In vitro metabolism of the pro-carcinogen aflatoxin B1 by liver preparations of the calf, nurse shark and clearnose skate

1. Liver postmitochondrial supernatant preparations of calf, clearnose skate, and nurse shark were able to metabolize the fungal toxin aflatoxin B1 to various metabolites. 2. Calf liver produced aflatoxin M1 and Q1 as the major chloroform soluble metabolites, with small amounts of aflatoxicol formed during incubation. 3. Liver preparations of the elasmobranchs, however, produced aflatoxicol as the major chloroform soluble metabolite with no other metabolite being detected. 4. The water soluble metabolite profiles for the three species were also quite different with the tris diol adduct being produced to a much greater extent in calf liver preparations. 5. Aflatoxicol production by the elasmobranch liver homogenates was reversible with the skate reconverting a large amount (30%) of aflatoxicol to AFB1. The nurse shark, however, appeared to convert a portion of aflatoxicol to an unknown metabolite more polar than AFB1. 6. Calf liver DNA bound approximately 3 x more 3H-AFB1 than shark liver DNA.     

Biotransformation of pregnenolone - 7alpha-3H, progesterone - 7alpha-3H and dehydroepiandrosterone - 7alpha-3H by porcine fetal and maternal adrenal homogenate preparations.

The biotransformation of pregnenolone-7alpha-3H and of progesterone-7alpha-3H by porcine fetal and maternal adrenal homogenates at 56 and 112 days of pregnancy and of dehydroepiandrosterone-7alpha-3H by fetal adrenal homogenates has been investigated in vitro. Both pregnenolone-7alpha-3H and progesterone-7alpha-3H were metabolized extensively by maternal adrenal preparations, the principal radioactive metabolites isolated being cortisol, corticosterone, 11-deoxycortisol, deoxycorticosterone, 11beta-hydroxyprogesterone and androstenedione. In addition, 17alpha-hydroxyprogesterone, 20alpha-dihydroprogesterone and cortisone were formed from both substrates and 17alpha-hydroxypregnenolone and progesterone were formed from pregnenolone. Although essentially the same radioactive metabolites were isolated after incubation of fetal adrenal glands with pregnenolone-7alpha-3H or progesterone-7alpha-3H, a greater proportion of the radioactivity was associated with corticosteroids at 112 days of pregnancy than at 56 days. 11beta-Hydroxyandrostenedione and androstenedione were isolated and identified together with an unknown polar metabolite, after incubation of fetal adrenal tissue with dehydroepiandrosterone-7alpha-3H. These results are discussed in relation to feto-placental steroid biosynthesis and metabolism and the role of the fetal adrenal in the initiation of parturition in the pig.     

Isolation and characterization of active metabolites of tryptophan-pyrolysate mutagen,TRP-P-2, formed by rat liver microsomes

The mutagenic compound derived from the pyrolysis of tryptophan, 3-amino-1-methyl-5H-pyrido-[4,3b]indole (Trp-P-2) was metabolized by rat liver microsomes to more than four metabolites, separable by high performance liquid chromatography. Among these metabolites, two metabolites, M-3 and M-4 were directly active in increasing the frequency of mutation in Salmonella typhimurium TA98. Treatments of rats with polychlorinated biphenyl (PCB) or 3-methylcholanthrene dramatically induced the activity of liver microsomes to form these active metabolites, while treatment with phenobarbital was without effect. A major active metabolite (M-3) formed the pentacyano-ammine ferroate, which is known to be formed by reaction of sodium pentacyano-ammine ferroate with some hydroxylamines. Further this metabolite was oxidized to the minor active metabolite (M-4) with potassium ferricyanide or γ-manganese dioxide, and was reduced back to Trp-P-2 with titanium trichloride. These results indicated that the major active metabolite of Trp-P-2, which is formed by cytochrome P-450, is the 3-hydroxyamino derivative.     

The metabolism of progesterone by animal tissues in vitro. Sex and species differences in conjugate formation during the metabolism of [4-14C]progesterone by liver homogenates

1. Sex and species differences during the metabolism of [4-¹⁴C]progesterone by liver homogenates from rat, rabbit, guinea pig and hamster have been investigated. 2. Liver homogenate from male rat formed `water-soluble' metabolites faster and in significantly larger amounts than did liver homogenate from female rat. About 65–70% of the added progesterone was conjugated as glucuronide by liver homogenate from male rat and about 45–50% by that from female rat. Liver homogenate from male rat also formed glucuronides faster than did liver homogenate from female rat. Sulphate formation was low (8–16%) in liver homogenates from both male and female rats. 3. Hamster-liver homogenate did not show any sex difference in the rate of formation of `water-soluble' metabolites, but a sex difference was observed in the amount of free steroids recovered at low tissue:steroid ratios. Liver homogenate from female hamster formed glucuronides faster and in significantly larger amounts than did liver homogenate from male hamster, the reverse of what was found in rat liver. 4. Liver homogenates from male and female rabbits and guinea pigs formed `water-soluble' metabolites that were almost entirely glucuronides. 5. Neither rabbit liver nor guinea-pig liver showed any significant sex difference in the rate or amount of formation of total `water-soluble' metabolites or glucuronides, but guinea-pig liver was considerably less active than rabbit liver. 6. Glucuronides were quantitatively the major type of conjugate formed by the liver homogenates from both sexes of all species except the male hamster.     

Degradation of juvenile hormone and methylation of juvenile hormone acid by corpora cardiaca–corpora allata of the cockroach,Nauphoeta cinerea: I. Biochemical aspects

Corpora cardiaca-corpora allata (CC-CA) from vitellogenic females of Nauphoeta cinerea degraded, in vitro, racemic and (10R)-juvenile hormone III (JH III) at a rate of 249 pmol/CC-CA/h and 786 pmol/CC-CA/h, respectively. The major metabolite formed was JH III acid, together with some highly polar products. CC-CA homogenates degraded racemic JH III to a small extent, whereas (10R)-JH III was degraded efficiently to JH III acid. No highly polar products were formed by CC-CA homogenates. When CC-CA were incubated with racemic JH III acid, some of this substance was degraded to highly polar products, and a minor part was methylated to JH III. CC degraded very little JH III acid and did not methylate it to JH III. CC-CA homogenates methylated JH III acid very efficiently; we measured an apparent K_max of 37.8 μM and a V_max of 1,260 pmol/4 h/ CC-CA equivalent. The addition of JH III acid to CC-CA in vitro increased the rate of biosynthesis of JH III, as determined by measuring incorporation of methyl[¹⁴C]methionine into JH III. These data indicate that the metabolite JH III acid can enter the CA and be methylated to JH III.     

Comparative metabolism of the Cecropia juvenile hormone

The in vivo and in vitro metabolism of ³H-Cecropia C18-juvenile hormone (JH) was studied in representative species of eight orders of insects. In all orders the major metabolites were found to be the JH-acid, the JH acid-diol, and conjugated polar metabolites thought to be glucosides or glucuronides. The JH-diol was also present in both Tenebrio and Saturniid pupae. In vitro studies revealed two additional metabolites produced by tissue homogenates in the presence of NADPH. On the basis of chromatographic evidence these are tentatively identified as the JH-tetrol metabolite in Cecropia, Thermobia, and Drosophila, and the JH-bisepoxide in Drosophila.     

Metabolism of megestrol acetate by rat adrenal glands in vitro

Megestrol acetate is metabolized by homogenates of rat adrenal glands to three more polar metabolites Y(2), Y(3) and Y(4). Their structures were investigated by microchemical reactions, paper chromatography, and ultraviolet and infrared spectroscopy. Metabolite Y(3) was identified as 17alpha-acetoxy-11beta-hydroxy-6-methyl-pregna-4,6-diene-3,20-dione, its oxidation product being identical with authentic 17alpha-acetoxy-6-methylpregna-4,6-diene-3,11,20-trione. It is suggested that metabolite Y(2) is 17,18-dihydroxy-6-methylpregna-4,6-diene-3,20-dione and that it also exists in the form of an alpha-ketol formed between the 18-hydroxyl and 20-oxo groups. Metabolite Y(4) is probably a tautomeric form of metabolite Y(2) as they were partially interconverted on chromatography and also have similar properties.     

Conversion of spironolactone to an active metabolite in target tissues: formation of 7α-thiospironolactone by microsomal preparations from guinea pig liver,adrenals, kidneys,and testes

Previous studies had established that much of the biological activity of the mineralocorticoid antagonist, spironolactone, depended upon its metabolism, but little was known about the nature of spironolactone metabolites in tissues. A method employing high pressure liquid chromatography has been developed for the separation and mfeasurement of several potential metabolites of spironolactone. Incubation of spironolactone with guinea pig hepatic, adrenal, renal, or testicular microsomal preparations resulted in the production of 7α-thiospironolactone (SC-24813), a compound which is a potent mineralocorticoid antagonist and which promotes the destruction of adrenal and testicular cytochromes P-450. Identification of 7α-thiospironolactone as the tissue metabolite was confirmed by mass spectrometry. The relative rates of production of 7α-thiospironolactone by the microsomal preparations were liver > kidney > adrenal > testis. Spectral data suggest that the effects of spironolactone on adrenal cytochromes P-450 may depend, at least in part, upon its conversion to 7α-thiospironolactone. The results establish that 7α-thiospironolactone is a tissue metabolite of spironolactone and may contribute to the therapeutic actions as well as some of the side effects of the parent drug.     

Diaryl dimers of estradiol and of estrone may be formed as major metabolites by mouse mammary glands

The formation of a novel estrogen metabolite by mammary tissues was investigated. Polar and nonpolar metabolites of endogenous estrogens are formed in liver and other tissues. Polar products such as the catechol estrogens are implicated in tumorigenesis in breast tissue, whereas a nonpolar metabolite, 2-methoxyestradiol, may be protective. Diaryl ether dimers, as a novel form, have been reported as nonpolar products from liver microsomes. We have noted major amounts of nonpolar metabolites in other tissues that were neither 2-methoxyestrogens nor estrogen fatty acid esters. The possible formation of such novel metabolites by breast tissues from adult nulliparous mice with [³H]-labeled estrogens as substrates was considered. Steroids were recovered from media by solid-phase extraction and profiles were obtained from HPLC (acetonitrile:water). Saponification was done with an internal standard of estradiol stearate. Major amounts of nonpolar metabolites were formed in all instances, with one or two principal peaks. Alkaline hydrolysis had no effect on the nonpolar product(s) but released estradiol from its stearate. Strong acid treatment also had no effect as shown by HPLC. Thus, it is suggested that diaryl dimers of estrogens may be formed as major metabolites by mouse mammary glands.     

Metabolism of auxin in pine tissues: Indole-3-acetic acid conjugation

Incubation of sections of various tissues of Pinus pinea L. with a relatively low concentration (3.6 μM) of indole-3-acetic acid-2-¹⁴C (IAA) resulted in the formation of two major metabolites. The first, which has not been identified, seemed to be a polar acidic compound and the second was identified as indole-3-acetylaspartic acid (IAAsp). The polar acidic metabolite has been found to be the major metabolite in needles, shoot wood and roots, while IAAsp has been found to be the major metabolite in shoot bark. Increasing the concentration of IAA in the incubation medium resulted in an increase in the formation of a third metabolite which proved to be l-O-(indole-3-acetyl)-β-d -glucose (IAGlu) and a concomitant decrease in the amount of the polar acidic metabolite. This phenomenon was prominent particularly in needles. IAGlu was isolated from needles and IAAsp was isolated from shoot bark by means of polyvinylpolypyrrolidone column chromatography and preparative thin-layer chromatography. IAGlu was identified by comparison with authentic material by co-chromatography in three different solvent systems and by ¹H-nuclear magnetic resonance analysis. IAAsp was identified by comparison with authentic material by gas-liquid chromatography and ¹H-nuclear magnetic resonance analysis. Several aspects of formation, separation and isolation of IAA metabolites are discussed.     

In vitro formation of organ specific proximate carcinogen of benzo(a)pyrene by rat homogenates

In order to determine the organ specific carcinogenicity of benzo(a)pyrene (B(a)P), its metabolites, formed in vitro by incubation with the homogenates from liver, lungs, kidneys, intestine and brain of rats, were isolated by TLC and spectroscopy. B(a)P was found to be converted into a number of metabolites by different tissue homogenates. The results showed that the proximate carcinogenic metabolite, 7,8-dihydro-7,8-dihydroxy B(a)P was formed only when rat lung and kidney homogenates were incubated with B(a)P in vitro. The UV spectral analysis also confirmed the formation of this metabolite only on incubation of B(a)P with rat lung and kidney homogenates. As the proximate carcinogenic metabolite was only formed by incubating B(a)P with the homogenates from target organs, its organ specific carcinogenicity may be explained.     

Identification of Monohydroxy metabolites of 15,16-dihydrocyclopenta(a)phenanthren-17-one and its carcinogenic 11-methyl homolog produced by rat liver preparations in vitro.

Incubation of 15,16-dihydrocyclopenta[a]phenanthren-17-one and its carcinogenic 11-methyl homolog with rat liver microsomes led to similar patterns of metabolites. The carcinogen was the more slowly metabolized, but both ketones gave the corresponding 15-hydroxy derivatives, together with small quantities of the isomeric 16-ols. The 11-hydroxymethyl-17-ketone also occurred as a minor carcinogen metabolite. Incubation of the carcinogen with rat liver homogenates caused more extensive metabolism. The ratio of mono-ols to more polar metabolites was similar with homogenates from untreated and methylcholanthrene-induced rats, but increased metabolism to polar derivatives was observed after phenobarbitone induction.     

Enzymic studies of glycol and glycerol lipids containing O-alkyl bonds in liver and tumor tissues

The utilization of [1-¹⁴C]hexadecyl-[2-³H]ethyleneglycol and [1-¹⁴C]hexadecyl-[2-³H]glycerol as substrates for acyltransferase, phosphotransferase, phosphorylcholine, and phosphorylethanolamine transferase, and O-alkyl cleavage activities in cell-free preparations from normal rat liver and preputial gland tumors of mice was investigated. Our studies demonstrate that alkylethyleneglycols, like alkylglycerols, can serve as substrates for acyltransferases in both the liver and tumor microsomes; the product alkylacylethyleneglycerol can be readily deacylated by pancreatic lipase. A polar lipid was formed from the alkylethyleneglycol by the tumor homogenates in the presence of ATP and Mg²⁺; although the small quantities formed precluded absolute identification, its thin-layer Chromatographic behavior in acidic and basic solvent systems indicated that a free phosphate group was present. As expected, phosphorylbase transferases in these preparations did not utilize either the alkylethyleneglycol or alkylglycerol as substrates. The O-alkyl moiety of hexadecyl-ethyleneglycol was oxidized to hexadecanal by a tetrahydropteridine-dependent cleavage enzyme in rat liver microsomes, whereas in the tumor microsomes this activity was not present. We conclude that alkylethyleneglycols are metabolized in a manner similar to alkylglycerols and perhaps by identical enzymes.     

The metabolism of cholecalciferol in the liver of Japanese quail (Coturnix coturnix japonica) with particular reference to the effects of oestrogen.

1. Studies were carried out in vitro with the livers of Japanese quail that had been fed from hatching on diets supplying their full requirements for vitamin D. 2. 25-Hydroxycholecalciferol was the major metabolite when liver homogenates of egg-laying female and oestrogen-treated quail of both sexes were incubated with [3H]cholecalciferol. 3. Very little 25-hydroxycholecalciferol was generated from liver homogenates of adult male and immature quail. Instead the cholecalciferol was converted into one or more compounds less polar than 25-hydroxycholecalciferol and into a number of highly polar metabolites, some of which were water-soluble. 4. Oestrogen not only stimulated the 25-hydroxylation of cholecalciferol but also protected both cholecalciferol and 25-hydroxycholecalciferol from degradation by the enzymic pathways active in immature and male birds. 5. These actions of oestrogen may be of physiological significance in relation to the high requirements of laying birds for 1,25-dihydroxycholecalciferol to support the intense metabolism of calcium associated with egg-shell calcification.     

Metabolism and binding in vitro of 5 alpha-androstane-3 beta, 17 beta-diol and of 5 alpha-androstane-3 alpha, 17 beta-diol in cell fractions of rat ventral prostate and liver.

Rat ventral prostate and liver were investigated for the binding in vitro to particulate fractions and for the metabolism of 5 alpha-androstane-3 beta, 17 beta-diol. Comparative investigations were carried out on the metabolism of 5 alpha-androstane-3 alpha, 17 beta-diol. Preparations of the liver were investigated in order to establish the organ specificity of the method. In the prostate, the bulk of the metabolites of 5 alpha-androstane-3 beta, 17 beta-diol was present as steroids of high polarity. Of the less polar metabolites, 17 beta-hydroxy-5 alpha-androstan-3-one, 3 beta-hydroxy-5 alpha-androstan, 17-one and 5 alpha-androstane-3 alpha, 17 beta-diol were detectable. The binding of a 5 alpha-androstane-3 beta, 17 beta-diol to mitochondria and microsomes was unspecific. In the liver, among the less polar metabolites, 3 beta-hydroxy-5 alpha-androstan-17-one was the main metabolite, and the binding was unspecific. The main metabolite in the prostate homogenate of 5 alpha-androstane-3 alpha, 17 beta-diol was 17 beta-hydroxy-5 alpha-androstan-3-one. The portion of highly polar steroids was very low. The portion of unmetabolized hormone was distributed almost equally among the different cell preparations except the nuclei, in which 17 beta-hydroxy-5 alpha-androstan-3-one was higher and 5 alpha-androstane-3 alpha, 17 beta-diol was lower than in the remaining cell fractions.     

Metabolic activation and toxicity of a DDT-metabolite, 3-methylsulphonyl-DDE, in the adrenal zona fasciculata in mice

Whole-body autoradiography of 14C-labelled 3-methylsulphonyl-DDE (3-MeSO2-DDE) in female C57BL mice revealed a heavy accumulation in the adrenal cortex. Fairly high radioactivity appeared in the nasal mucosa and fat, while the labelling of the liver was intermediate. The adrenal radioactivity remained largely unextracted in tissue-sections treated with organic solvents. In the liver and intestinal contents the radioactivity was partly extracted, whereas in all other tissues almost completely extracted. According to light microscopic autoradiography, the tissue-bound adrenal radioactivity was confined to the zona fasciculata, leaving the other adrenal zones devoid of bound material. Incubation of 3-MeSO2-DDE with adrenal tissue (300 X g supernatant) revealed a dose- and time-dependent covalent binding to protein and formation of water-soluble metabolites. The cytochrome P-450 inhibitors metyrapone and carbon monoxide inhibited both covalent binding and polar metabolite formation. Addition of reduced glutathione decreased binding, while polar metabolite formation was increased. Histopathological examination of adrenals from 3-MeSO2-DDE-treated mice revealed extensive vacuolation and necrosis of the zona fasciculata 1-12 days after single doses down to 25 mg/kg. Degenerative changes were observed at 12.5 mg/kg. In contrast to 3-MeSO2-DDE, 14C-labelled 3,3'-bis(methylsulphonyl)-DDE was not accumulated in the adrenal cortex. 3-MeSO2-DDE is thus a persistent environmental pollutant with a unique ability to produce acute toxicity subsequent to metabolic activation in a mammalian tissue.     

[3H]cyclo(Histidyl-Proline) in rat tissues: Distribution,clearance and binding

Cyclo(Histidyl-Proline), a metabolite of TRH, has been demonstrated to have a number of biological activities. The clearance, distribution and binding of the peptide in the rat was studied. Cyclo(His-Pro) was cleared from the circulation biphasically ($\text{tl}\text{2}\text{= 1.25 and 33 min}$). Unmetabolized cyclo(His-Pro) appeared rapidly in urine. Accumulation of [³H]cyclo(His-Pro) in adrenal, liver and kidney was demonstrated. Membrane preparations from adrenal and liver, but not from kidney, brain, pituitary, and other tissues were shown to bind cyclo(His-Pro) specifically.     

Progesterone synthesis,secretion and metabolism by human teratoma-derived cell-lines

The synthesis, secretion and metabolism of progesterone have been examined in six human teratoma-derived cell lines with the objective of determining if they exhibit trophoblast-related or other specific steroidogenic functions. Progesterone was synthesised in nanogram amounts (per 10⁶ cells/day) by the cell line SuSa, as measured by radioimmunoassay, and in lesser amounts by line LICR-LON HX-39. Lines Tera 1, Tera 2, T₃B₁ and PA-1 did not secrete detectable progesterone. All teratomas, however, metabolized added progesterone in microgram amounts (per 10⁶ cells/day). In all cases the major metabolite was a polar compound, identified by reversed phase HPLC, TLC and GC-MS as 3β, 6α-dihydroxy-5α-pregnan-20-one. This pattern of metabolism was not confined to the teratomas as equivalent amounts of this polar metabolite were formed by cultures of adult differentiated human epithelial and fibroblast cells. When progesterone and its metabolites, separated by HPLC, were included in the estimation, the Δ⁵-3β-hydroxysteroid dehydrogenase-isomerase activity of SuSa was equivalent to 47ng pregnenolone (3β-hydroxy-5-pregnen-20-one) metabolised/mg protein/day, that of HX-39 to 9ng/mg protein/day and those of other teratomas to <3.5ng/mg protein/day.     

Metabolism of capsaicinoids: Evidence for aliphatic hydroxylation and its pharmacological implications

A new metabolic oxidation pathway of capsaicin (N-[(4-hydroxy-3-methoxyphenyl)-methyl]-8-methyl-(E)-6-nonenamide), a major pungent and pharmacologically active principle of hot peppers, was investigated. Incubation of capsaicin with phenobarbital-induced rat liver postmitochondrial supernatant enriched with NADPH-generating system produced N-(4, 5-dihydroxy-3-methoxybenzyl)-(E)-6-nonenylamide and a more polar metabolite. The latter metabolite was spectrophotometrically and chromatographically identical to authentic ω-hydroxycapsaicin. This new metabolite was also detected in the urine of rabbits given capsaicin by gastric intubation. Other analogs of capsaicin, such as dihydrocapsaicin and nonivamide, also formed similar metabolites via aliphatic hydroxylation. When tested for antinociceptive activity as well as pungency, the above polar metabolites were found to be inactive while their parent compounds exhibited strong sensory effects. Capsaicin interacted irreversibly with hepatic drug metabolizing enzymes, thereby inhibiting their activity as indicated by prolongation of pentobarbital sleeping time in rats. Such inhibition of drug metabolism was not observed with ω-hydroxycapsaicin. These findings suggest that metabolism of capsaicinoids via hydroxylation of their side chains plays an important role in the detoxification of these pharmacologically active substances.     

Metabolism of prostaglandin A. I. The kidney cortex as a major site of PGA2 degradation

The antihypertensive and natriuretic prostaglandin A₂ (medullin) has been isolated and identified in rabbit renal papilla. Since PGA₂, unlike prostaglandin F₂ (PGE₂) and prostaglandin F_2α (PGF_2α), is not metabolized by the lung, studies were undertaken to determine if the site of PGA₂ metabolism is in the renal cortex where its primary vasodilatory and natriuretic effects occur. In $\text{in vitro}$ experiments, homogenates of renal cortex and outer medulla were incubated with ³H-PGA₂ (0.2 μc, 20 μg) at 37°C for 30 minutes. A metabolite(s) less polar than ³H-PGA₂ was observed following silicic acid chromatography of acidic lipid extracts of cortical, but not outer medullary homogenates. In $\text{in vivo}$ studies, ³H-PGA₂ (2 μc, 50 μg) was injected into the renal artery of the rabbit and blood withdrawn from the ipsilateral renal vein. At least three less polar major metabolites of PGA₂ were observed in the plasma within 15 seconds following injection. No appreciable ³H-PGA₂ was observed in venous plasma 30 seconds following injection of ³H-PGA₂. In contrast to plasma, the major urinary metabolites were more polar than PGA₂. The present study reveals that PGA₂ is almost completely metabolized in a single passage through the rabbit kidney suggesting this organ is a major site of PGA₂ metabolism.