omega-1 and omega-2 hydroxylation of prostaglandins by rabbit hepatic microsomal cytochrome P-450 isozyme 6

Incubation of prostaglandin E1 (PGE1) with liver microsomes from control rabbits and from rabbits treated with ethanol or imidazole yielded 18-, 19-, and 20-hydroxy metabolites, representing hydroxylation at omega-2, omega-1, and omega carbons, respectively. The current investigation demonstrates that rabbit liver P-450 isozyme 6 effectively catalyzes the omega-1 and omega-2 hydroxylation of PGE1 and PGE2. Additionally, a small amount of product with chromatographic characteristics of the corresponding 20-hydroxy metabolite has been detected. The incorporation of cytochrome b5 into the reconstituted system did not enhance the rate of PGE1 hydroxylation and had no effect on the ratio of products formed. The Km value for the omega-1 and omega-2 hydroxylation of PGE1 with P-450 isozyme 6 from imidazole-treated rabbits was approximately 140 microM; the Vmax's (nmol product min-1 nmol P-450-1) were 2.1 and 1.1 for the omega-1 and omega-2 hydroxylations, respectively. These rates represent the highest activities by hepatic P-450 isozymes for hydroxylation of PGs, and suggest that isozyme 6 is responsible for the omega-2 hydroxylation of PGEs observed in rabbit liver microsomes.     

Polar metabolites of di-(2-ethylhexyl)phthalate in the rat

Di-(2-ethylhexyl)phthalate (DEHP) is an important industrial chemical widely used as a plasticizer for vinyl and other plastics. DEHP is extensively metabolized by mammals, different species showing dramatic differences in metabolite distributions. Previous studies of the metabolism in rats led to the suggestion that the enzymatic processes normally associated with omega-, omega-1, alpha-, and beta-oxidation of fatty acids could account for the known metabolites of DEHP found in the urine. Several additional metabolites of DEHP have been identified in the present study. Their formation requires that the initial hydroxylation process be less specific than fatty acid omega- and omega-1 oxidation are thought to be. Furthermore, it is necessary to postulate either that the aliphatic chain of mono-(2-ethylhexyl)phthalate can be oxidized at two sites simultaneously, or that oxidation products can be recycled for a second hydroxylation prior to excretion.     

Omega- and (omega-1)-hydroxylation of lauric acid and arachidonic acid by rat renal cytochrome P-450

We resolved four cytochrome P-450s, designated as P450 K-2, K-3, K-4, and K-5, from the renal microsomes of untreated male rats by high-performance liquid chromatography (HPLC) and investigated the lauric acid and arachidonic acid hydroxylation activities of these fractions. P450 K-4 and K-5 had high omega- and (omega-1)-hydroxylation activities toward lauric acid. The ratio of the omega-/(omega-1)-hydroxylation activity of P450 K-4 and K-5 was 3 and 6, respectively. Also, P450 K-4 and K-5 effectively catalyzed the omega- and (omega-1)-hydroxylation of arachidonic acid. P450 K-3 was not efficient in the hydroxylation of either lauric acid or arachidonic acid. P450 K-2 had low omega- and (omega-1)-hydroxylation activities toward arachidonic acid, and efficiently catalyzed the hydroxylation of lauric acid at the (omega-1)-position only, not at the omega-position.     

Stereoselective aliphatic hydroxylation of 6-n-propylchromone-2-carboxylic acid by female Dutch rabbits.

6-n-Alkylchromone-2-carboxylic acids are metabolized solely by aliphatic oxidation. In the rabbit, the 6-n-propyl congener (PCCA) undergoes omega-1 hydroxylation exclusively. Following administration of PCCA to female Dutch rabbits (500 mumol/kg), some 77% of the dose was excreted in the urine, 41% as PCCA and 36% as 6-(2'-hydroxy-n-propyl)chromone-2-carboxylic acid. Since this metabolite is chiral, we have examined the stereochemistry of the excreted material. Diastereoisomeric (as camphanate and alpha-methoxy-alpha-(trifluoro-methyl)phenylacetate esters) and direct chiral HPLC and chiral lanthanide shift NMR have each shown the S:R ratio of the excreted metabolite to be 76:24. When rabbits were dosed with the racemic metabolite, excretion of the compound was not stereoselective. The regio- and stereo-selectivity of the aliphatic hydroxylation of PCCA are thus reflections of the selectivities of the enzyme systems responsible for its formation and suggest PCCA to be an appropriate probe compound for the study of prochiral-chiral hydroxylations.     

Cytochromes P450 from family 4 are the main omega hydroxylating enzymes in humans: CYP4F3B is the prominent player in PUFA metabolism

Human CYP450 omega-hydroxylases of the CYP4 family are known to convert arachidonic acid (AA) to its metabolite 20-hydroxyeicosatetraenoic acid (20-HETE). This study deals with hydroxylations of four PUFAs, eicosatrienoic acid (ETA), AA, eicosapentaenoic acid (EPA), and docosahexaenoic acid (DHA) by either human recombinant CYP4s enzymes or human liver microsomal preparations. CYP4F3A and CYP4F3B were the most efficient omega-hydroxylases of these PUFAs. Moreover, the differences in the number of unsaturations of ETA, AA, and EPA allowed us to demonstrate a rise in the metabolic rate of hydroxylation when the double bond in 14-15 or 17-18 was missing. With the CYP4F enzymes, the main pathway was always the omega-hydroxylation of PUFAs, whereas it was the (omega-1)-hydroxylation with CYP1A1, CYP2C19, and CYP2E1. Finally, we demonstrated that the omega9 and omega3 PUFAs (ETA, EPA, and DHA) could all be used as alternative substrates in AA metabolism by human CYP4F2 and -4F3B. Thus, they decreased the ability of these enzymes to convert AA to 20-HETE. However, although ETA was the most hydroxylated substrate, EPA and DHA were the most potent inhibitors of the conversion of AA to 20-HETE. These findings suggest that some physiological effects of omega3 FAs could partly result from a shift in the generation of active hydroxylated metabolites of AA through a CYP-mediated catalysis.     

Regioselectivity of hydroxylation of prostaglandins by liver microsomes supported by NADPH versus H2O2 in methylcholanthrene-treated and control rats: formation of novel prostaglandin metabolites

The effects of methylcholanthrene (MC) treatment of male rats on the regioselectivity of hydroxylation of prostaglandins E1 and E2 (PGE1 and PGE2) by liver microsomes, supplemented with NADPH or H2O2, was examined. In the presence of NADPH, control microsomes catalyzed the hydroxylation at omega-1 (C19) and at omega-(C20) sites with minimal formation of novel monohydroxy metabolites of PGE1 and PGE2, referred to as compounds X1 and X2, respectively. Similarly, H2O2 supported the 19-hydroxylation and the formation of compounds X1 and X2, but yielded only minimal amounts of 20-hydroxy products. With NADPH, MC-treated microsomal incubations demonstrated only minor quantitative change in the 19- and 20-hydroxylation as compared with controls, but showed a 7- to 11-fold increase in formation of compound X1 and a 10-fold increase in formation of X2. By contrast with H2O2, MC-treatment increased by about 3-fold the 19- and 20-hydroxylation of PGE1 and by 35- to 46-fold the formation of X1; similarly, there was an approximate 2-fold increase in 19- and 20-hydroxylation of PGE2 and a 10-fold increase in formation of X2. These findings suggest that several monooxygenases are involved in catalyzing the hydroxylation at the various sites of the PGE molecule. Inhibitors of monooxygenases (SKF 525A, alpha-naphthoflavone, and imidazole derivatives) provided further evidence that the hydroxylation at the three sites of PGEs is catalyzed by different P-450 monooxygenases. It is striking that the inhibitors had a much lesser effect on the 20-hydroxylation of PGE1 as compared with other sites of hydroxylation. Structural identification of compounds X1 and X2 was elucidated as follows. Resistance of the PGB derivative of X1 to periodate oxidation and mass fragmentation analysis of the t-butyldimethylsilyl ether methyl ester, placed the hydroxylation at C17 or C18. Finally, mass fragmentation of trimethylsilyl ether methyl ester PGB derivatives of X1 and X2 provided conclusive evidence that X1 and X2 are 18-hydroxy-PGE1 and 18-hydroxy-PGE2, respectively. The above findings indicate that the high regioselectivity of hydroxylation of PGE1 and PGE2, resulting in the formation of 18-hydroxy-PGE1 and 18-hydroxy-PGE2, respectively, is catalyzed by P-450 isozyme(s) which are induced by MC, possibly by P-450c.     

Inhibitory effect of nicotine and its metabolites on tolbutamide hydroxylation in rat liver microsomes

A simple HPLC/fluorescence method to detect hydroxytolbutamide (a major metabolite of the anti-diabetic drug tolbutamide) has been developed. The effects of nicotine and some of its metabolites on tolbutamide hydroxylation is described. An extraction procedure with diethyl ether was followed by isocratic HPLC analysis of tolbutamide hydroxylation with a binary mobile phase composed of 10 mM monobasic sodium phosphate in methanol (45:55, v/v, apparent pH 2.28). A detection limit of sub-nanogram amounts (0.353 ng) of hydroxytolbutamide was obtained with fluorescence detection at 226 nm for excitation and 318 nm for emission. Overall precision values for hydroxytolbutamide was determined with coefficients of variation of 1.4–4.6% when nanogram levels of the metabolite were analyzed. Differential inhibitory responses were demonstrated for tolbutamide hydroxylation to nicotine and its metabolites. Tolbutamide hydroxylation was apparently inhibited by cotinine and relatively less inhibited by nicotine. Nornicotine, however, caused very little inhibition of tolbutamide hydroxylation. The implication is that nornicotine may not share similar affinity for the substrate binding site for tolbutamide. The results also suggest that heavy smokers may experience reduction in tolbutamide metabolism. The assay system itself will be useful for future studies of tolbutamide, and possibly related sulfonylureas.     

The omega-hydroxylation of arachidonic acid by human polymorphonuclear leukocytes

Incubations of [1-14C]arachidonic acid with unstimulated human polymorphonuclear leukocytes resulted in the formation of four new metabolites in a previously described reverse-phase HPLC system. Three of these metabolites were largely suppressed in a CO/O2 (80/20, by vol.) atmosphere indicating a cytochrome-P450-dependent monooxygenase reaction. In agreement with this assumption is their NADPH/O2-dependent formation in the microsomal fraction. One metabolite was identified by gas chromatography/mass spectrometry analysis as omega-hydroxy-arachidonic acid and the two others were secondary products identified as omega-carboxy-arachidonic acid and 5,20-dihydroxy-E,Z,Z,Z-6,8,11,14-eicosatetraenoic acid. Since the affinity for arachidonate of the omega-monooxygenase was quite low and the presence of LTB4 suppressed the omega-hydroxylation of arachidonate, we conclude that the known LTB4 omega-monooxygenase is responsible for the formation of omega-hydroxy-arachidonate. It is unlikely, however, that significant concentrations of these metabolites are formed by activated polymorphonuclear leukocytes in vivo. The fourth metabolite remains tightly associated with the leukocytes but has not been further characterized.     

Human liver microsomal steroid metabolism: identification of the major microsomal steroid hormone 6 beta-hydroxylase cytochrome P-450 enzyme

Cytochrome P-450-dependent steroid hormone metabolism was studied in isolated human liver microsomal fractions. 6 beta hydroxylation was shown to be the major route of NADPH-dependent oxidative metabolism (greater than or equal to 75% of total hydroxylated metabolites) with each of three steroid substrates, testosterone, androstenedione, and progesterone. With testosterone, 2 beta and 15 beta hydroxylation also occurred, proceeding at approximately 10% and 3-4% the rate of microsomal 6 beta hydroxylation, respectively, in each of the liver samples examined. Rates for the three steroid 6 beta-hydroxylase activities were highly correlated with each other (r = 0.95-0.97 for 25 individual microsomal preparations), suggesting that a single human liver P-450 enzyme is the principal microsomal 6 beta-hydroxylase catalyst with all three steroid substrates. Steroid 6 beta-hydroxylase rates correlated well with the specific content of human P-450NF (r = 0.69-0.83) and with its associated nifedipine oxidase activity (r = 0.80), but not with the rates for debrisoquine 4-hydroxylase, phenacetin O-deethylase, or S-mephenytoin 4-hydroxylase activities or the specific contents of their respective associated P-450 forms in these same liver microsomes (r less than 0.2). These correlative observations were supported by the selective inhibition of human liver microsomal 6 beta hydroxylation by antibody raised to either human P-450NF or a rat homolog, P-450 PB-2a. Anti-P-450NF also inhibited human microsomal testosterone 2 beta and 15 beta hydroxylation in parallel to the 6 beta-hydroxylation reaction. This antibody also inhibited rat P-450 2a-dependent steroid hormone 6 beta hydroxylation in uninduced adult male rat liver microsomes but not the steroid 2 alpha, 16 alpha, or 7 alpha hydroxylation reactions catalyzed by other rat P-450 forms. Finally, steroid 6 beta hydroxylation catalyzed by either human or rat liver microsomes was selectively inhibited by NADPH-dependent complexation of the macrolide antibiotic triacetyloleandomycin, a reaction that is characteristic of members of the P-450NF gene subfamily (P-450 IIIA subfamily). These observations establish that P-450NF or a closely related enzyme is the major catalyst of steroid hormone 6 beta hydroxylation in human liver microsomes, and furthermore suggest that steroid 6 beta hydroxylation may provide a useful, noninvasive monitor for the monooxygenase activity of this hepatic P-450 form.     

Regioselective hydroxylation of prostaglandins by constitutive forms of cytochrome P-450 from rat liver: formation of a novel metabolite by a female-specific P-450

Previous studies demonstrated that liver microsomes from untreated rats catalyze the omega, omega-1, and omega-2 hydroxylation of prostaglandins [K. A. Holm, R. J. Engell, and D. Kupfer (1985) Arch. Biochem. Biophys. 237, 477-489]. The current study examined the regioselectivity of hydroxylation of PGE1 and PGE2 by purified forms of P-450 from untreated male and female rat liver microsomes. PGE1 was incubated with a reconstituted system containing cytochrome P-450 RLM 2, 3, 5, 5a, 5b, 6, or f4, NADPH-P-450 reductase, and dilauroylphosphatidylcholine in the presence or absence of cytochrome b5. Among the P-450 forms examined, only RLM 5 (male specific), 5a (present in both sexes), and f4 (female specific) yielded high levels of PGE hydroxylation. With PGE1, RLM 5 catalyzed solely the omega-1 hydroxylation and 5a catalyzed primarily the omega-1 and little omega and omega-2 hydroxylation. By contrast, f4 effectively hydroxylated PGE1 and PGE2 at the omega-1 and at a novel site. Based on retention on HPLC and on limited mass fragmentation, we speculate that this site is omega-3 (i.e., 17-hydroxylation). Kinetic analysis of PGE1 hydroxylation demonstrated that the affinity of f4 for PGE1 is approximately 100-fold higher than that of RLM 5; the Km values for f4, monitoring 19- and 17-hydroxylation of PGE1, were about 10 microM. Surprisingly, cytochrome b5 stimulated the activity of RLM 5a and f4, but not that of RLM 5. Hydroxylation of PGE2 by RLM 5 was at the omega, omega-1, and omega-2 sites, demonstrating a lesser regioselectivity than with PGE1. These findings show that the constitutive P-450s differ dramatically in their ability to hydroxylate PGs, in their regioselectivity of hydroxylation, and in their cytochrome b5 requirement.     

Cytochrome P-450-dependent oxidation of arachidonic acid to 16-, 17-, and 18-hydroxyeicosatetraenoic acids

Incubation of rat liver microsomal fractions with arachidonic acid in the presence of NADPH results in the formation of three novel monohydroxylated fatty acid metabolites. Utilizing chromatographic and mass spectral techniques, these metabolites have been identified as 16-, 17-, and 18-hydroxyeicosatetraenoic acids. The NADPH-dependent microsomal metabolism of arachidonic acid to 16-, 17-, 18-, and 19-hydroxyeicosatetraenoic acids is induced after animal treatment with beta-naphthoflavone. Reconstitution of the arachidonic acid oxygenase utilizing individual purified cytochrome P-450 enzymes demonstrates regioselectivity, controlled by the protein catalyst, for the hydroxylation of the sp3 carbon atoms adjacent to the methyl end of the fatty acid.     

Effect of inducers and inhibitors of monooxygenase on the hydroxylation of prostaglandins in the guinea pig. Evidence for several monooxygenases catalyzing omega- and omega-1-hydroxylation.

The incubation of prostaglandins (PG's) with liver microsomes from guinea pigs treated with inducers of monooxygenase (1,1,1-trichloro-2,2-bis(p-chlorophenyl)ethane (DDT), benzo[alpha]pyrene (benzpyrene), or a mixture of chlorinated biphenyls (Aroclor 1254)) exhibited marked elevation of 19-hydroxylation of PGE1, PGE2, PGA1, and PGA2 without affecting significantly 20-hydroxylation. However, with respect to effects on hydroxylation of a variety of xenobiotics, benzpyrene and Aroclor treatments differed markedly; whereas Aroclor treatment elevated the demethylation of ethylmorphine, benzphetamine, and p-chloro-N-methylaniline (PCMA), benzpyrene treatment had no effect on demethylation of ethylmorphine and only a marginal effect on that of PCMA. Both inducers elevated benzpyrene hydroxylation. By contrast, treatment with phenobarbital did not affect the hepatic microsomal PG's hydroxylation, although the hydroxylation of benzpyrene and the demethylation of ethylmorphine, benzphetamine, and PCMA were enhanced. Also, the hydroxylation of PG's by kidney cortex microsomes was not affected by either benzpyrene or Aroclor treatment. Inhibitors of monooxygenase were used to help delineate the type of monooxygenases induced. At low levels of alpha-naphthoflavone (ANF), benzpyrene hydroxylation in control- and Aroclor-treated guinea pigs was only little affected; by contrast, the same concentration of ANF markedly inhibited benzpyrene hydroxylation in benzpyrene-treated guinea pigs. On the other hand, metyrapone was most inhibitory in control guinea pigs. Support for the conclusion that benzpyrene induces in the guinea pig a hepatic monooxygenase with different characteristics than that found in control animals was provided by the observation that ANF (10 MICROM) inhibited PGE1 hydroxylation more pronouncedly in liver microsomes from benzpyrene-treated than from Aroclor-treated guinea pigs or controls. In addition, in benzpyrene and Aroclor-treated guinea pigs, ANF inhibited the (omega-1)-hydroxylation more pronouncedly than that of omega-hydroxylation. By contrast, metyrapone appeared to inhibit omega-hydroxylation more effectively than (omega-1)-hydroxylation. These results indicate that in the guinea pig, hydroxylation of PG's at the omega (20-) and omega-1 (19-) positions is catalyzed by different monooxygenases and that the inducers tested affect several hepatic monooxygenases with different specificities toward xenobiotics; however, with respect to PG's only the enzyme(s) involved in the 19-hydroxylation is affected.     

Microsomal monooxygenation of the carcinostatic 1-(2-chloroethyl)-3-cyclohexyl-1-nitrosourea. Synthesis and identification of cis and trans monohydroxylated products.

Liver microsomal hydroxylation of 1-(2-chloroethyl)-3-cyclohexyl-1-nitrosourea was shown to occur on the cyclohexyl ring at positions 3 and 4. Four metabolites were isolated by selective solvent extraction and purifed by high-pressure liquid chromatography. cis-4-, trans-4-, cis-3-, and trans-3-OH derivatives of 1-(2-chloroethyl)-3-cyclohexyl-1-nitrosourea were synthesized and their chromatographic, mass spectral, and nuclear magnetic resonance characteristics matched those of the metabolites. The position of ring hydroxylation and the identity of each geometric isomer were established by nuclear magnetic resonance using a shift reagent in conjunction with spin decoupling techniques. Microsomes from rats pretreated with phenobarbital showed a sixfold increase in hydroxylation rate (19.5 vs. 3.3 nmol per mg per min). The induction was quite selective for cis-4 hydroxylation (19-fold); however, induction of trans-4 (threefold), cis-3 (threefold), and trans-3 (twofold) hydroxylation did occur. Quantitatively the cis-4-hydroxy metabolite was 67of the total product by phenobarbital-induced microsomes and 21% for normal microsomes. Microsomes from animals pretreated wit- 3-methyl-cholanthrene gave about the same rate and product distribution that normal microsomes gave. A mixture of 80% carbon monoxide-20% oxygen inhibited formation of all four hydroxy metabolites with the inhibition ranging from 55 to 78%.     

Differential Metabolism of Hydroxyeicosatetraenoic Acid Isomers by Mouse Cerebromicrovascular Endothelium

Hydroxyeicosatetraenoic acid (HETE) derivatives of arachidonic acid are produced in the brain and have been implicated as pathologic mediators in various types of brain injury. To understand better their fate in the brain, particularly in cerebral microvessels, several HETEs were incubated with cultured mouse cerebromicrovascular endothelium for 1, 2, and 4 h, followed by HPLC analysis of medium and cellular lipids. 5(S)-, 8(RS)-, and 9(RS)-HETE were not metabolized by the cells, but were extensively incorporated, unmodified, into cell lipids. On the other hand, 11(RS)-, 12(S)-, and 15(S)-HETE were extensively metabolized and only minimally incorporated into cell lipids. Previously, the major 12-HETE metabolite was identified as 8-hydroxyhexadecatrienoic acid. In the present study, we identified the major 11-HETE metabolite as 7-hydroxyhexadecatrienoic acid and the major 15-HETE metabolite as 11-hydroxyhexadecatrienoic acid. omega-3 compounds, 15(S)- and 12(S)-hydroxyeicosapentaenoic acids (HEPE), were also metabolized to more polar compounds, but to a lesser extent than their tetraenoic acid, omega-6 counterparts. Comparison of 5-, 12-, and 15-HETE enantiomers revealed no differences in metabolism or incorporation between the R and S stereoisomers. These data suggest that many isomers of HETE and HEPE can be incorporated into cell lipids or metabolized by pathways that do not distinguish between enantiomers. These pathways, however, are sensitive to the position or number of double bonds and are selective based on the position of the hydroxyl group.     

Hepatic microsomal metabolism of androst-4-ene-3,17-dione: Relative importance of ring hydroxylation and aromatization in control and induced rat liver

The purpose of these studies was to determine whether oestrogen production is a quantitatively important pathway in the hepatic microsomal metabolism of androst-4-ene-3,17-dione. The effects of the enzyme inducing agents phenobarbitone and β-naphthoflavone on microsomal cytochrome P-450-mediated androst-4-ene-3,17-dione hydroxylation and aromatization was investigated in the rat in vitro. In microsomal fractions from untreated rats the ratio of hydroxylated products to aromatized (oestrogenic) metabolites was 33:1. Phenobarbitone pretreatment of rats increased total hydroxylation by about 20% but did not change the ratio of hydroxylated to aromatized products (27:1). In contrast, β-naphthoflavone induction decreased total hydroxylation to about 35% of control but did not affect total aromatization. Thus the ratio of hydroxylation to aromatization was significantly lower than in control microsomes (17:1).The principal aromatized products were oestriol and 2-hydroxyoestradiol-17β, with oestradiol-17β and its 4-hydroxy metabolite as minor products; no oestrone was observed. In further studies of the microsomal metabolism of oestrone, the major product was oestradiol-17β whereas hydroxylated metabolites were only minor products. Oestradiol-17β, in contrast, was hydroxylated to a considerable extent. These findings suggest that oestrone is a better substrate for the microsomal 17β-oxidoreductase than it is for cytochrome P-450. It therefore appears likely that any oestrone formed from the aromatization of androst-4-ene-3,17-dione would be readily converted to oestradiol-17β which, in turn, is subject to cytochrome P-450-mediated hydroxylation. Although the liver is a site of C₁₉-steroid aromatization, it appears unlikely that this organ could contribute significantly to serum oestrogen levels since microsomal hydroxylases are readily able to convert aromatized products to biologically inactive metabolites.     

Metabolism of valproic acid by hepatic microsomal cytochrome P-450

Incubation of valproic acid with rat liver microsomes led to the formation of 3-, 4- and 5-hydroxy-valproic acid. The latter two metabolites, which have been characterized previously from in vivo studies, may be regarded as products of fatty acid ω-1 and ω hydroxylation, respectively. 3-Hydroxy-valproic acid, however, had been thought to derive from the β-oxidation pathway in mitochondria. Conversion of valproic acid to all three metabolites in microsomes required NADPH (NADH was less effective), utilized molecular oxygen, was suppressed by inhibitors of cytochrome P-450 and was stimulated (notably at C-3 and C-4) by phenobarbital pretreatment of the rats. It is concluded that rat liver microsomal cytochrome P-450 catalyzes ω-2 hydroxylation of valproic acid, a reaction not detected previously with fatty acids in mammalian systems, and that the product, 3-hydroxyvalproic acid, should not be used to assess in vivo metabolism of valproate via the β-oxidation pathway.     

Alkylation and carbamoylation intermediates from the carcinostatic 1-(2-chloroethyl)-3-cyclohexyl -1-nitrosourea (CCNU)

Evidence is presented which shows that 1-(2-chloroethyl) -3-cyclohexyl-1-nitrosourea (CCNU) upon degradation provides a 2-chloroethyl alkylating intermediate, possibly 2-chloroethyl carbonium ion, and 2-chloroethanol. Thiol alkylation occurs $\text{in vivo}$ and a major urinary metabolite of CCNU is thiodiacetic acid. A rapid microsomal hydroxylation of the cyclohexyl ring occurs which yields varying ratios of at least five metabolites: cis or trans 2-hydroxy, trans- 3-hydroxy, cis-3-hydroxy, cis-4-hydroxy and trans-4- hydroxy-CCNU. $\text{In vivo}$ carbamoylation appears to not be due to cyclohexylisocyanate but to the various hydroxy-cyclohexylisocyanates which are formed from hydroxy CCNU metabolites.     

Conjugated linoleic acid reduction of murine mammary tumor cell growth through 5-hydroxyeicosatetraenoic acid

Conjugated linoleic acid (CLA) is a dietary fatty acid that has been shown to reduce tumorigenesis and metastasis in breast, prostate and colon cancer in animals. However, the mechanism of its action has not been clarified. The goal of this study was to determine whether CLA altered mouse mammary tumor cell growth and whether specific metabolites of the lipoxygenase pathway were involved in CLA action. Both t10, c12-CLA and a lipoxygenase inhibitor, but not c9, t11-CLA or linoleic acid (LA), reduced mouse mammary tumor cell viability and growth by inducing apoptosis and reducing cell proliferation. t10, c12-CLA reduced the production of the 5-lipoxygenase metabolite, 5-hydroxyeicosatetraenoic acid (5-HETE). That effect was not seen with c9, t11-CLA or LA. Adding 5-HETE back to tumor cells reduced the t10, c12-CLA effect on both apoptosis and cell proliferation. These data suggest that t10, c12-CLA reduction of tumor cell growth may involve the suppression of the 5-lipoxygenase metabolite, 5-HETE, with subsequent effects on apoptosis and cell proliferation.     

In vitro metabolic stability and metabolite profiling of TJ0711 hydrochloride, a newly developed vasodilatory β-blocker, using a liquid chromatography-tandem mass spectrometry method

In this paper, a liquid chromatography-tandem mass spectrometry (LC-MS/MS) method was developed and validated for the simultaneous analysis of metabolic stability and metabolite profiling of 1-[4-(2-methoxyethyl) phenoxy]-3-[[2-(2-methoxyphenoxy) ethyl]amino]-2-propanol hydrochloride (TJ0711 HCl), a new vasodilatory β-blocker. Multiple reaction monitoring (MRM) was used as a survey scan to quantify the parent compound and to trigger the acquisition of enhanced product ions (EPI) for the identification of formed metabolites. In addition, comparison between MRM-only and MRM-information dependent acquisition-EPI (MRM-IDA-EPI) methods was conducted to determine analytical variables, including linearity, limit of detection (LOD), lower limit of quantification (LLOQ), as well as intra-day and inter-day accuracy and precision. Results demonstrated that MRM-IDA-EPI quantitative analysis was not affected by the addition of EPI scans to obtain qualitative information during the same chromatographic run, compared to MRM-only method. Thereafter, metabolic stability and metabolite identification of TJ0711 HCl were investigated using human liver microsomes (HLM) by the MRM-IDA-EPI method. The in vitro metabolic stability parameters were calculated and t(1/2), microsomal intrinsic clearance (CL(int)), as well as hepatic CL, were 13.0 min, 106.5 μL/min/mg microsomal protein, and 1082.2 mL/min, respectively. The major formed metabolites were also simultaneously monitored and the metabolite profiling data demonstrated that this MRM-IDA-EPI method was capable of targeting a large number of metabolites, in which demethylation and hydroxylation were the principle metabolism pathways during the in vitro incubation with HLM.     

Cytochrome P-450 arachidonic acid epoxygenase. Regulatory control of the renal epoxygenase by dietary salt loading.

The rat kidney microsomal epoxygenase catalyzed the asymmetric epoxidation of arachidonic acid to generate as major products: 8(R),9(S)-, 11(R),12(S)- and 14(S),15(R)-epoxyeicosatrienoic acids with optical purities of 97, 88, and 70%, respectively. Inhibition studies utilizing a panel of polyclonal antibodies to several rat liver cytochrome P-450 isoforms, indicated that the renal epoxygenase(s) belongs to the cytochrome P-450 2C gene family. Dietary salt, administered either as a 2-2.5% (w/v) solution in the drinking water or as a modified solid diet containing 8% NaCl (w/w), resulted in marked and selective increases in the renal microsomal epoxygenase activity (416 and 260% of controls, for the liquid and solid forms of NaCl, respectively) with no significant changes in the microsomal omega/omega-1 oxygenase or in the hepatic arachidonic acid monooxygenase reaction. Immunoblotting studies demonstrated that dietary salt induced marked increases in the concentration of a cytochrome P-450 isoform(s) recognized by polyclonal antibodies raised against human liver cytochrome P-450 2C10 or rat liver cytochrome P-450 2C11. Comparisons of the stereochemical selectivity of the induced and non-induced microsomal epoxygenase(s) with that of purified rat liver cytochrome P-450 2C11 suggest that the salt-induced protein(s) is catalytically and structurally different from liver cytochrome P-450 2C11. The in vivo significance of dietary salt in regulating the activities of the kidney endogenous arachidonic acid epoxygenase was established by the demonstration of a salt-induced 10-20-fold increase in the urinary output of epoxygenase metabolites. These results, in conjunction with published evidence demonstrating the potent biological activities of its metabolites, suggest a role for the epoxygenase in the renal response to dietary salt.