DNA fragmentation, DNA repair and apoptosis induced in primary rat hepatocytes by dienogest, dydrogesterone and 1,4,6-androstatriene-17beta-ol-3-one acetate

Four steroids that share the 17-hydroxy-3-oxopregna-4,6-diene structure - cyproterone acetate, chlormadinone acetate, megestrol acetate, and potassium canrenoate - have been shown previously to behave with different potency as liver-specific genotoxic agents, the response being markedly higher in female than in male rats, but similar in humans of both genders. In this study, performed to better define the relationship between chemical structure and genotoxicity, dydrogesterone (DGT) with double bonds C4=C5 and C6=C7, dienogest (DNG) with double bonds C4=C5 and C9=C10, and 1,4,6-androstatriene-17beta-ol-3-one acetate (ADT) with double bonds C1=C2, C4=C5 and C6=C7, were compared with cyproterone acetate (CPA) for their ability to induce DNA fragmentation and DNA repair synthesis in primary cultures of hepatocytes from three rats of each sex. At subtoxic concentrations, ranging from 10 to 90 microM, all four steroids consistently induced a dose-dependent increase of DNA fragmentation, which in all cases was higher in females than in males; their DNA damaging potency decreased in the order CPA > DNG > ADT > DGT. Under the same experimental conditions, the responses provided by the DNA repair-synthesis assay were positive or inconclusive in hepatocytes from female rats and consistently negative in hepatocytes from male rats. In the induction of apoptotic cells, examined in primary hepatocytes from female rats, CPA was more active than ADT and DGT, and DNG was inactive. Considered as a whole these findings suggest that a liver-specific genotoxic effect more marked in female than in male rats might be a common property of steroids with two or three double bonds.     

Hepoxilin A3 (HxA3) is formed by the rat aorta and is metabolized into HxA3-C, a glutathione conjugate.

In this paper we describe the release of hepoxilin A3 (HxA3) by intact pieces of the rat thoracic aorta and its stimulation by exogenous arachidonic acid but not by the calcium ionophore A23187. Homogenates of the rat aorta metabolize HxA3 via two competing pathways; one involves hepoxilin epoxide hydrolase to form the trihydroxy metabolite, trioxilin A3 (TrXA3), and a second pathway involves conjugation of HxA3 with glutathione via glutathione S-transferase to form a glutathione conjugate, which we refer to as hepoxilin A3-C (HxA3-C), a name based upon the accepted nomenclature for the glutathione conjugate leukotriene C. The formation of HxA3-C was dependent on the presence of reduced glutathione in the incubation medium. HxA3-C formation was greatly enhanced in the presence of TCPO, an epoxide hydrolase inhibitor which blocks utilization of the substrate via hepoxilin epoxide hydrolase. Comparison of HxA3-C formation by several arteries and veins indicated that glutathione conjugation was more evident in veins than arteries. The aorta from spontaneously hypertensive rats was essentially similar in HxA3-C formation to aorta from local normotensive Wistar rats although the aorta from the normotensive Wistar Kyoto rats was much more active than aorta from either of the two other rat types. The biological activity of HxA3 and HxA3-C was investigated on isolated helicoidal strips of the rat aorta. While both compounds were inactive on their own, HxA3 and to a lesser extent HxA3-C potentiated the contractile response induced by norepinephrine. The present results provide evidence of the presence in rat aorta of a new pathway of arachidonic acid metabolism whose products may possess potential regulatory properties on vascular tissue.     

Design and syntheses of putative bioactive taxanes

Reduction of 5 alpha-hydroxy-7 beta,9 alpha,10 beta-triacetoxy-4(20), 11(12)-taxadien-13-one 1 with activated zinc in glacial acetic acid led to rearranged products, including compounds with double bonds at C3-C4, C10-C11 or with an epoxide at C11-C12. Molecular modeling studies suggested that addition of a side chain at C-20 or C-5 of the taxanes with a C3-C4 double bond might lead to bioactivity. Semi-syntheses and results of bioactivities are discussed.     

Metabolism of the 16-androstene steroids in primary cultured porcine hepatocytes

The hepatic metabolism of the 16-androstene steroids was investigated using isolated porcine hepatocytes. This study demonstrated that the liver is capable of producing both phase I and phase II steroid metabolites from 16-androstene steroid precursors. 16-Androstene metabolites were recovered by solid-phase extraction and identified by gas chromatography-mass spectrometry (GC-MS). When 5alpha-androstenone was provided as a substrate, both 3beta- and 3alpha-androstenol were produced as well as a metabolite that showed evidence of hydroxylation. Incubations with the various 16-androstene steroids produced metabolic profiles which suggested that the major role of the liver is phase II conjugation. Sulfoconjugated 16-androstene steroids included androstadienol, 5alpha-androstenone, 3beta-, 3alpha-androstenol, and possibly the hydroxylated metabolite of 5alpha-androstenone. It was determined that hydroxysteroid sulfotransferase (HST) is the likely candidate for the sulfoconjugation of the 16-androstene steroids within the liver. Despite the capacity of the hepatocytes to sulfoconjugate the 16-androstene steroids, the principle metabolites produced from incubations with 5alpha-androstenone, 3beta-, and 3alpha-androstenol were glucuronide conjugates, accounting for approximately 68% of all phase II metabolism. These findings underline the importance of steroid conjugation and suggest that hepatic metabolism of the 16-androstene steroids may influence the levels of 5alpha-androstenone present in the circulation, and thus, capable of accumulating in fat.     

Average structural and motional properties of a diunsaturated acyl chain in a lipid bilayer: effects of two cis-unsaturated double bonds

Isolinoleic acid (18:2 delta 6,9) deuterated at 10 different positions was esterified to form 1-palmitoyl-2-isolinoleoyl-sn-glycero-3-phosphocholine (PiLPC), and the average structural and motional properties of the diunsaturated chain, in aqueous dispersions of PiLPC, were examined by 2H NMR spectroscopy. For each sample, 2H spectra were acquired over a temperature range of 1-40 degrees C and the quadrupolar splittings interpreted in terms of carbon-deuterium bond order parameters, SCD. Furthermore, definition of the average orientation of the C8 methylene unit with respect to the bilayer normal [Baenziger, J. E., Smith, I. C. P., Hill, R. J., & Jarrell, H. C. (1988) J. Am. Chem. Soc. 110, 8229-8231] provided sufficient information to calculate both the average orientations and the molecular order parameters, Smol (which reflects the amplitudes of motion), for the C6-C7 and the C9-C10 double bonds. The results indicate that both the motional freedom (reflected in the order profile) and the average structure (reflected in the orientation of carbon segments with respect to the bilayer normal) are strongly affected by the presence of two cis-unsaturated double bonds. The data were interpreted in terms of two possible models whereby, in each case, the chain adopts a conformation consistent with the low-energy conformation of 1,4-pentadiene [Applegate, K. R., & Glomset, J. A. (1986) J. Lipid Res. 27, 658-680] but undergoes a two-site jump between the conformations. The jump motion arises mainly from rotations about the C7-C8 and the C8-C9 single bonds that disorder the C8 and the C9-C10 segments (Smol = 0.15 and 0.08, respectively) but leave the C6-C7 double bond relatively immobile (Smol = 0.55; all at 40 degrees C). It is suggested that acyl chains containing three or more double bonds could not undergo a similar jump motion and therefore would be highly ordered and not "fluid" as is generally thought.     

A comparative molecular modeling study of dydrogesterone with other progestational agents through theoretical calculations and nuclear magnetic resonance spectroscopy

6-Dehydroretroprogesterone (dydrogesterone) and three other natural or synthetic progestins (progesterone, retroprogesterone, and 6-dehydroprogesterone) were submitted to a conformational study through theoretical calculations at the B3LYP/6-31G(*) level and high field NMR spectroscopy. The study allows to define the role of the two structural features which differentiate these steroids, i.e., the C9 and C10 configuration and the C6-C7 unsaturation. The combined effects of the conformational preference of A ring, determined by the configuration at C9 and C10, and the enhanced rigidity due to the C6-C7 double bond, could account both for the higher activity and selectivity of dydrogesterone with respect to the other three steroids.     

Substrate specificity and inhibitor analyses of human steroid 5β-reductase (AKR1D1)

Human steroid 5β-reductase (aldo-keto reductase 1D1) catalyzes the stereospecific NADPH-dependent reduction of the C4-C5 double bond of Δ⁴-ketosteroids to yield an A/B cis-ring junction. This cis-configuration is crucial for bile acid biosynthesis and plays important roles in steroid metabolism. The biochemical properties of the enzyme have not been thoroughly studied and conflicting data have been reported, partially due to the lack of highly homogeneous protein. In the present study, we systematically determined the substrate specificity of homogeneous human recombinant AKR1D1 using C18, C19, C21, and C27 Δ⁴-ketosteroids and assessed the pH-rate dependence of the enzyme. Our results show that AKR1D1 proficiently reduced all the steroids tested at physiological pH, indicating AKR1D1 is the only enzyme necessary for all the 5β-steroid metabolites present in humans. Substrate inhibition was observed with C18 to C21 steroids provided that the C11 position was unsubstituted. This structure activity relationship can be explained by the existence of a small alternative substrate binding pocket revealed by the AKR1D1 crystal structure. Non-steroidal anti-inflammatory drugs which are potent inhibitors of the related AKR1C enzymes do not inhibit AKR1D1. By contrast chenodeoxycholate and ursodeoxycholate were found to be potent non-competitive inhibitors suggesting that bile-acids may regulate their own synthesis at the level of AKR1D1 inhibition.     

Rat P450(17 alpha) from testis: characterization of a full-length cDNA encoding a unique steroid hydroxylase capable of catalyzing both delta 4- and delta 5-steroid-17,20-lyase reactions

A cDNA clone encoding the complete rat 17 alpha-hydroxylase (P450(17 alpha] from testis has been identified and sequenced. The deduced amino acid sequence is found to have 69% similarity with human P450(17 alpha), 64% similarity with bovine P450(17 alpha), and 47% similarity with chicken P450(17 alpha). The protein contains 507 amino acids being one amino acid shorter than the human P450(17 alpha) as the result of a codon being absent at the position of amino acid 139 in the human sequence. The cDNA hybridizes to a single mRNA (approximately 2.0 kilobases) in rat testis RNA and Southern analysis indicates the presence of a single CYP17 gene in the rat genome. Expression of this cDNA in COS1 cells leads to production of a steroid hydroxylase which is capable of converting both 17 alpha-hydroxypregnenolone and 17 alpha-hydroxyprogesterone into C19 steroids, dehydroepiandrosterone, and androstenedione, respectively. This activity profile is distinct from that of either the human or bovine forms of P450(17 alpha) which are unable to catalyze 17,20-lyase conversion of delta 4-C21 steroids to delta 4-C19 steroids at significant rates.     

Chemospecific deuteration of prostaglandin silyl ethers

Complete chemical selectivity (i.e., chemospecificity) has been achieved in the homogeneous deuteration of C5-C6 and endocyclic C10-C11 prostaglandin double bonds without arrangement or partial reduction of C13-C14- or C8-C12 double bonds. The homogeneous deuteration reaction utilizes protection of the C13-C14 double bond as the C15O-silyl ether and protection of the carboxyl group as the methyl ester prior to reduction under molecular deuterium with tris(triphenylphosphine)chlorohodium (I) (Wilkinson's catalyst) in 60:40 acetone:benzene at 25 degrees C. The reaction has been used to prepare six specifically deuterated prostaglandin: 5,6-dideuterio-PGE1 alpha 5,6-dideuterio-PGE1, 5,6-dideuterio-PGB1, 3,3,4,4,5,6-hexadeuterio-PGF1 alpha, 5,6,10,11-tetradeuterio-11-deoxy-PGE1, and 10, 11-dideuterio-11-deoxy-PGE1.     

Inhibition of glutathione S-transferase in rat hepatocytes by a glycine-tetrazole modified S-alkyl-GSH analogue

Glutathione (GSH) conjugates inhibit enzymes that are involved in drug metabolism and drug resistance, but their cellular uptake is very low. To improve membrane-permeability, we synthesized a novel GSH-conjugate analogue with a tetrazole carboxylate isostere at the glycine position. Introduction of the tetrazole decreases inhibitory potency towards CDNB conjugation by glutathione S-transferase. However, the tetrazole derivative inhibited 2-bromoisovalerylurea conjugation in rat liver cytosol, as well as in hepatocytes.     

Isolation and characterisation of a C(18) neutral steroid, oestra-5(10),7-diene-3,17-diol, from pregnant mare urine and allantoic fluid. Facile oxidation to yield oestra-5(10),6,8-triene-3, 17-diol (diol of Heard's ketone)

Oestradiene-3,17-diol and oestratriene-3,17-diol (or the diol of Heard's ketone (3-hydroxy-5(10),6,8-oestratriene-17-one) have been extracted on a large scale from pooled urines and allantoic fluid obtained from pregnant mares. Initial purification was achieved using column chromatography, and further purification by high performance liquid chromatography or silver nitrate (argentation) thin layer chromatography. The steroids were characterised using gas chromatography-mass spectrometry. Positions of the double bonds in ring B of oestradienediol were deduced on the basis of results of ultraviolet (UV) and nuclear magnetic resonance (NMR) spectroscopy, hydrogenation, and incubation studies with the enzyme 5-ene-3beta-hydroxysteroid dehydrogenase/steroid-4,5-isomerase. The reference steroid, 5,7-cholestadien-3beta-ol (7-dehydrocholesterol), with its conjugated double bond system, behaved entirely differently to oestradienediol, consistent with the latter having no conjugated system. These data, together with detailed results of NMR studies, have led us to designate the positions of the double bonds in oestradienediol as 5(10),7-. The instability of the dienediol became apparent when the steroid was converted to its bis-trimethylsilyl (TMS) ether. The phenomenon was exacerbated when derivatisation was performed at elevated temperatures or when the fraction containing the dienediol was stored at 4 degrees C prior to being derivatised. The facile oxidation product was shown to be 5(10),6, 8-oestratriene-3,17-diol, implying that the two steroids are related and, furthermore, that all the sites of unsaturation are in the B ring. Because of the facile oxidation of oestradienediol to oestratrienediol (the diol of Heard's ketone), we propose, that this, and by implication, Heard's ketone itself, are artefacts of the isolation procedures which were utilised in the original studies. A possible mechanism is proposed for the biosynthesis of 5, 7-oestradienediol from a ring-B unsaturated C(19) compound, involving C(19) demethylation without aromatisation.     

1-bromoalkanes as new potent nontoxic glutathione depletors in isolated rat hepatocytes

The effect of 1-bromlalkanes on intracellular glutathione (GSH) was studied in freshly isolated rat hepatocytes. Treatment of cells with bromoalkanes depleted cellular GSH levels without causing cytotoxicity. The extent of GSH depletion was directly proportional to the concentration and increasing chain length of 1-bromoalkanes (C2-C7). Bromoheptane (100 microM) depleted GSH by 87% in 30 mins which remained depleted for the 4 hr study period without causing cytotoxicity. A 30 fold higher concentration of bromoheptane was required before cytotoxicity ensued. Bromoheptane would therefore be particularly useful for studying the role of GSH in modulating xenobiotic cytotoxicity.     

Biotransformation XXXIX. Metabolism of testosterone, androstenedione, progesterone and testosterone derivatives in Absidia coerulea culture

The strain of Absidia coerulea was used to investigate the transformations of testosterone, androstenedione, progesterone and testosterone derivatives with additional C1–C2 double bond and/or 17-methyl group. All the examined substrates were transformed, mainly hydroxylated. It was found that the position and stereochemistry of the introduced hydroxyl group, as well as the yield of products, depended on the structure of the substrate. The first three substrates (hormones) underwent hydroxylation at C-14, and additional hydroxylation at 7 was observed in progesterone. The presence of the double bond (C1–C2) in 1-dehydrotestosterone did not influence the position of hydroxylation, but the product with additional C14–C15 double bond (at the same site as hydroxylation) was formed. 17-Methyltestosterone was hydroxylated at the 7 position, and also the dehydrogenated product (at the same site, with C6–C7 double bond) was obtained. The testosterone derivative with both C1–C2 double bond and 17-methyl group underwent hydroxylation at the 7 or 11β position, and a little amount of 14, 15 epoxide was formed.     

Glycogenolysis is directed towards ascorbate synthesis by glutathione conjugation

Using isolated rat hepatocytes we have shown that glutathione (GSH) depletion by glutathione-S-transferase (GST)-catalyzed conjugation with 1-bromoheptane or phorone was accompanied by a significant elevation in ascorbate synthesis. Glycogenolysis was also stimulated without a significant rise in glucose synthesis. Furthermore, when glycogenolysis was stimulated in control hepatocytes by increasing intracellular cAMP levels (with glucagon or dibutyryl cAMP), cellular glucose levels, but not ascorbate levels, increased. These data suggest that GSH depletion can stimulate ascorbate synthesis independently of glucose synthesis and that hepatocytes can direct glycogenolysis towards ascorbate synthesis during GSH conjugation.     

Precise quantitation of 5alpha-reductase type 1 mRNA by RT-PCR in rat liver and its positive regulation by testosterone and dihydrotestosterone

The liver is a multifunctional organ responsible for steroid hormones catabolism. Thus, the enzymes responsible for steroid catabolism are located in the liver, including the steroid 5alpha-Reductase (5alpha-R) (EC 1.3.99.5) which catalyzes the conversion of compounds with Delta(4,5) double bonds such as testosterone (T) into their respective reduced derivatives such as dihydrotestosterone (DHT), which are more hydrosoluble, therefore facilitating their excretion. We present precise measurements of mRNA levels of steroid 5alpha-Reductase type 1 isozyme (5alpha-R1) in the liver of male rats with different androgen status, using a quantitative RT-PCR coupled to laser-induced fluorescence capillary electrophoresis (LIF-CE). By means of this technique, we demonstrate a high level of expression of the gene that encodes 5alpha-R1 isozyme in male rat liver, and both T and DHT exert a positive control on the genetic expression of liver 5alpha-R1 isozyme. Since DHT does not contain a Delta(4,5) double bond, our results raise the possibility that hepatic 5alpha-R type 1 not only participates in the catabolism of steroids with Delta(4,5) double bonds, but also in other physiological functions, perhaps in the masculinization of the external genitalia in males with 5alpha-R type 2 gene deficiency.     

Structure-activity relationships for glucocorticoids—III. Structural and conformational study of the rings and side-chain of steroids which bind to the glucocorticoid receptor

The structure of fifteen steroids which bind to the glucocorticoid receptor has been determined by complete geometry optimisation. This method calculates the spatial atomic coordinates for each molecule in the conformation with the minimum internal constraint (lowest-energy state). In addition, the relative energy changes associated with a complete rotation of the side-chain have been calculated for nine of these steroids.The molecules in this series differ by their substituents at C11, C16, C17 and C21, and by a C1-C2 double bond. First we find that, except for the deformable A-ring and side-chain, the optimized structures are in good agreement with the available crystallographic ones.As to the structural influence of substituents, it is of course most evident in their immediate vicinity. More subtle effects which, however, become apparent when one considers the overall shape of the steroid, are discussed in the accompanying paper. In all optimized molecules except prednisolone (Δ1-cortisol). the A-ring is a 1α, 2β-half-chair. The different conformations seen by crystallography are consistent with the distortability of this ring. The rigid B- and C-rings all have similar chair conformations. The D-rings range from a 13β-envelope to a 13β, 14α-half-chair, depending on the substitution. Concerning the side-chain, all optimized molecules exhibit a C13-C17-C20-O20 torsion angle between 70° and 120°. The 17-H-substituted steroids have a mean angle of 79°. This value increases to 101° in the presence of a 17-hydroxyl group.Finally, the energetical curves corresponding to the complete rotation about the C17-C20 bond imposed to the side-chain are all different for the steroids studied. In each molecule, the range of energy changes is relatively small indicating the ability of the molecules to minimize the introduced perturbation. The hypothesis is formulated that receptor binding involves a specific conformation of the side-chain, different from the lowest energy state.     

Predicting the effect of steroids on membrane biophysical properties based on the molecular structure

The relationship between sterol structure and the resulting effects on membrane physical properties is still unclear, owing to the conflicting results found in the current literature. This study presents a multivariate analysis describing the physical properties of 83 steroid membranes. This first structure-activity analysis supports the generally accepted physical effects of sterols in lipid bilayers. The sterol chemical substituents and the sterol/phospholipid membrane physical properties were encoded by defining binary variables for the presence/absence of those chemical substituents in the polycyclic ring system and physical parameters obtained from phospholipid mixtures containing those sterols. Utilizing Principal Coordinates Analysis, the steroid population was grouped into five well-defined clusters according to their chemical structures. An examination of the membrane activity of each sterol structural cluster revealed that a hydroxyl group at C3 and an 8-10 carbon isoalkyl side-chain at C17 are mainly present in membrane active sterols having rigidifying, molecular ordering/condensing effects and/or a raft promoting ability. In contrast, sterol chemical structures containing a keto group at C3, a C4-C5-double bond, and polar groups or a short alkyl side-chain at C17 (3 to 7 atoms) are mostly found in sterols having opposite effects. Using combined multivariate approaches, it was concluded that the most important structural determinants influencing the physical properties of sterol-containing mixtures were the presence of an 8-10 carbon C17 isoalkyl side-chain, followed by a hydroxyl group at C3 and a C5-C6 double bond. Finally, a simple Logistic Regression model predicting the dependence of membrane activity on sterol chemical structure is proposed.     

Phenyl-terminated fatty acids in seeds of various aroids

A series of homologous omega-phenylalkanoic acids and omega-phenylalkenoic acids were isolated from seed lipids of various genera of the subfamily Aroideae of Araceae (the Jack-in-the-Pulpit family) and characterized. Besides the major acids, 11-phenylundecanoic acid, 13-phenyltridecanoic acid and 15-phenylpentadecanoic acid, all other homologous odd carbon number omega-phenylalkanoic acids from C7 to C23 were detected in trace amounts. Additionally, one even carbon number acid, 12-phenyldodecanoic acid was found in several specimens in trace amounts. Similarly, two series of homologous odd carbon number monounsaturated omega-phenylalkenoic acids were found and characterized using dimethyl disulfide derivatization to locate the positions of their double bonds. In five acids from C11 to C19, the double bond is located at the same distance, A7, from the phenyl ring. In the other two acids of C13 and C15 chain length, the double bond is located at delta5 from the phenyl ring.     

A blue corrinoid from partial degradation of vitamin B12 in aqueous bicarbonate: spectra, structure, and interaction with proteins of B12 transport

Cobalamin (Cbl) is a complex cofactor produced only by bacteria but used by all animals and humans. Cyanocobalamin (vitamin B(12), CNCbl) is one commonly isolated form of cobalamin. B(12) belongs to a large group of corrinoids, which are characterized by a distinct red color conferred by the system of conjugated double bonds of the corrin ring retaining a Co(III) ion. A unique blue Cbl derivative was produced by hydrolysis of CNCbl in a weakly alkaline aqueous solution of bicarbonate. This corrinoid was purified and isolated as dark blue crystals. Its spectroscopic analysis and X-ray crystallography revealed B-ring opening with formation of 7,8-seco-cyanocobalamin (7,8-sCNCbl). The unprecedented structural change was caused by cleavage of the peripheral C-C bond between saturated carbons 7 and 8 of the corrin macrocycle accompanied by formation of a C═C bond at C7 and a carbonyl group at C8. Additionally, the C-amide was hydrolyzed to a carboxylic acid. The extended conjugation of the π-system caused a considerable red shift of the absorbance spectrum. Formation and degradation of 7,8-sCNCbl were analyzed qualitatively. Its interaction with the proteins of mammalian Cbl transport revealed both a slow binding kinetics and a low overall affinity. The binding data were compared to those of other monocarboxylic derivatives and agreed with the earlier proposed scheme for two-step ligand recognition. The obtained results are consistent with the structural models of 7,8-sCNCbl and the transport proteins intrinsic factor and transcobalamin. Potential applications of the novel derivative for drug conjugation are discussed.     

Stereoselective glutathione conjugation of a uricosuric diuretic

A reduction of cellular glutathione (GSH) content was observed when isolated rat hepatocytes were incubated with a stereoisomer of a uricosuric diuretic (S-8666) at a high concentration. Subsequent studies have revealed it was due to conjugation of GSH and S-8666 (-)-enantiomer in the liver cytosol. The (+)-enantiomer strongly inhibited the conjugation reaction, therefore, GSH depletion did not take place when a racemic form of S-8666 was incubated with the liver cells. A possible chemical structure of the GSH-conjugate is tentatively proposed.