Synthesis of free and sulphoconjugated 16-androstene steroids by the Leydig cells of the mature domestic boar

This study examined the involvement of sulphoconjugation in the biosynthesis of the 16-androstene steroids in Leydig cells of the mature boar, since the formation of steroid sulphoconjugates can reduce the levels of these steroids that accumulate in fatty tissue. Leydig cells were purified from testes of mature male pigs and incubated with pregnenolone, or various individual 16-androstene steroids for 10 min, 1, 4 and 8h. Sulphoconjugated steroids were recovered by solid-phase extraction followed by solvolysis. Profiles of unconjugated and sulphoconjugated steroids were analysed by HPLC. Steroids present in the sulphoconjugated fractions were purified, derivatised as O-methoxime/trimethylsilyl ethers (MO-TMS), and subsequently identified using gas chromatography-mass spectrometry (GC-MS). The principal metabolite produced from incubations with pregnenolone, androstadienol, androstadienone and 5alpha-androstenone was 3beta-androstenol. 16-Androstene steroids that were sulphoconjugated included 5alpha-androstenone, 3beta-androstenol and 3alpha-androstenol. Approximately 70% of the total amount of each 16-androstene steroid was in its sulphoconjugated form after incubations for 4h or more. The finding that sulphoconjugated 5alpha-androstenone was present in large amounts suggests that this steroid may be converted from a 3-keto to a 3-enol form which is subsequently sulphoconjugated. These findings emphasise the need to consider the impact of sulphoconjugation of the 16-androstene steroids and their role in contributing to boar taint.     

Factors affecting the pheromone composition of voided boar saliva

The pheromone binding protein 'pheromaxein' which binds the pheromonal 16-androstene steroids in the saliva of the male pig (boar), was degraded and lost its binding activity in saliva incubated in air for 72 h at 21 degrees C and 37 degrees C. However, pheromaxein and its binding activity were retained in saliva incubated for 168 h at 4 degrees C. When the 3H-labelled pheromones 5 alpha-androst-16-en-3 alpha-ol (3 alpha-androstenol), 5 alpha-androst-16-en-3-one (5 alpha-androstenone) and 5 alpha-androst-16-en-3 beta-ol (3 beta-androstenol) were incubated with boar saliva for 168 h at 21 degrees C, 3 alpha-androstenol was primarily converted to 5 alpha-androstenone and 5 alpha-androstenone to 3 beta-androstenol; 3 beta-androstenol was unchanged. Evidence was obtained for microorganisms being responsible for these steroid transformations.     

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.     

The metabolism in man of (3H)-5alpha-16-androsten-3alpha-ol and of (3H)-5alpha-16-androsten-3-one

The in vitro metabolism in man of two 16-androstene steroids, 5alpha-16-androsten-3-one and 5alpha-16-androsten-3alpha-ol, has been studied using 3H-labelled tracers. 4 healthy subjects (2 of each sex) were chosen, and each labelled steroid was administered, by a single injection, to 1 man and 1 woman. Disappearance of (3H)-3alpha-androstenol in the subjects receiving this compound followed a curve which indicated a two-pool distribution in both cases; metabolic clearance rates for these subjects were found to be 3,790 1/24 h in the man and 3,120 1/24 h in the woman. Blood production rates calculated for the 3alpha-androstenol-treated subjects were 875 microgram/24 h in the man and 1,780 microgram/24 h in the woman. Recovery of 3H in the urine of all 4 subjects was very low, between 28 and 42%. Conversion of the injected precursors to urinary 3alpha-androstenol was 13.5 and 12.7% in the 2 men and 6.1 and 5.9% in the 2 women. The male subjects were found to have a lower 24-hour urinary 3alpha-androstenol output (570 and 387 microgram/24 h) than the average for men of their age. The urinary 3alpha-androstenol output in the women was 225 and 276 microgram/24 h, and was within the normal range for women. The urine production rates of 3alpha-androstenol were 2,470 and 4,090 microgram/24 h in the male and female subjects, respectively; the difference between the blood and urine production rates of this compound are thought to indicate the direct secretion of conjugates. Urine production rates of 5alpha-androstenone (measured as 3alpha-androstenol) were 2,370 and 4,340 microgram/24 h in the male and female subjects, respectively.     

Positive relationship between menstrual synchrony and ability to smell 5alpha-androst-16-en-3alpha-ol

To explore the possibility that compounds which were identified as pheromones in experimental animals mediate human menstrual synchrony, we examined the relationship between menstrual synchrony and the ability to smell putative pheromones, 5alpha-androst-16-en-3alpha-ol (3alpha-androstenol) and 5alpha-androst-16-en-3-one (5alpha-androstenone). When we examined menstrual synchrony among 64 women living together in a college dormitory, we found that 24 (38%) of them became synchronized with room-mates in 3 months. Afterwards, dilution series of 3alpha-androstenol and 5alpha-androstenone and the control odorant (pyridine) were presented to the 64 women and sensitivity to the odors was compared between synchronized and non-synchronized women. No difference was found between the two groups of women in the detection threshold for pyridine, indicating that general olfactory ability did not differ between them. The detection threshold for 3alpha-androstenol of synchronized women was significantly lower than that of non-synchronized women, but no difference in the threshold for 5alpha-androstenone was found between synchronized and non-synchronized women. These results indicate that the women who showed menstrual synchrony had a higher sensitivity to 3alpha-androstenol but not necessarily to 5alpha-androstenone.     

Investigation of Testosterone,Androstenone, and Estradiol Metabolism in HepG2 Cells and Primary Culture Pig Hepatocytes and Their Effects on 17βHSD7 Gene Expression

Steroid metabolism is important in various species. The accumulation of androgen metabolite, androstenone, in pig adipose tissue is negatively associated with pork flavor, odour and makes the meat unfit for human consumption. The 17β-hydroxysteroid dehydrogenase type 7 (17βHSD7) expressed abundantly in porcine liver, and it was previously suggested to be associated with androstenone levels. Understanding the enzymes and metabolic pathways responsible for androstenone as well as other steroids metabolism is important for improving the meat quality. At the same time, metabolism of steroids is known to be species- and tissue-specific. Therefore it is important to investigate between-species variations in the hepatic steroid metabolism and to elucidate the role of 17βHSD7 in this process. Here we used an effective methodological approach, liquid chromatography coupled with mass spectrometry, to investigate species-specific metabolism of androstenone, testosterone and beta-estradiol in HepG2 cell line, and pig cultured hepatocytes. Species- and concentration-depended effect of steroids on 17βHSD7 gene expression was also investigated. It was demonstrated that the investigated steroids can regulate the 17βHSD7 gene expression in HepG2 and primary cultured porcine hepatocytes in a concentration-dependent and species-dependent pattern. Investigation of steroid metabolites demonstrated that androstenone formed a 3′-hydroxy compound 3β-hydroxy-5α-androst-16-ene. Testosterone was metabolized to 4-androstene-3,17-dione. Estrone was found as the metabolite for β-estradiol. Inhibition study with 17βHSD inhibitor apigenin showed that apigenin didn’t affect androstenone metabolism. Apigenin at high concentration (50 µM) tends to inhibit testosterone metabolism but this inhibition effect was negligible. Beta-estradiol metabolism was notably inhibited with apigenin at high concentration. The study also established that the level of testosterone and β-estradiol metabolites was markedly increased after co-incubation with high concentration of apigenin. This study established that 17βHSD7 is not the key enzyme responsible for androstenone and testosterone metabolism in porcine liver cells.     

Phospholipases modulate immature pig testicular androgen and 16-androstene biosynthetic pathways in vitro.

The role of membrane phospholipids in porcine testicular androgen and 16-androstene biosynthesis was examined by monitoring the effects of phospholipase treatments on the activities of the steroid transforming enzymes. Untreated (control) microsomes from immature pig testes converted pregnenolone to 17-hydroxypregnenolone and DHA to 5,16-androstadien-3 beta-ol (andien-beta) and 4,16-androstadien-3-one (dienone) in the 16-androstene pathway, these metabolites accounting for most (65%) of the pregnenolone converted. The 4-ene steroids in the androgen pathway (progesterone, 17-hydroxyprogesterone, androstenedione and testosterone) totalled less than 10% of the pregnenolone metabolites. No estrogens or 5 alpha-reduced metabolites were detected. Treatment with phospholipase A2 or C, decreased the conversion of pregnenolone to 4-ene-3-oxo steroids but did not decrease the quantities of 5-ene-3 beta-hydroxysteroids. Confirmation of these findings was obtained by measuring the individual enzymatic steps. Phospholipases A2 and C significantly reduced the conversion of DHA to androstenedione and andien-beta to dienone but did not affect 17-hydroxylase or 'andien-beta-synthetase'. However, when the C-17, 20 lyase step was measured alone, phospholipase C decreased the quantity of androstenedione produced indicating that the side-chain cleavage reaction may involve a lipid component. The different effects of phospholipases on these enzymes suggests that pregnenolone metabolism may be regulated by alterations in the membrane microenvironment.     

Microsomal cytochrome P450-dependent steroid metabolism in male sheep liver. Quantitative importance of 6 beta-hydroxylation and evidence for the involvement of a P450 from the IIIA subfamily in the pathway

The metabolism of testosterone (TEST), androstenedione (AD) and progesterone (PROG) was assessed in hepatic microsomal fractions from male sheep. Rates of total hydroxylation of each steroid were lower in sheep liver than in microsomes isolated from untreated male rat, guinea pig or human liver, 6 beta-Hydroxylation was the most important pathway of biotransformation of each of the three steroids (0.80, 0.89 and 0.43 nmol/min/mg protein for TEST, AD and PROG, respectively). Significant minor metabolites from TEST were the 2 beta-, 15 beta- and 15 alpha-alcohols (0.19, 0.22 and 0.17 nmol/min/mg microsomal protein, respectively). Apart from the 6 beta-hydroxysteroid, only the 21-hydroxy derivative was formed from PROG at a significant rate (0.27 nmol/min/mg protein). The 6 beta-alcohol was the only metabolite formed from AD at a rate greater than 0.1 nmol/min/mg protein. Antisera raised in rabbits to several rat hepatic microsomal P450s were assessed for their capacity to modulate sheep microsomal TEST hydroxylation. Anti-P450 IIIA isolated from phenobarbital-induced rat liver effectively inhibited TEST hydroxylation at the 2 beta-, 6 beta-, 15 alpha- and 15 beta-positions (by 31-56% when incubated with microsomes at a ratio of 5 mg IgG/mg protein). IgG raised against rat P450 IIC11 and IIB1 inhibited the formation of some of the minor hydroxysteroid metabolites but did not decrease the rate of TEST 6 beta-hydroxylation. Western immunoblot analysis confirmed the cross-reactivity of anti-rat P450 IIIA with an antigen in sheep hepatic microsomes; anti-IIC11 and anti-IIB1 exhibited only weak immunoreactivity with proteins in these fractions. Considered together, the present findings indicate that, as is the case in many mammalian species, 6 beta-hydroxylation is the principal steroid biotransformation pathway of male sheep liver. Evidence from immunoinhibition and Western immunoblot experiments strongly implicate the involvement of a P450 from the IIIA subfamily in ovine steroid 6 beta-hydroxylation.     

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.     

Alternate hydroxylating activities in newborn rat adrenal cells in primary culture

During the course of a study to produce reference compounds, the metabolism of tetrahydrogenated derivatives (ring A reduced) of progesterone, 6 alpha-hydroxyprogesterone, 11-deoxycorticosterone and corticosterone in newborn rat adrenal cells in primary culture was studied. Analysis of the metabolites was made by gas chromatography-mass spectrometry. Most products resulted from the enzymatic reactions of 11 beta-, 18- and 21-hydroxylation, reduction of the 20-oxo group and oxidoreduction of the 3-hydroxyl group. However, unexpected metabolites were produced from the incubation of 3 beta, 5 alpha-tetrahydroprogesterone and 6 alpha-hydroxy-3 alpha, 5 beta-tetrahydroprogesterone. They resulted from the 16 alpha-hydroxylation of the precursors and probably from the 15 alpha-, 16 beta- and 17 alpha-hydroxylation of 6 alpha-hydroxy-3 alpha, 5 beta-tetrahydroprogesterone. These hydroxylating activities are weak and were not detected from the endogenous steroidogenesis. They were not detected either from the incubation of exogenous steroids with a 3-oxo-4-ene structure or from steroids with a 21-hydroxyl substituent. They result only from substrates showing diminished or no affinity towards the 11 beta/18- and 21-steroid hydroxylase systems. These unusual hydroxylations could be catalyzed by monooxygenase systems in the endoplasmic reticulum similar to those present in the liver or by the monooxygenase systems specific to steroidogenesis. In particular, the reaction specificity of cytochrome P-450(11) beta could be altered by the presence of a 6 alpha-hydroxyl group in a tetrahydrogenated steroid.     

Metabolism of leukotriene B4 in isolated rat hepatocytes. Involvement of 2,4-dienoyl-coenzyme A reductase in leukotriene B4 metabolism

Radiolabeled leukotriene (LT) B4 was incubated with isolated rat hepatocytes in order to assess the metabolism of this chemotactic leukotriene by the liver. At least eight radioactive metabolites were observed, three of which were previously identified as 20-hydroxy-, 20-carboxy-, and 18-carboxy-19,20-dinor-LTB4. A less lipophilic major metabolite (designated HIV) was purified by two reverse phase high performance liquid chromatography separations and was found to exhibit maximal UV absorbance at 269 nm with shoulders at 260 and 280 indicating the presence of a conjugated triene chromophore. Negative ion electron capture gas chromatography/mass spectrometry analysis of the pentafluorobenzyl ester, trimethylsilyl ether derivative of HIV, and positive ion electron ionization mass spectra of the methyl ester trimethylsilyl derivative were consistent with a structure of this metabolite being 16-carboxy-14,15-dihydro-17,18,19,20-tetranor-LTB3. The appearance of this metabolite supports the concept of further beta-oxidation of LTB4 to the carbon 16 which requires the action of 2,4-dienoyl-CoA reductase to remove the 14,15-double bond located two carbon atoms removed from the CoA thioester moiety. One minor metabolite was analyzed by negative ion continuous flow fast atom bombardment mass spectrometry which revealed an ion at m/z 444 which by high resolution mass spectrometry was shown to contain both nitrogen and sulfur. Tandem mass spectrometry suggested the presence of SO3- as well as other fragments corresponding to the amino acid taurine. Incubation of isolated rat hepatocytes with [14C]taurine as well as [3H]LTB4 revealed the incorporation of both radioactive isotopes into this metabolite. The data supported the identification of this metabolite as tauro-18-carboxy-19,20-dinor-LTB4. Amino acid conjugation of leukotrienes has not been previously reported and suggests that such intermediates might participate in enterohepatic circulation of LTB4 metabolites in the intact animal and thus serve as an alternative metabolic route for LTB4 elimination.     

Glutathione conjugates of 4-hydroxy-2(E)-nonenal as biomarkers of hepatic oxidative stress-induced lipid peroxidation in rats

Here we present a simple, specific, and sensitive liquid chromatography/mass spectrometry method to measure 4-hydroxy-2(E)-nonenal-glutathione (HNE-GSH), the major stable hepatic metabolite of HNE after GSH conjugation, as a marker of oxidative stress in rat liver and hepatocytes. Commonly employed methods for the measurement of lipid peroxidation-derived free aldehydes or modified proteins suffer from the artificial formation of HNE or HNE adducts to cellular molecules during sample preparation and derivatization, resulting in an overestimation of background levels. Basal levels of HNE-GSH in liver tissue from untreated rats were detected in amounts of 20 pmol/g liver. Rats exposed to a single dose of iron nitrilotriacetate (Fe(III)NTA; 15 mg Fe/kg bw, ip), a model compound for the induction of oxidative stress, revealed a fivefold increase in the hepatic HNE-GSH levels compared to controls 5 h after dosing. Moreover, a significant increase in HNE-mercapturic acid (HNE-MA) and its reduced metabolite DHN-MA was evident at 5 or 24 h after treatment, which was also reflected in increased plasma concentrations of these secondary HNE-GSH metabolites. In agreement with the in vivo data, a time-dependent increase in the levels of HNE-GSH from <1 to 123 +/- 16 pmol/10(6) cells over 5 h was detected in rat hepatocytes treated with Fe(III)NTA (150 microM). An increase in cellular HNE-GSH from <1.0 to 7.2 +/- 0.3 pmol/10(6) cells could be observed in rat hepatocytes treated with allyl alcohol (500 microM, 3 h), known for generation of HNE in hepatocytes. These data suggest that the direct measurement of the stable GSH conjugation product of cellular HNE in rat primary hepatocytes or its secondary metabolites may represent a reliable biomarker of oxidative stress-induced lipid peroxidation in rat liver in vivo.     

Gas chromatographic-mass spectrometric study of metabolites of C21 and C19 steroids in neonatal porcine testicular microsomes.

Microsomal fractions obtained from testes of 3-week-old piglets have been incubated, separately, with progesterone, 17-hydroxyprogesterone, 5-pregnene-3 beta,20 beta-diol, 16 alpha-hydroxypregnenolone, 5-androstene-3 beta,17 alpha-diol and dehydro-epiandrosterone. The metabolites, after derivatization, have been separated by capillary gas chromatography and identified by mass spectrometry. Quantification was by selected ion monitoring. Progesterone was shown to be 17-hydroxylated and also converted into 4,16-androstadien-3-one (androstadienone). The major metabolite of 17-hydroxyprogesterone was 4-androstene-3,17-dione (4-androstenedione), but little, if any, androstadienone was formed, indicating that this particular biosynthesis did not require 17-hydroxylation. The metabolites of 5-pregnene-3 beta, 20 beta-diol were found to be 17-hydroxypregnenolone, 3 beta-hydroxy-5,16-pregnadien-20-one (16-dehydropregnenolone) and 5,16-androstadien-3 beta-ol. Dehydroepiandrosterone and 5-androstene-3 beta,17 alpha-diol were interconvertible but neither steroid acted as a substrate for 16-androstene formation. However, dehydroepiandrosterone was metabolized to a small quantity of 4-androstenedione. Under the conditions used, no metabolites of 16 alpha-hydroxypregnenolone could be detected. The present results, together with those obtained earlier, indicate that the neonatal porcine testis has the capacity to synthesize weak androgens, mainly by the 4-en-3-oxo steroid pathway. Although 16-androstenes cannot be formed from C19 steroids, progesterone served as a substrate and may be converted directly to androstadienone, without being 17-hydroxylated first. The pathway to 5,16-androstadien-3 beta-ol, however, involves 17-hydroxypregnenolone and 16-dehydropregnenolone as intermediates.     

Studies on rat liver microsomal steroid metabolism using 18O-labelled testosterone and progesterone

In order to investigate the possible involvement of oxygen functions in the rat liver microsomal metabolism of progesterone and testosterone these steroids were specifically labelled with 18O in their oxo-functions and incubated with NADPH supplemented 105,000 g sediments. Gas chromatography-mass spectrometry was used to identify the metabolites formed as well as to quantitate the losses of 18O-label. With 18O-labelled testosterone as substrate two of the major monohydroxylated metabolites, i.e. 2 beta- and 6 beta-hydroxytestosterone were shown to have lost about 25 and 50% of their 18O respectively. A complete retention of label was found in 7 alpha- and 16 alpha-hydroxytestosterone. None of the monohydroxylated progesterone metabolites, i.e. the 2 alpha-, 6 beta- and 16 alpha-hydroxyprogesterone had lost any 18O following incubation with 3,20-18O-labelled progesterone. Control incubation (30', 37 degrees C) with buffer and 18O-labelled progesterone and testosterone revealed no exchange of 18O. Thus the partial loss of 3-18O-label during 2 beta- and 6 beta-hydroxylation of testosterone may indicate a covalent interaction between the steroid 3-oxo-group and one or more cytochrome P-450 species in the rat liver microsomes. In view of the potentiating effect of a 3-imine group in spontaneous 6 beta-hydroxylation the present in vitro data suggest that a steroid protein-interaction may occur via a 3-imine group during 6 beta-hydroxylation of testosterone in rat liver microsomes. Analysis of 5 alpha-reduced metabolites of both progesterone and testosterone showed significant losses of 3-18O, but due to the ease with which 3-oxo-5 alpha-steroids exchange their 3-18O with aqueous media an enzymatically induced loss of 3-18O could not be safely established. The 20-oxido-reductase which converted progesterone did not induce a loss of 20- or 3-18O thus indicating that the oxofunctions were not covalently engaged in the enzymatic binding of the steroid.     

Detection of stanozolol and its metabolites in equine urine by liquid chromatography-electrospray ionization ion trap mass spectrometry

The equine phase I and phase II metabolism of the synthetic anabolic steroid stanozolol was investigated following its administration by intramuscular injection to a thoroughbred gelding. The major phase I biotransformations were hydroxylation at C16 and one other site, while phase II metabolism in the form of sulfate and beta-glucuronide conjugation was extensive. An analytical procedure was developed for the detection of stanozolol and its metabolites in equine urine using solid phase extraction, acid solvolysis of phase II conjugates and analysis by positive ion electrospray ionization ion trap LC-MS.     

Cytoplasmic receptor protein for etiochalanolone in chick embryo liver.

Acute intermittent porphyria is a gentic disease associated with changes in the activity of some of the hepatic enzymes in the heme biosynthetic pathway and in the activity of delta4-5alpha-steroid reductase, an enzyme involved in steroid metabolism. Embryonic chick liver has been used as a model system to study the effects of several naturally occurring 5beta steroid metabolites on delta-aminolevulinic acid synthetase, the rate-limiting enzyme in the heme pathway (Granick, S., and Kappas, A. (1967) J. Biol. Chem. 242, 4587-4593). In this study we have identified in vitro a hepatic cytoplasmic receptor which binds [3H]-etiocholanolone (a 5beta-H androgen metabolite). The steroid-receptor complex has an apparent Kd value of 3.5 times 10(-6) M at 0-4degrees; the number of binding sites per cell is 23,000. The macromolecular complex sediments at approximately 4 S in a 5 to 20% sucrose gradient and is unaffected by KCl concentrations up to 0.4 M. The steroid-receptor complex can be destroyed by heat (60degrees) or proteolytic digestion and is inhibited by sulfhydryl-blocking agents. Competition studies revealed that among the nonradioactive steroids tested, all of the primary androgens and the progestins as well as their 5alpha and 5beta metabolites block the binding of [3H]etiochalanolone. Only the glucuronide derivative of etiocholanolone, glucocorticoids and their metabolites, 17beta-estradiol, and cyproterone compete poorly for the receptor. The steroid receptor described here appears to be different from the androgen receptor isolated from rat liver and prostate.     

Testosterone metabolism by cytochrome P-450 isozymes RLM3 and RLM5 and by microsomes. Metabolite identification

Testosterone metabolism by cytochrome P-450 isozymes RLM3 and RLM5 in a reconstituted system and by rat liver microsomes was examined. Eleven metabolites were detected. Two of these, found in spots 2 and 4 of a thin layer plate, were only formed by the rat liver microsomes and may represent reductive metabolites of testosterone. A number of monohydroxy metabolites were conclusively identified by gas chromatography-mass spectrometry. These include the 2-, 6 beta-, 7 alpha-, and 16 alpha-hydroxy isomers. Liver microsomes formed the 2 alpha- and 2 beta-epimers in a 1:2 ratio and both co-chromatographed with a third reduced metabolite in thin layer plate spot 4. In contrast with RLM5 about 90% of the 2-hydroxy isomer was the 2 alpha-epimer. RLM3 did not perform the 2-hydroxylation in detectable amounts. The 6 beta-isomer was a major metabolite of RLM3 and microsomes, but a minor product of metabolism by RLM5. In contrast, the 7 alpha-isomer was a minor metabolite of RLM3, was not formed by RLM5, and was a major microsomal metabolite. Hydroxylation at position 16 alpha was a major activity of RLM5 and the heterogeneous microsomal cytochromes, but with RLM3 it was a minor reaction. One new metabolite was found which appeared to be hydroxylated in the D-ring, had a mass spectrum different from both 16 alpha- and 16 beta-hydroxytestosterone, and was tentatively identified as a 15-hydroxy isomer. In agreement with the literature, androstene-3,17-dione was found to be an oxidative metabolite of testosterone by both microsomes and purified cytochrome P-450. It was a major metabolite of RLM5 but was not produced by RLM3. Studies with 18O2 and H218O conclusively show that oxidation of testosterone at C-17 does not involve transient incorporation of an oxygen atom in this position. A mechanism is suggested whereby cytochrome P-450 acts as a peroxidase in the formation of androstenedione.     

Steroid metabolism by constitutive cytochromes P450

In rat liver endoplasmic reticulum some 16 different cytochromes P450 have been identified as constitutive, sequenced from recombinant DNA, and shown to be distinct gene products. These forms are “multipurpose”, i.e. functional in xenobiotic metabolism as well as endogenous substrate metabolism. In the latter case, these forms metabolize steroids, fatty acids, prostaglandins and even ketone bodies, indicating an involvement in homeostasis. In steroid metabolism, in contrast to “biosynthetic” forms of P450 which generally yield one product, the multipurpose forms exhibit broad, overlapping metabolite profiles, with isomeric and epimeric specificity and different mechanisms of product formation. The nature of the substrate docking region is of much interest and attempts have been made to rationalize the manner in which multiple metabolites are produced from a single substrate. Brain, with a very low level of P450 relative to liver also catalyzes steroid metabolism. The nature of the forms involved are not yet known.     

Inhibition of steroid 5 alpha-reductase and its effects on testosterone hydroxylation by rat liver microsomal cytochrome P-450

It has been shown previously that liver microsomal steroid 5 alpha-reductase activity increases with age in female but not male rats, which coincides with a female-specific, age-dependent decline in the cytochrome P-450-dependent oxidation of testosterone to 1 beta-, 2 alpha-, 2 beta-, 6 alpha-, 6 beta-, 7 alpha-, 15 beta-, 16 alpha-, 16 beta-, and 18-hydroxytestosterone and androstenedione. To determine whether the increase in steroid 5 alpha-reductase activity is responsible for the decrease in testosterone oxidation, we have examined the effects of the steroid 5 alpha-reductase inhibitor, 4-MA (17 beta-N,N-diethylcarbamoyl-4-methyl-4-aza-5 alpha-androstan-3-one), on the pathways of testosterone oxidation catalyzed by rat liver microsomes. We have also determined which hydroxytestosterone metabolites are substrates for steroid 5 alpha-reductase. At concentrations of 0.1 to 10 microM, 4-MA completely inhibited steroid 5 alpha-reductase activity without inhibiting the pathways of testosterone oxidation catalyzed by liver microsomes from rats of different age and sex, and from rats induced with phenobarbital or pregnenolone-16 alpha-carbonitrile. 4-MA (10 microM) had little or no effect on the oxidation of testosterone catalyzed by liver microsomes from mature male rats (which have low steroid 5 alpha-reductase activity). In contrast, the hydroxylated testosterone metabolites formed by liver microsomes from mature female rats (which have high steroid 5 alpha-reductase activity) accumulated to a much greater extent in the presence of 4-MA. Evidence is presented that 4-MA increases the accumulation of hydroxytestosterones by two mechanisms. First, 4-MA inhibited the 5 alpha-reduction of those metabolites (such as 6 beta-hydroxytestosterone) that were found to be excellent substrates for steroid 5 alpha-reductase. In the absence of 4-MA, these metabolites eventually disappeared from incubations containing liver microsomes from mature female rats. Second, 4-MA inhibited the formation of 5 alpha-dihydrotestosterone, which otherwise competed with testosterone for oxidation by cytochrome P-450. This second mechanism explains why 4-MA increased the accumulation of metabolites (such as 7 alpha-hydroxytestosterone) that were found to be poor substrates for steroid 5 alpha-reductase. Despite its marked effect on the accumulation of hydroxylated testosterone metabolites, 4-MA had no effect on their initial rate of formation by liver microsomes from either male or female rats.(ABSTRACT TRUNCATED AT 400 WORDS)     

Metabolism of spirolactones by the rat testis in vitro

Spironolactone (SPIR) has been shown in numerous clinical studies to produce sexual disorders. We studied the metabolism of canrenone (CAN), the main metabolite of SPIR, and of the analogue 6,7-dihydrocanrenone (DHC) by the rat testis in vitro. The metabolites produced during a 4 h incubation period were isolated by HPLC and identified by nmr-, ms-, ir- and uv-spectrometry. SPIR was not metabolised in a detectable amount. CAN was converted to canrenoic acid, several hydroxylated (15 beta-, 16 alpha-, 19-, 2OR- and 21S-OH-CAN) and one reduced metabolite (3 alpha-OH-CAN). When DHC was incubated, an analogous pattern was detected. It is concluded that CAN and DHC serve as substrates for steroid metabolism in the rat testis.