence on the tracheal smooth muscle. The results of our study indicate that glucocorticoid enhancement of adrenergic bronchodilators is selective for catecholamines, and not for resorcinols.     

Purification and properties of an NADPH-dependent 21-oxo-20-hydroxysteroid reductase (17beta-aldol reductase) from sheep liver. Isolation of the 20beta-glycol product.

This investigation was undertaken to test the hypothesis that steroidal 20-hydroxy-21-aldehydes are intermediates in an alternative pathway of corticosteroid metabolism leading to steroidal 20,21-diols. A NADPH-dependent 21-oxo-20-hydroxysteroid reductase which catalyzed the reduction of 11beta,17,20beta-trihydroxy-3-keto-4-pregnen-21-al (isocortisol) to 11beta,17,20beta,21-tetrahydroxy-4-pregnen-3-one (Reichstein's compound E) was prepared from sheep liver. Other steroidal 17-aldols were also good substrates. Some steroidal 17-oxoaldehydes, D-, and L-glyceraldehyde were reduced, but less effectively than the steroidal aldols. Steroidal ketols and 21-oic acids were not substrates. The enzyme contains--SH groups, has a pH optimum of 6.9 to 7.5 and a molecular weight of about 28,000. Reversibility of the enzymic reaction could not be demonstrated. The reduction product obtained from isocortisol was isolated and characterized. Other 17-glycols were derived from their respective steroid aldols. Reductase activity was also present in hamster and rat liver. From a comparison of 21-oxo-20-hydroxysteroid reductase and 21-hydroxysteroid dehydrogenase with respect to pH optima, substrate specificity, stability to heat, and kinetic constants, we conclude that the two enzymes are distinct.     

Methandrostenolone metabolism in humans: potential problems associated with isolation and identification of metabolites

Methandrostenolone dose (amount and duration) and methods of isolation from urine can influence the identification and quantitation of methandrostenolone metabolites. Long-term use of methandrostenolone at high dosages led to the appearance of unmetabolized drug in the urine and contributed to the identification of a previously unreported metabolite, 3 beta, 6 section, 17 beta-trihydroxy-17 alpha-methyl-5 section-1-androstene. Exposure of methandrostenolone in vitro to acid conditions induced a retropinacol rearrangement in the D-ring of the methandrostenolone molecule, causing the formation of 18-nor-17,17-dimethyl-1,4,13(14)-androstatrien-3-one in large amounts. The same acidic conditions led to the addition of a hydroxyl at the 6 position of the B-ring of either the retropinacol rearrangement products or native methandrostenolone resulting in the formation of 6 beta-hydroxy-18-nor-17,17-dimethyl-1,4,13(14)-androstatrien-3-one, 6 alpha- hydroxy-18-nor-17,17-dimethyl-1,4,13(14)-androstatrien, 6 beta-17 alpha-methyl-1,4-androstadien-3-one and 6 alpha,17 beta-dihydroxy-17 alpha-methyl-1,4-androstadien-3-one. Hydroxylation of native methandrostenolone at the 6 position also occurs endogenously. However, no evidence of an endogenous retropinacol rearrangement was found. Silylating agents alone can induce the formation of small amounts of 6 beta-17 beta-dihydroxy-17 alpha-methyl-1,4-androstadien-3-one. Discrepancies between previously published reports on methandrostenolone metabolism in man are discussed and compared with an animal model.     

Polar corticosteroids in human neonatal urine; Synthesis and gas chromatography-mass spectrometry of ring a reduced 6-hydroxylate corticosteroids

This report describes the synthesis of 3α, 6β, 11β, 17α, 21-pentahydroxy-5β-pregnane-20-one, 3α, 6β, 11β, 17α, 21-pentahydroxy-5α-pregnane-20-one, 3α, 6α, 11β, 17α, 21-pentahydroxy-5β-pregnane-20-one, 3α, 6α, 11β, 17α, 21-pentahydroxy-5α-pregnane-20-one, 3α, 6β, 17α, 21-tetrahydroxy-5β-pregnane-11, 20-dione, 3α, 6β, 17α, 21-tetrahydroxy-5α-pregnane-11, 20-dione, 3α, 6α, 17α, 21-tetrahydroxy-5β-pregnane-1 1, 20-dione and 3α, 6α, 17α, 21-tetrahydroxy-5α-pregnane-11, 20-dione.The gas chromatographic-mass spectrometric properties of these compounds are given. Proof of structure was accomplished using gas chromatography-mass spectrometry, microchemical reactions, optical rotatory dispersion and nuclear magnetic resonance spectroscopy.     

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.     

Steroid metabolism by ovarian follicles of the sea bass Dicentrarchus labrax

Ovarian samples from fear sea bass, Dicentrarchus labrax, were collected for the in vitro incubations during the spawning period. Follicles with fully developed vitellogenic oocytes showing central germinal vesicle (stage I follicles) and follicles with oocytes showing initial germinal vesicle migration (stage II follicles) were treated with either (1) 20 μg sea bass hypophysis plus 50 ng 17-hydroxyprogesterone (17-P), (2) 20 μg hypophysis alone, (3) 50 ng 17-P alone and (4) media alone. Structure-activity experiments used stage II follicles treated with several dosages (0.1, 1.0 and 10.0 ng/ml) of either 17-P, 17,20β-P, or 17,20β,21-P. Free and conjugated (sulfates and glucuronides) levels of the established teleost oocyte maturation inducing steroids (MIS), i.e. 17,20β-dihydroxy-4-pregnen-3-one (17,20β-P) and 17,20β,21-trihydroxy-4-pregnen-3-one (17,20β,21-P) were measured in the incubation media by high performance liquid chromatography. Our results show that the synthesis of free and conjugated 17,20β-P is constant (0.1–0.2 ng/ml) in all incubates. In contrast, the synthesis of free and conjugated 17,20β,21-P is higher in incubates containing stage II follicles (up to 5 ng/ml) than in those having stage I follicles (up to 3 ng/ml; P<0.01). Structure-activity data reveal that 17-P is not effective at inducing in vitro germinal vesicle breakdown whereas both 17,20β-P and 17,20β,21-P are equally potent and highly effective. These results demonstrate that 17,20β-P and 17,20β,21-P are synthesized in vitro by follicles of sea bass and that sulfation is the main route for the metabolism of the C₂₁-steroids in riper follicles. The highest levels of 17,20β,21-P, found in incubates containing stage II follicles, points at 17,20β,21-P, rather than 17,20β-P, as the most probable MIS in sea bass, nonetheless, this hypothesis requires further confirmation.     

Characterization and quantification of the androgen and glucocorticoid receptors in cytosol from rat skeletal muscle

The binding of the radioactive synthetic hormonal steroids [3H]dexamethasone (9 alpha-fluoro-11 beta, 17 alpha, 21-trihydroxy-16 alpha-methyl-1,4-pregnadiene-3,20-dione) and [3H]methyltrienolone (17 beta-hydroxy-17 alpha-methyl-4,9,11-estratien-3-one) to cytosol from rat skeletal muscle was studied using dextran-coated charcoal to separate unbound and receptor-bound steroid. The rates of association, dissociation, and degradation of the complexes of dexamethasone and methyltrienolone with receptor were highly dependent on temperature. The temperature dependence of association was greater for dexamethasone, and that of degradation was greater for methyltrienolone. Dissociation rates were insignificant for both steroid-receptor complexes compared to association and degradation rates. The apparent equilibrium dissociation constants for the binding of dexamethasone and methyltrienolone to their receptor binding sites were about 7 and 0.3 nM, respectively, regardless of temperature (0. 15 or 23 degrees C). The lack of influence of temperature on the equilibrium constants indicate that the binding was of hydrophobic character, and the corresponding free energy changes upon binding of dexamethasone and methyltrienolone to their respective binding sites were -41 and -49 kJ mol-1 under equilibrium conditions at 0 degrees C. The apparent maximum number of binding sites determined from Scatchard plots under these conditions was about 1900 fmol/g of tissue, 3500 fmol/mg of DNA or 30 fmol/mg of protein in the case of the dexamethasone receptor, and the corresponding figures for the methyltrienolone were about 100 fmol/g of tissue, 200 fmol/mg of DNA or 2 fmol/mg of protein. The ligand specificities of the binding sites for dexamethasone and methyltrienolone were typical of a glucocorticoid and an androgen receptor, respectively. Both steroid-receptor complexes were retained on DNA-cellulose columns, and were eluted by NaCl at an ionic strength of 0.1. The DNA-cellulose step purified about 20 times, and was used to allow gel exclusion chromatography and electrofocusing. Both steroid-receptor complexes were excluded from a column of Sephadex G-150. Electrofocusing in preparative columns gave reproducible patterns consisting of three peaks for each receptor. The apparent isoelectric points were 5.4, 5.6 and 6.2 for the glucocorticoid receptor, and 5.9, 6.2 and 8.5 for the androgen receptor.     

Synthesis of deuterium-labeled tetrahydrocortisol and tetrahydrocortisone for study of cortisol metabolism in humans

A method is described for the preparation of multi-labeled tetrahydrocortisol (3alpha,11beta,17alpha,21-tetrahydroxy-5beta-[1, 2,3,4,5-2H5]pregnan-20-one, THF-d5), allo-tetrahydrocortisol (3alpha,11beta,17alpha,21-tetrahydroxy-5alpha-[1 ,2,3,4,5-2H5]pregnan-20-one, allo-THF-d5), and tetrahydrocortisone (3alpha,17alpha,21-trihydroxy-5beta-[1,2,3,4,5-2H5]pre gnane-11,20-dione, THE-d5) containing five non-exchangeable deuterium atoms in the steroid ring A. Reductive deuteration at C-1, C-2, C-3, C-4, and C-5 of prednisolone or prednisone was performed in CH3COOD with rhodium (5%) on alumina under the deuterium atmosphere. The isotopic purities of the labeled compounds as [2H5]-form were estimated to be 86.17 atom%D for THF-d5, 74.46 atom%D for allo-THF-d5 and 81.90 atom%D for THE-d5, based on the ion intensities in the region of the molecular ion of methoxime-trimethylsilyl (MO-TMS) derivatives measured by GC-MS.     

甾体1，4-脱氢和11α-羟基化反应的两种不同微生物转化

Two kinds of micro-organism, Arthrobacter sp. AX86(1,4-dehdrogenator)and Absidia sp. A28(11α-hydroxylator) were used in this experiment. Two different fermentation techniques were performed to accomplish the multiple conversional reactions for producing 16β-methyl-11α, 17α, 21-trihydroxy-1,4-pregnadiene-3,20-dione (Ⅲ) from 16β-methyl-3β, 17α,21-trihydroxy-5α-pregnane-20-one-21-acetate(1) 1)To produce product(Ⅲ)by means of a two-step fermentation method which were independently performed first by Arthrobacter and next by Abslaia, and 2)the product was obtained by a sequential fermentation system of aforesaid two micro-organisms in a single fermentor without isolation of the intermediates from the mixture. Our results showed that in both fermentation systems high yield of product was obtained. However, according to the technical simplicity, shorter duration of fermentation cycle and efficient yield of product, the second method is better than the first one.     

Stereospecific 1,4-addition to an alpha,beta-unsaturated steroidal epoxide: syntheses of new 15-oxygenated sterols

3 beta-Benzoyloxy-14 alpha,15 alpha-epoxy-5 alpha-cholest-7-ene (1) is a key intermediate in the synthesis of C-7 and C-15 oxygenated sterols. Treatment of 1 with benzoyl chloride resulted in the formation of 3 beta,15 alpha-bis-benzoyloxy-7 alpha-chloro-5 alpha-cholest-8(14)-ene (2). Reaction of 2 with LiAlH4 or LiAlD4 resulted in the formation of 5 alpha-cholest-7-ene-3 beta,15 alpha-diol (3a) or [14 alpha-2H]5 alpha-cholest-7-ene-3 beta,15 alpha-diol (3b). Diol 3b was selectively oxidized by Ag2CO3/celite to [14 alpha-2H]5 alpha-cholest-7-en-15 alpha-ol-3-one (4). Treatment of 1 with MeMgI/CuI gave 7 alpha-methyl-5 alpha-cholest-8(14)-ene-3 beta,15 alpha-diol (5). Selective oxidation of 5 with pyridinium chlorochromate (PCC)/pyridine or oxidation with PCC resulted in the formation of 7 alpha-methyl-5 alpha-cholest-8(14)-en-3 beta-ol-15-one (6) and 7 alpha-methyl-5 alpha-cholest-8(14)-ene-3,15-dione, respectively. Reduction of 6 with LiAlH4 yielded 5 and 7 alpha-methyl-5 alpha-cholest-8(14)-ene-3 beta,15 beta-diol (6). Reaction of 1 with benzoic acid/pyridine gave 3 beta,7 alpha-bis-benzoyloxy-5 alpha-cholest-8(14)-en-15 alpha-ol (9). Treatment of 9 with LiAlH4 or ethanolic KOH resulted in the formation of 5 alpha-cholest-8(14)-ene-3 beta,7 alpha,15 alpha-triol (10). Dibenzoate 9, upon brief treatment with mineral acid, gave 3 beta-benzoyloxy-5 alpha-cholest-8(14)-ene-15-one (11). Oxidation of 9 with PCC yielded 3 beta,7 alpha-bis-benzoyloxy-5 alpha-cholest-8(14)-ene-15-one (12). Ketone 12 was also prepared by the selective hydride reduction of 5 alpha-cholest-8(14)-en-7 alpha-ol-3,15-dione (13) to give 5 alpha-cholest-8(14)-ene-3 beta,7 alpha-diol-15-one (14), which was then treated with benzoyl chloride to produce 12.     

New steroidal anti-inflammatory antedrugs: methyl 21-desoxy-21-chloro-11beta,17alpha-dihydroxy-3,20-dioxo-1, 4-pregnadiene-16alpha-carboxylate, methyl 21-desoxy-21-chloro-11beta-hydroxy-3,20-dioxo-1, 4-pregnadiene-16alpha-carboxylate, and their 9alpha-fluoro derivatives*

To a series of 21-desoxy-21-chloro-corticosteroids, a metabolically labile methoxycarbonyl group at C-16 has been incorporated. The approach is to synthesize locally active compounds that are hydrolyzed to inactive and readily excretable acid metabolites upon entry into the systemic circulation. Novel antedrugs were evaluated for anti-inflammatory activity and their adverse effects in an acute and semichronic croton oil-induced ear edema bioassay. Binding affinity to glucocorticoid receptors and induction of L-tyrosine-2-oxoglutarate aminotransferase were studied in hepatoma tissue culture cells. After a single topical application in the croton oil-induced ear edema bioassay, treatment with all the compounds resulted in dose-dependent inhibition of edema. From these dose-response profiles, the following ID(50) values (nmol/ear resulting in a 50% reduction of edema) were calculated: 540, 618, 454, and 346 nmol for prednisolone (P), methyl 21-desoxy-21-chloro-11beta,17alpha-dihydroxy-3,20-dioxo-1, 4-pregnadien-16alpha-carboxylate (PClCM), methyl 21-desoxy-21-chloro-11beta,17alpha-dihydroxy-9alpha-fl uoro-3, 20-dioxo-1,4-pregnadien-16alpha-carboxylate (FPClCM), and methyl 21-desoxy-21-chloro-9alpha-fluoro-11beta-hydroxy-3,20-dioxo- 1, 4-pregnadien-16alpha-carboxylate (FDPClCM), respectively. Results of the 5-day rat croton oil ear edema bioassay indicated that, in contrast with the parent compound P, the novel steroidal antedrugs did not significantly alter body weight gain, thymus weights, or plasma corticosterone levels. The binding affinities for cytosolic hepatoma tissue culture glucocorticoid receptors were 33, 201, 471, 5304, and 3765 nM for P, PClCM, FPClCM, methyl 21-desoxy-21-chloro-11beta-hydroxy-3,20-dioxo-1, 4-pregnadien-16alpha-carboxylate (DPClCM), and FDPClCM, respectively. Collectively, results of these investigations suggest that modifications of P, which included replacement of 21-hydroxyl group with chlorine and addition of 16-methoxycarbonyl group with or without 17-hydroxyl moiety, retained the topical anti-inflammatory activity of the parent compound P without significant adverse systemic effects.     

Synthesis of 3-methyl-3-hydroxy-6-oxo-androstane derivatives

3alpha,17beta-Dihydroxy-3beta-methyl-5alpha-androstan-6-one (1) and 3beta,17beta-dihydroxy-3alpha-methyl-5alpha-androstan-6-one (13) were prepared by the reaction of methylmagnesium bromide with the 3-ketosteroids. Structures and configurations in position 3 were determined by NMR spectra. Substitution in the position 6 influences the ratio of the products.     

Marine sterols. XIII.★ Isolation and synthesis of 1β,3β,5,6β-tetrahydroxy-5α-androstan-17-one from the soft coral Sarcophyton glaucum

A new polyhydroxysterol 1β,3β,5,6β-tetrahydroxy-5α-androstan-17-one ($\text{1}$) was isolated from the soft coral $\text{Sarcophyton glaucum}$. The structure of $\text{1}$ was deduced from comparison of the spectral data with those of known 1β,3β,5α,6β-tetrahydroxysterols and confirmed by the synthesis starting from 1β,3β-dihydroxy-5,16-pregnadien-20-one ($\text{6a}$)     

18-nor-Podocarpanes and podocarpanes from the Bark of Taiwania cryptomerioides

Seven nor- and podocarpane-type diterpenes were isolated from the bark of Taiwania cryptomerioides Hayata, including three 18-nor-podocarpanes: 18-nor-1beta,4alpha,14-trihydroxy-13-methoxy-8,11,13-podocarpatriene (1), 18-nor-1beta,4alpha,13,14-tetrahydroxy-8,11,13-podocarpatrien-7-one (2), 18-nor-1beta,4alpha,14-trihydroxy-13-methoxy-8,11,13-podocarpatrien-7-one (3), 1beta,14,19-trihydroxy-13-methoxy-8,11,13-podocarpatrien-7-one (4), 1beta,13,14,18-tetrahydroxy-8,11,13-podocarpatrien-7-one (5), 18-acetoxy-1beta,13,14-trihydroxy-8,11,13-podocarpatrien-7-one (6), and 1beta,14,18-trihydroxy-13-methoxy-8,11,13-podocarpatrien-7-one (7). Their structures were determined by application of 1D and 2D NMR spectroscopy and other techniques. Podocarpane-type diterpenes do not occur extensively in nature, and the presumed oxidative enzyme in this plant will be of interest to identify.     

Oocyte maturation-inducing steroids in protandrous black porgy, Acanthopagrus schlegeli

The study objectives aimed to investigate the maturation-inducing steroid (MIS) in marine protandrous black porgy, Acanthopagrus schlegeli. The characteristics of oocyte maturation were also described. Females were injected with two successive doses of LHRH analog (LHRH-A, 10 and 50 microg/kg of fish). The ovarian tissue was obtained at 6-h intervals for in vitro oocyte maturation. Both 17,20 beta-dihydroxy-4-pregnen-3-one (DHP) and 17,20 beta,21-trihydorxy-4-pregnen-3-one (20 beta-S) were the most effective steroids to induce in vitro maturation (e.g. germinal vesicle breakdown, GVBD) in oocytes cultured for either 24 h or 1 min. 20 beta-S had a better potency than DHP in inducing oocyte maturation. 17-hydroxyprogesterone, 11-deoxycortisol, and 20 beta-21-dihydroxy-4-pregnen-3-one also significantly induced oocyte maturation at high concentrations. The process of oocyte maturation (after the injection of LHRH analog) was founded to be divided into four stages: hormone-insensitive stage (insensitive to gonadotropin and MIS); MIS-insensitive (respond to gonadotropin, but not MIS); MIS-sensitive (respond to MIS); and spontaneous stage (GVBD in the hormone-free condition), respectively. Cycloheximide blocked GVBD at the MIS-insensitive stage, control (hormone-free), and hormone-induced GVBD at the MIS-sensitive stage in a dose-dependent effect.     

Neonatal urinary steroids in Smith-Lemli-Opitz syndrome associated with 7-dehydrocholesterol reductase deficiency.

The biosynthetic abnormality in Smith-Lemli-Opitz syndrome (SLOS) is a deficiency of 7-dehydrocholesterol (7DHC) reductase, the enzyme responsible for catalyzing the final step in the Kandutsch-Russell pathway for cholesterol synthesis. Because the disposition of 7DHC and 8-dehydrocholesterol [8DHC; cholesta-5,8(9)-dien-3beta-ol] produced in this syndrome is little understood, we have analyzed urine from three young infants by gas chromatography/mass spectrometry to characterize its steroid metabolites. All steroid metabolites of adrenal origin found in normal infant urine were also found in urine from the patients with SLOS but in reduced amount. Quantitatively, the major steroids in these SLOS patients were identified by mass spectrometry as homologs of normal neonatal steroids possessing an additional double bond. Generally, two forms of each steroid were present in a similar amount. Because of the markedly increased levels of 7DHC and 8DHC in SLOS, these almost certainly represented the 5,7 and 5,8(9) unsaturated forms of each metabolite. The most abundant steroids were tentatively identified as 3beta,16alpha-dihydroxy-5,7-pregnadien-20-one and 3beta,16alpha-dihydroxy-5,8(9)-pregnadien-20-one, although similar 21-hydroxylated steroids and homologs of 16alpha-hydroxy-DHEA were also found. This study shows that all enzymatic steps used by cholesterol in the DHEA synthetic pathway are also functional for 7DHC and 8DHC.     

Studies on anabolic steroids--11. 18-hydroxylated metabolites of mesterolone, methenolone and stenbolone: new steroids isolated from human urine.

New metabolites of mesterolone, methenolone and stenbolone bearing a C18 hydroxyl group were isolated from the steroid glucuronide fraction of urine specimens collected after administration of single 50 mg doses of these steroids to human subjects. Mesterolone gave rise to four metabolites which were identified by gas chromatography/mass spectrometry as 18-hydroxy-1 alpha-methyl-5 alpha-androstan-3,17-dione 1, 3 alpha,18-dihydroxy-1 alpha-methyl-5 alpha-androstan-17-one 2, 3 beta,18-dihydroxy-1-alpha-methyl-5 alpha-androstan-17-one 3 and 3 alpha,6 xi,18-trihydroxy-1 alpha-methyl-5 alpha-androstan-17-one 4. These data suggest that mesterolone itself was not hydroxylated at C18, but rather 1 alpha-methyl-5 alpha-androstan-3,17-dione, an intermediate metabolite which results from oxidation of mesterolone 17-hydroxyl group. In addition to hydroxylation at C18, reduction of the 3-keto group and further hydroxylation at C6 were other reactions that led to the formation of these metabolites. It is of interest to note that in the case of both methenolone and stenbolone, only one 18-hydroxylated urinary metabolite namely 18-hydroxy-1-methyl-5 alpha-androst-1-ene-3,17-dione 5 and 18-hydroxy-1-methyl-5 alpha-androst-1-ene-3,17-dione 6 were both detected in post-administration urine specimens. These data indicate that the presence of a methyl group at the C1 or C2 positions in the steroids studied is a structural feature that seems to favor interaction of hepatic 18-hydroxylases with these steroids. These data provide further evidence that 18-hydroxylation of endogenous steroids can also occur in extra-adrenal sites in man.     

Studies on the Transformation of Steroids by Microorganisms

Microbiological conversions of Reichstein’s substance S (4-pregnene-17α,21-diol-3,20-dione) and hydrocortisone to their corresponding 20β-hydroxy derivatives were achieved by means of numerous strains of Streptomyces such as S. diastaticus (ATCC 3315), S. flavogriseus (H-4449), S. albus (ATCC 3351) etc., and it became apparent that 20-carbonyl reduction is the, wide-spread type of transformation in the Streptomyces species.

Moreover, several interesting strains having both l-dehydrogenating and 20-carbonyl reducing activities were detected. For instance, when Reichstcin’s substance S was used as substrate 1,4-pregnadiene-17α,21-diol-3,20-dione, 4-pregnene-17α,20β,21-triol-3-one and 1,4-pregnadiene-17α,20β,21-triol-3-one were isolated simultaneously using S. flaveolus (D-551), s. roseochromogenes (O-36) etc. These strains also exhibited similar transformation patterns in the use of hydrocortisone.