Fatty acid hydroxylation in rat kidney cortex microsomes

Rat kidney microsomes have been found to catalyze the hydroxylation of medium-chained fatty acids to the omega- and (omego-1)-hydroxy derivatives. This reaction, which requires NADPH and molecular oxygen, is a function of monooxygenase system present in the kidney microsomes, containing NADPH-cytochrome c reductase and cytochrome P-450K. NADH is about half as effective as an electron donor as NADPH and there is an additive effect in the presence of both nucleotides. Cytochrome P-450K absorbs light maximally at 452-3 nm, when it is reduced and bound to carbon monoxide. The extinction coefficient of this complex is 91 mM(-1) cm(-1). Electrons from NADPH are transferred to cytochrome P-450K via the NADPH-cytochrome c reductase. The reduction rate of cytochrome P-450K is stimulated by added fatty acids and the reduction kinetics reveal the presence of endogenous substrates bound to cytochrome P-450K. Both cytochrome P-450K concentration and fatty acid hydroxylation activity in kidney microsomes are increased by starvation. On the other hand, phenobarbital treatment of the rats has no effect on either the hemoprotein or the overall hydroxylation reaction and 3,4-benzpyrene administration induces a new species of cytochrome P-450K not involved in fatty acid hydroxylation. Cytochrome P-450K shows, in contrast to liver P-450, high substrate specificity. The only substances forming enzyme-substrate complexes with cytochrome P-450K are the medium-chained fatty acids and certain derivatives of these acids. The chemical requirements for substrate binding include a carbon chain of medium length and at the end of the chain a carbonyl group and a free electron pair on a neighbouring atom. The distance between the binding site for the carbonyl group and the active oxygen is suggested to be in the order of 16 A. This distance fixes the ratio of omega- and (omega-1)-hydroxylated products formed from a certain fatty acid by the single species of cytochrome P-450K involved. The membrane microenvironment seems also to be of importance for the substrate specificity of cytochrome P-450K, since removal of the cytochrome from the membrane lowers its binding specificity to some extent. A comparison between the liver and kidney cytochrome P-450 systems suggests that the kidney cytochrome P-450K system is specialized for fatty acid hydroxylation.     

Ring hydroxylation of 25-hydroxycholecalciferol by rat renal microsomes

Two metabolites have been isolated from rat renal microsomes incubated with 25-hydroxycholecalciferol. Postmitochondrial supernatant fractions from kidneys of thyroidectomized and parathyroidectomized rats were incubated with magnesium acetate, potassium acetate, an NADPH generating system, and 25-hydroxycholecalciferol at a level of 20 micrograms/ml postmitochondrial supernatant for 60 min at 30 degrees C. Lipid extracts of the incubation mixtures were purified by silica gel TLC and HPLC. Two peaks were obtained. Metabolite chi 2 eluted at 18 min and metabolite chi 1 at 23 min when chromatographed on a silica column developed with hexane-isopropanol. Metabolites chi 1 and chi 2 were found to have maximal absorbance at 265 nm. Both metabolites were periodate sensitive, indicating vicinal hydroxyl groups. Mass spectral analysis of metabolite chi 2, which was isolated in greater quantity than metabolite chi 1, indicates that metabolite chi 2 had resulted from hydroxylation of the A ring. Results indicate that 25-hydroxycholecalciferol is hydroxylated on carbon 2 or carbon 4 by renal microsomes. Metabolites chi 1 and chi 2, because of similarity in chromatographic migration and periodate sensitivity, are, perhaps, isomers or 2- and 4-hydroxylated metabolites.     

Kinetic characteristics of 3,4-benzpyrene hydroxylation in the liver microsomes of mice

The kinetic parameters of binding and hydroxylation of hydrophobic substrate 3,4-benzpyrene have been studied in liver microsomes of untreated and 3-methylcholanthrene treated mice. The reaction of benzpyrene-hydroxylase has been established to be described by hyperbolic curve, which characterizes the dependence of [ES] and d(P)/dt on [E0] for reactions in biphasic system. A key role of microsomal membraneous phospholipids has been revealed in competitive inhibition of 3,4-benzpyrene hydroxylation. For the adequate application of Michaelis--Menten theory for benzpyrene-hydroxylation reaction a modified method of 3,4-benzpyrene-hydroxylation in the samples with low content of protein in microsomal fraction is suggested.     

Biotransformation of terodiline. V. Stereoselectivity in hydroxylation by human liver microsomes

The stereoselective hydroxylation of N-tert-butyl-4,4-diphenyl-2-butylamine (Terodiline) was studied in human liver microsomes. Formation of the two main metabolites, N-tert-butyl-4(4-hydroxyphenyl)-4-phenyl-2-butylamine (II) and N-(2-hydroxymethyl-2-propyl)-4,4-diphenyl-2-butylamine (VI), was found to be stereoselective. R-Terodiline was preferentially transformed by phenolic hydroxylation to the 2R,4S-II and 2R,4R-II forms with a pronounced selectivity for the former. The formation rate ratio 2R,4S-II/2R,4R-II was about 6, obtained from two liver preparations. S-Terodiline was mainly hydroxylated to the alcohol 2S-VI although phenolic hydroxylation to the 2S,4S-II and 2S,4R-II also occurred, yielding about equal amounts of the two phenols.     

Lipid peroxide formation in microsomes. Relationship of hydroxylation to lipid peroxide formation

1. Metal ion-chelating agents such as EDTA, o-phenanthroline or desferrioxamine inhibit lipid peroxide formation when rat liver microsomes prepared from homogenates made in pure sucrose are incubated with ascorbate or NADPH. 2. Microsomes treated with metal ion-chelating agents do not form peroxide on incubation unless inorganic iron (Fe(2+) or Fe(3+)) in a low concentration is added subsequently. No other metal ion can replace inorganic iron adequately. 3. Microsomes prepared from sucrose homogenates containing EDTA (1mm) do not form lipid peroxide on incubation with ascorbate or NADPH unless Fe(2+) is added. Washing the microsomes with sucrose after preparation restores most of the capacity to form lipid peroxide. 4. Lipid peroxide formation in microsomes prepared from sucrose is stimulated to a small extent by inorganic iron but to a greater extent if adenine nucleotides, containing iron compounds as a contaminant, are added. 5. The iron contained in normal microsome preparations exists in haem and in non-haem forms. One non-haem component in which the iron may be linked to phosphate is considered to be essential for both the ascorbate system and NADPH system that catalyse lipid peroxidation in microsomes.     

In vitro hydroxylation of bentazon by microsomes from naphthalic anhydride-treated corn shoots

In vitro metabolism of the herbicide bentazon was studied in microsomal membranes isolated from 6-day-old etiolated corn shoots. Microsomes isolated from shoots of nontreated seeds did not metabolize bentazon when assayed with NADPH or peroxides. However, microsomes isolated from shoots of seeds pretreated with naphthalic anhydride formed a single bentazon metabolite when provided with NADPH. The metabolite was identified as 6-hydroxybentazon, the major phase I metabolite produced in vivo. In vitro formation of this metabolite was strongly inhibited by carbon monoxide, nitrogen, and tetcyclacis (10 microM). The results suggest that aryl hydroxylation of bentazon in corn shoots is catalyzed by a cytochrome P-450 (E.C. 1.14.14.1) and that a seed pretreatment with naphthalic anhydride is necessary for recovery of activity in vitro.     

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.     

Kinetics and mechanism of oxygen-independent hydrocarbon hydroxylation by ethylbenzene dehydrogenase

Ethylbenzene dehydrogenase (EBDH) from the denitrifying bacterium Azoarcus sp. strain EbN1 (to be renamed Aromatoleum aromaticum) catalyzes the oxygen-independent, stereospecific hydroxylation of ethylbenzene to (S)-1-phenylethanol, the first known example of direct anaerobic oxidation of a nonactivated hydrocarbon. The enzyme is a trimeric molybdenum/iron-sulfur/heme protein of 155 kDa that is quickly inactivated in air in its reduced state. Enzyme activity can be coupled to ferricenium tetrafluoroborate, providing a convenient way for kinetic measurements. EBDH exhibits activity with a wide range of ethylbenzene analogues, which were analyzed for their kinetic parameters, stoichiometry, and formed products. The reactivity was correlated to the chemical structures by a quantitative structure-activity relationship (QSAR) model. On the basis of these results, quantum chemical calculations of DeltaG298 for formation of carbocations of the respective substrates were performed and used in reactivity analysis. A putative reaction mechanism is proposed on the basis of the experimental results and theoretical considerations. Finally, the enzyme reaction has been established in an electrochemical reactor, allowing sustained enzymatic reaction and potential technical applications of the enzyme.