Identification of UGT2B9*2 and UGT2B33 isolated from female rhesus monkey liver

Two UDP-glucuronosyltransferases (UGT2B9(*)2 and UGT2B33) have been isolated from female rhesus monkey liver. Microsomal preparations of the cell lines expressing the UGTs catalyzed the glucuronidation of the general substrate 7-hydroxy-4-(trifluoromethyl)coumarin in addition to selected estrogens (beta-estradiol and estriol) and opioids (morphine, naloxone, and naltrexone). UGT2B9(*)2 displayed highest efficiency for beta-estradiol-17-glucuronide production and did not catalyze the glucuronidation of naltrexone. UGT2B33 displayed highest efficiency for estriol and did not catalyze the glucuronidation of beta-estradiol. UGT2B9(*)2 was found also to catalyze the glucuronidation of 4-hydroxyestrone, 16-epiestriol, and hyodeoxycholic acid, while UGT2B33 was capable of conjugating 4-hydroxyestrone, androsterone, diclofenac, and hyodeoxycholic acid. Three glucocorticoids (cortisone, cortisol, and corticosterone) were not substrates for glucuronidation by liver or kidney microsomes or any expressed UGTs. Our current data suggest the use of beta-estradiol-3-glucuronidation, beta-estradiol-17-glucuronidation, and estriol-17-glucuronidation to assay UGT1A01, UGT2B9(*)2, and UGT2B33 activity in rhesus liver microsomes, respectively.     

Evidence of 2-hydroxylation of estradiol-17 beta 17-glucuronide by male rat liver microsomes

When estradiol-17 beta 17-glucuronide was incubated with male rat liver microsomal preparations with a NADPH-generating system, 2-hydroxyestradiol-17 beta 17-glucuronide was obtained. This 2-hydroxylation was shown to occur without cleavage of the conjugate group. The result clearly indicates that estradiol-17 beta 17-glucuronide could act as substrate for rat liver microsomal 2-hydroxylase.     

Androgen glucuronyl transferase activity in rat liver, evidence for the importance of hepatic tissue in 5 alpha-reduced androgen metabolism

To elucidate the role of the liver in 5 alpha-reduced androgen metabolism, we used a rat liver glucuronyl transferase assay to determine the conversion of 17 beta-hydroxy-5 alpha-androstane-3-one (DHT), 5 alpha-androstane-3 alpha, 17 beta-diol (androstanediol), and androsterone to their glucuronide metabolites. Serum levels of the two isomers of androstanediol glucuronide (androstanediol 3- and 17-glucuronide) were also measured. Using 5 microM unconjugated steroid as substrate, the production rate (pmol/mg/min) for each product from its respective unconjugated steroid was 6.9 +/- 0.4 for DHT glucuronide, 101 +/- 3.3 for androstanediol 3-glucuronide, 71 +/- 2.0 for androstanediol 17-glucuronide, and 181 +/- 11 for androsterone glucuronide. Production rates for androstanediol glucuronide were 800 times greater for rat liver than for rat prostate, when examined under similar conditions. In the presence of either 0 or 5 microM unlabeled androstanediol, about 60% of the androstanediol glucuronide formed by rat liver was androstanediol 3-glucuronide. In normal male rat serum, 69 +/- 8% (mean +/- SEM) of total androstanediol glucuronide was androstanediol 3-glucuronide. We have previously shown that rat prostate forms androstanediol 17-glucuronide, but not androstanediol 3-glucuronide. The results from the present study indicate that rat liver forms both androstanediol glucuronide isomers, and does so in about the same ratio as is found in rat serum. The rate of glucuronidation is also much greater in rat liver than in rat prostate. While other sites of glucuronidation are possible, these results are consistent with the hypothesis that DHT and other unconjugated androgens formed in rat prostate are conjugated to glucuronic acid mainly in the liver.     

Pivaloylcodeine,a new codeine derivative,for the inhibition of morphine glucuronidation. An in vitro study in the rat

We have previously found that phenanthrenic opioids, including codeine, modulate morphine glucuronidation in the rat. Here codeine and five of its derivatives were compared in their effects on the synthesis of morphine-3-glucuronide (M3G) and morphine-6-glucuronide (M6G) from morphine by rat liver microsomal preparations, and by primary cultures of rat hepatocytes previously incubated for 72 h with either codeine or its derivatives. Acetylcodeine and pivaloylcodeine shared the capability of the parent compound of inhibiting the synthesis of M3G by liver microsomes through a noncompetitive mechanism of action. Their IC₅₀ were 3.25, 2.27, and 4.32 μM, respectively. Dihydrocodeine, acetyldihydrocodeine, and lauroylcodeine were ineffective. In all the experimental circumstances M6G was undetectable in the incubation medium. In primary hepatocyte cultures codeine only inhibited M3G formation, but with a lower efficacy than that observed with microsomes (IC₅₀ 20.91 vs 4.32 μM). Preliminary results show that at micromolar concentrations codeine derivatives exhibit a low rate of affinity for μ opiate receptors. In conclusion, acetyl and pivaloyl derivatives of codeine noncompetitively inhibit liver glucuronidation of morphine interacting with microsomes. This study further strengths the notion that phenanthrenic opioids can modulate morphine glucuronidation independently from their effects on μ opiate receptors.     

In vitro and in vivo glucuronidation of 24,25-dihydroxyvitamin D3.

Glucuronidation of 24,25-dihydroxyvitamin D3 has been investigated in in vitro and in vivo experiments. Three positional isomers of 24,25-dihydroxyvitamin D3 monoglucuronide were synthesized from 24,25-dihydroxyprovitamin D3 derivatives with Koenigs-Knorr reaction and used as standard samples. In the presence of the rat liver microsomal fraction and uridine-5'-diphosphoglucuronic acid, 24,25-dihydroxyvitamin D3 gave 3- and 24-glucuronides as the main products in almost equal amounts, but only a small amount of the corresponding 25-glucuronide was obtained. 24,25-Dihydroxyvitamin D3 monoglucuronide was deconjugated with rat intestine homogenate, which indicated the entero-hepatic circulation of 24,25-dihydroxyvitamin D3. After the administration of 24,25-dihydroxyvitamin D3 to rats, its 3- and 24-glucuronides were identified from the bile as inferred from the in vitro experiment. However, the in vivo glucuronidation occurred at the 24-position in preference to the 3-position, and the corresponding 25-glucuronide was not detected. These glucuronides were identified in comparison with standard samples based on their chromatographic behavior during high-performance liquid chromatography and data obtained from liquid chromatography-electrospray ionization-mass spectrometry, which was helpful in identifying these compounds.     

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.     

Sensitive liquid chromatographic method using fluorescence detection for the determination of estradiol 3- and 17-glucuronides in rat and human liver microsomal incubations: formation kinetics

We have developed a sensitive and specific HPLC-fluorescence assay for the determination of estradiol-3-glucuronide and estradiol-17-glucuronide in human and rat liver microsomal incubations. The method utilizes a mobile phase comprised of acetonitrile and 50 mM ammonium phosphate buffer (35:65, v/v) that is pumped though a phenyl column at 1 ml/min; the run time is less than 15 min. Calibration curves for both metabolites were linear over the range 20-4000 pmol. The intra- and inter-day coefficients of variation were <6%. In both rat and human liver microsomes, the formation of estradiol-3-glucuronide displayed atypical kinetics (consistent with activation), while estradiol-17-glucuronide formation was consistent with classical Michaelis-Menten kinetics. Overall, the assay described is a sensitive and reproducible method for the determination of estradiol glucuronides in liver microsomal preparations.     

The biosynthesis of tyramine glucuronide by liver microsomal fractions.

Labelled tyramine glucuronide was synthesized in vitro from UDP-[14C]glucuronic acid, [14C]tyramine or [3H]tyramine. The glucuronidation was carried out at pH9.2 in the presence of a monoamine oxidase inhibitor, trans-2-phenylcyclopropylamine. The Km values for tyramine were 69 and 125 micrometer and those for UDP-glucuronic acid were 260 and 290 micrometer respectively for guinea-pig and rat liver microsomal preparatons. The specific activities of microsomal glucuronyltransferase measured in fresh hepatic preparations of guinea pig, mouse and rat were respectively 601, 251 and 235 pmol of [14C]tyramine glucuronide/min per mg of protein. Increase in activity ranged from 2- to 6-fold in preparations which were frozen and thawed once and 5.4- to 10-fold when the freezing and thawing was repeated. Rabbit liver has very low activity, and monkey liver and intestine were completely devoid of this conjugating capacity.     

Estrogen 2-hydroxylase: Activity in rat tissues

Incubation parameters for a radioderivative assay for estrogen 2-hydroxylase have been examined. The assay was found to be specific and sensitive if a chromatographically purified preparation of COMT was used. Estradiol was found to be a better substrate for the 2-hydroxylase than estrone or estriol. The liver had significantly higher estrogen 2-hydroxylase activity than any other tissue examined. The estrogen 2-hydroxylase was highly localized in the microsomal fraction in both the liver and the brain. The male rat was found to have significantly more estrogen 2-hydroxylase activity in the liver than the female rat. In addition, in the male rat liver, the estrogen 2-hydroxylase activity was reversibly inducible by testosterone and was not affected by phenobarbital. In the male and female rat brain the estrogen 2-hydroxylase activities were similar.     

Steroid glucuronyltransferases of rat liver. Properties of oestrone and testosterone glucuronyltransferases and the effect of ovariectomy, castration and administration of steroids on the enzymes.

1. Microsomal preparations from rat liver, kidney and intestine were tested for UDP-glucuronyltransferase activity by using oestrone, oestradiol-17 beta, oestriol, testosterone, cortisol, cortisone, corticosterone, aldosterone, tetrahydrocortisol and tetrahydrocortisone as substrates. The microsomal preparation from the liver glucuronidated oestrone, oestradiol-17 beta and testosterone. 2. The specific activity of the enzyme was significantly higher in livers from female rats than in those from male rats. 3. Testosterone was actively glucuronidated by both sexes. Cortisol, cortisone, corticosterone, aldosterone, tetrahydrocortisol and tetrahydrocortisone were not glucuronidated by any of the three tissues. 4. The non-ionic detergent Lubrol WX activates liver microsomal UDP-glucuronyltransferase 2-3-fold with oestrone and testosterone as substrates. 5. Oestrone glucuronyltransferase was inhibited by oestradiol-17 beta, predominantly competitively and by testosterone non-competitively. Bilirubin was a non-competitive inhibitor of oestrone glucuronidation. p-Nitrophenol had no effect. 6. Oestrone glucuronyltransferase could not be stimulated by either acute or prolonged treatment of animals with phenobarbital, whereas a single dose of 3-methylcholanthrene led to a moderate stimulation. 7. Ovariectomy leads to a 56% decrease in oestrone glucuronyltransferase activity; administration of oestradiol-17 beta induces the enzyme to normal activity after 12 days, and after 15 days the activity is twice the control value. Actinomycin D and cycloheximide block the oestradiol-17 beta-induced increase in enzyme activity. 8. Castration has no effect on the activity of testosterone glucuronyltransferase, nor does administration of testosterone influence enzyme activity. The results provide strong evidence for the existence of multiple steroid glucuronyltransferases in the liver of the rat.     

The fate of sulphadimethoxine in primates compared with other species

1. The metabolism of sulphadimethoxine (2,4-dimethoxy-6-sulphanilamidopyrimidine) was examined in nine species of primates and nine species of non-primates. 2. The main metabolite of the drug in the urine in man, rhesus monkey, baboon, squirrel monkey, capuchin, bushbaby, slow loris and tree shrew was sulphadimethoxine N(1)-glucuronide. In the green monkey, although the main metabolite was N(4)-acetylsulphadimethoxine, the N(1)-glucuronide was also a major metabolite. 3. In the dog, rat, mouse, guinea pig, Indian fruit bat and hen the N(1)-glucuronide was a minor metabolite in the urine, whereas in the cat, ferret and rabbit this glucuronide was not found in the urine. 4. All the species examined except the dog excreted some N(4)-acetylsulphadimethoxine, which was the major metabolite in the green monkey, rabbit and guinea pig. 5. In the tree shrew, a doubtful primate, N(1)-glucuronide formation was similar to that in the other primates. 6. It is suggested that the slow excretion of the drug by the rat may be due partly to strong binding of the drug to tissue proteins and that the strength of binding may vary with species. 7. In the rat the amount of N(1)-glucuronide found in the urine is not a true indication of the extent of this conjugation since much more of the conjugate was found in the bile (7% of the dose) than in the urine (1%). In the rabbit, no N(1)-glucuronide was found in the bile or urine, but a small amount of sulphadimethoxine N(4)-glucuronide was found in the bile of the rat (0.5% of dose) and rabbit (0.8%).     

Species differences in the metabolism of sulphadimethoxine

1. The fate of sulphadimethoxine (2,4-dimethoxy-6-sulphanilamidopyrimidine) was studied in man, rhesus monkey, dog, rat, guinea pig and rabbit. 2. About 20–46% of the dose (0·1g./kg.) of the drug is excreted in the urine in 24hr. in these species, except the rat, in which only 13% is excreted. 3. In man and the monkey sulphadimethoxine N¹-glucuronide is the major metabolite in the urine. In the rabbit and guinea pig N⁴-acetylsulphadimethoxine is the main metabolite. In the dog the drug is excreted mainly unchanged. In the rat equal amounts of the unchanged drug and its N⁴-acetyl derivative are the main products. 4. Small amounts of sulphadimethoxine N⁴-glucuronide are found in the urine of all the species. Sulphadimethoxine N¹-glucuronide occurs in small amounts in the urine of rat, dog and guinea pig; none is found in rabbit urine. 5. Sulphadimethoxine N⁴-sulphate was synthesized and found to occur in small amounts in rat urine. 6. Monkey liver homogenates fortified with UDP-glucuronic acid are able to synthesize sulphadimethoxine N¹-glucuronide with the drug as substrate. Rat liver has also this ability to a slight extent, but rabbit liver is unable to do so. 7. Sulphadimethoxine N⁴-glucuronide is formed spontaneously when the drug is added to human urine. 8. The biliary excretion of the drug and its metabolites was examined in rats. The drug is excreted in rat bile mainly as the N¹-glucuronide. The N¹- and N⁴-glucuronides administered as such are extensively excreted in the bile by rats.     

A Spectrofluorimetric study of the 7-hydroxylation of coumarin by liver microsomes

1. The fluorescence characteristics of 3- and 7-hydroxycoumarin, and 7-hydroxy-and 7-methoxy-4-methylcoumarin, have been determined. 7-Hydroxycoumarin shows excited-state ionization from pH1 to 9. 2. A sensitive and specific fluorimetric method for the determination of 7-hydroxycoumarin (umbelliferone), and its application to liver homogenates and other tissue preparations, are described. 3. The enzymic hydroxylation of coumarin to 7-hydroxycoumarin has been studied by this method and the optimum conditions have been determined for rabbit-liver preparations. The enzymic activity was found in the microsomal fraction and required NADPH₂ and oxygen. Activity with NADH₂ was one-third of that with NADPH₂. 4. Addition of NADP was necessary for full activity of 10000g supernatant preparations of liver. Nicotinamide added during preparation preserved coenzymic activity in tissue stored at −12°. Glucose 6-phosphate had no effect on the activity of stored or fresh tissue. 5. Inhibition occurred with p-chloromercuribenzoate, and with the usual inhibitors of the microsomal drug-metabolizing enzymes, SKF acid, SKF 525A, and Lilly 7132, but not with 2,2′-bipyridyl. 6. Liver homogenates from rabbit, guinea pig, coypu, cat and pigeon showed activity, but preparations of rat or mouse liver, and of locust fat bodies, did not hydroxylate coumarin to umbelliferone. The enzyme system was absent from rat-liver homogenates and microsomal preparations. Moreover, rat liver also contained inhibitors of the rabbit-liver coumarin-7-hydroxylase system and of the further metabolism of umbelliferone by guinea-pig liver. Guinea-pig-liver preparations hydroxylated coumarin to umbelliferone and then converted this product into its glucuronide. 7. The coumarin-7-hydroxylase activity of female rabbit liver was two to three times that of male rabbit liver.     

Synthesis of 2-hydroxyestriol monoglucuronides and monosulfates

The ring A monoglucuronides and monosulfates of 2-hydroxyestriol were synthesized from 2-hydroxyestriol 16,17-diacetate by means of the Koenigs-Knorr reaction with methyl alpha-acetobromoglucuronate and sulfation with sulfur trioxide-pyridine complex, respectively. The conjugated positions of these compounds were definitely established by conversion to 2-hydroxyestriol monomethyl ethers by methylation, then enzymatic hydrolysis. The ring D monoglucuronides and monosulfates of 2-hydroxyestriol were also prepared from 2-hydroxyestriol 2,3-dibenzyl ether by glucuronidation and sulfation in a similar fashion followed by debenzylation, respectively. The positions of conjugation were established on the basis of their 1H-nuclear magnetic resonance spectral data.     

Regulation of expression of male-specific rat liver microsomal 3 beta-hydroxysteroid dehydrogenase

In the steroidogenic pathways present in the gonads and adrenal cortex, 3 beta-hydroxysteroid dehydrogenase isomerase (3 beta HSD) is a key enzyme which controls the formation of delta 4-3-ketosteroids from delta 5-3 beta-hydroxysteroids. Herein, we used an antibody against human placental 3 beta HSD and a rat testicular 3 beta HSD cDNA probe to study the expression of rat liver 3 beta HSD mRNA and protein. Rat liver microsomal 3 beta HSD activity has been previously reported to exhibit a significant sex difference, with much higher activity in the male. We have shown an age-dependent increase in levels of immunoreactive 3 beta HSD through the time of maturation of the male rat. The immunoreactive protein, of similar molecular size to the human placental and rat testicular 3 beta HSD, was localized to the microsomal fraction of liver and was concentrated in pericentral locations. Immunoreactive protein was not detected in liver of immature (before 25 days of age) rats of either sex or in adult female liver. Northern blot analysis of liver and testicular RNA with a rat testicular 3 beta HSD cDNA probe revealed the presence of a 1.6-kilobase mRNA species in addition to the major 2.1-kilobase mRNA species in adult male liver, neither of which was detected in immature or adult female liver RNA. Hypophysectomy of female rats or treatment with testosterone implants caused induction of liver 3 beta HSD protein, while continuous infusion of GH to male rats decreased the level of 3 beta HSD protein. Similarly, the levels of the mRNA species were decreased after GH treatment. Using [3 alpha-3H]dehydroepiandrosterone as substrate for 3 beta HSD activity, we determined the apparent Km for liver microsomal NAD(+)-dependent 3 beta HSD activity to be 20 microM in both adult male and female liver and was much greater than the Km of rat Leydig tumor 3 beta HSD activity (0.2 microM). Liver 3 beta HSD activity was inhibited by trilostane, a proven inhibitor of gonadal and adrenal 3 beta HSD activity. A rat liver 3 beta HSD cDNA was isolated from a male liver cDNA library that was closely related to the type II 3 beta HSD form of rat ovary but different from type III liver 3 beta HSD. The enzyme obtained upon expression of this cDNA had properties characteristic of male-specific NAD(+)-dependent liver microsomal 3 beta HSD (i.e. high apparent Km for dehydroepiandrosterone) and distinct from those of the high affinity gonadal type I 3 beta HSD.(ABSTRACT TRUNCATED AT 400 WORDS)     

The kinetic basis for age-associated changes in quercetin and genistein glucuronidation by rat liver microsomes

The dietary bioavailability of the isoflavone genistein is decreased in older rats compared to young adults. Since flavonoids are metabolized extensively by the UDP-glucuronosyltransferases (UGTs), we hypothesized that UGT flavonoid conjugating activity changes with age. The effect of age on flavonoid glucuronidation was determined using hepatic microsomes from male F344 rats. Kinetic models of UGT activity toward the flavonol quercetin and the isoflavone genistein were established using pooled hepatic microsomal fractions of rats at different ages, and glucuronidation rates were determined using individual samples. Intrinsic clearance (V_max/K_m) values in 4-, 18- and 28-month-old rats were 0.100, 0.078 and 0.087 ml/min/mg for quercetin-7-O-glucuronide; 0.138, 0.133 and 0.088 for quercetin-3′-O-glucuronide; and 0.075, 0.077 and 0.057 for quercetin-4′-O-glucuronide, respectively. While there were no differences in formation rates of total quercetin glucuronides in individual samples, the production of the primary metabolite, quercetin-7-O-glucuronide, at 30 μM quercetin concentration was increased from 3.4 and 3.1 nmol/min/mg at 4 and 18 months to 3.8 nmol/min/mg at 28 months, while quercetin-3′-O-glucuronide formation at 28 months declined by a similar degree (P≤.05). At 30 and 300 μM quercetin concentration, the rate of quercetin-4′-O-glucuronide formation peaked at 18 months at 0.9 nmol/min/mg. Intrinsic clearance values of genistein 7-O-glucuronide increased with age, in contrast to quercetin glucuronidation. Thus, the capacity for flavonoid glucuronidation by rat liver microsomes is dependent on age, UGT isoenzymes and flavonoid structure.     

Effect on uridine diphosphate glucuronyltransferase activity of depleting and restoring phospholipids to guinea-pig liver microsomal preparations.

Phospholipid depletion substantially inhibited the maximum demonstrable activities of the forward (glucuronidation) and reverse reactions of UDP-glucuronyltransferase towards p-nitrophenol in guinea-pig liver microsomal preparations. Dispersions of liver phospholipids restored activity, whereas non-phospholipid amphipaths failed to do so effectively. These results suggest that the system is probably phospholipid-dependent rather than conformationally constrained by phospholipids.     

A rapid NAD+-linked assay for microsomal uridine diphosphate glucuronyltransferase of rat liver and some observations on substrate specificity of the enzyme.

1. A new and rapid continuous assay of rat liver microsomal UDP-glucuronyltransferase (EC 2.4.1.17) has been developed. It is based on measurement of UDP production from UDP-glucuronate during the glucuronidation reaction; UDP production was continuously measured by coupling it to the conversion of NADH into NAD+ through pyruvate kinase and lactate dehydrogenase. This assay is independent of the acceptor substrate used; several findings confirm its applicability. 2. The glucuronidation rate of a series of phenol derivatives was determined with this assay, by using a Triton X-100-activated microsomal preparation as enzyme source. Conjugation of a series of nitrophenol derivatives was also investigated by the 'classical' assay (measurement of disappearance of the yellow colour of the nitrophenol during glucuronidation). The substrate with the highest conversion rate was 3-methyl-2-nitrophenol. 3. Both electron releasing and electron withdrawing ring substituents increased the glucuronidation rate of the phenol derivatives, as compared with phenol. 4. Lipid solubility seems important for determining the conversion rate: poorly lipid-soluble substrates were glucuronidated only at a low rate and high lipid solubility seems to be a prerequisite for high conversion rate. Glucuronidation of poorly lipid-soluble compounds may be limited by diffusion. 5. The consequences of these findings for the interpretation of studies on heterogeneity of the enzyme are discussed.     

Practical one-step glucuronidation via biotransformation

We herein report a practical one-step glucuronidation method by biotransformation using Streptomyces sp. SANK 60895. This novel direct method of biotransformation has been shown to be more practical and scalable for glucuronidation than previously reported chemical and enzymatic procedures given its simplicity, high β-selectivity, cost-effectiveness, and reproducibility. We applied the present method to the synthesis of acyl glucuronide and hydroxy-β-glucuronide of mycophenolic acid and compound 4, respectively. This method was also shown to be applicable to the N-glucuronidation of various compounds.     

The induction of liver microsomal proteins by 3-methylcholanthrene in rats of different age,sex and strain

The treatment of male and female adult and male and female immature rats with 3-methylcholanthrene results in increases in the intensity of two liver microsomal protein bands separated by sodium dodecyl sulphate-polyacrylamide gel electrophoresis. The induced protein species have estimated molecular weights of about 55 000 and 52 500. The time course of the induction of these species has been followed in a semi-quantitative manner. In immature rats an additional band, corresponding to a protein species with a molecular weight of about 43 000, is also increased by 3-methylcholanthrene treatment. In male adults rats exclusively, treatment with 3-methylcholanthrene also results in a decrease in the intensity of a band corresponding to a protein species of about 51 000. The appearance of this band in the liver microsomal fraction of adult male rats occurs following sexual maturation and its presence represents a significant difference in the microsomal proteins between male and female rats, this protein is not detected in younger male rats or in female rats at any age. These findings are discussed in terms of their possible relevance to the cytochrome P-450 content of the endoplasmic reticulum of rat hepatocytes.