Author index to volume 154

Horseradish peroxidase-catalyzed N-demethylation of aminopyrine and dimethylaniline results in generation of free radical intermediates which can interact with glutathione (GSH) to form a glutathione radical. This can either dimerize to yield glutathione disulfide or react with O₂ to form oxygenated products of glutathione. Ethylmorphine is not a substrate in the peroxidase-mediated reaction, and free radical intermediates which react with GSH, are not formed from aminopyrine and dimethylaniline when the horseradish peroxidase/H₂O₂ system is replaced by liver microsomes and NADPH. Therefore, it appears unlikely that formation of free radical intermediates can be responsible for the depletion of GSH observed during N-demethylation of several drugs in isolated liver cells.     

Microsomal formation and chemical decomposition of pargyline N-oxide

Pargyline undergoes metabolic N-oxidation in rat and rabbit liver microsomal preparations. The reaction requires oxygen and is NADPH dependent. N-oxidation and N-demethylation are equal in both control and induced rat liver microsomes, while N-oxidation is more dominant in rabbit tissue. Experiments investigating the CO-sensitivity and the effects of metyrapone suggest that cytochrome P-450 systems are involved in both reactions in the rat while an additional enzyme is responsible for the N-oxidation in the rabbit. Pargyline N-oxide is characterized by chemical instability and undergoes two consecutive rearrangements to yield propenal and Schiff bases, the latter undergoing hydrolysis to aldehydes and primary amines. Accordingly, due to the inherent instability of the N-oxide, metabolic N-oxidation of pargyline is, in addition to α-carbon oxidation, indicated as a metabolic route to benzaldehyde. Similarly the ease with which pargyline N-oxide generates propenal implicates N-oxidation as a metabolic route to be considered when evaluating the toxicity of pargyline.     

Simultaneous measurement of nicotinamide and its catabolites,nicotinamide N-oxide,N1-methyl-2-pyridone-5-carboxamide,and N1-methyl-4-pyridone-3-carboxamide,in mice urine

Nicotinamide N-oxide is a major nicotinamide catabolite in mice but not in humans and rats. A high-performance liquid chromatographic method for the simultaneous measurement of nicotinamide, nicotinamide N-oxide, N¹-methyl-2-pyridone-5-carboxamide, and N¹-methyl-4-pyridone-3-carboxamide in mice urine was developed by modifying the mobile phase of a reported method for measurement of nicotinamide N-oxide.     

Assimilatory reduction of trimethylamine N-oxide in the yeast Sporopachydermia cereana

Summary Washed microsomal preparations (100 000 xg sediment) from the yeast Sporopachydermia cereana that had been grown on trimethylamine N-oxide as sole nitrogen source catalysed the NAD(P)H-dependent reduction of trimethylamine N-oxide to trimethylamine. Under anaerobic conditions, this was the sole reaction product, but under aerobic conditions only small amounts of trimethylamine accumulated, most being further metabolized to methylamine and formaldehyde (no detectable dimenthylamine accumulated due to its rapid turnover). In the absence of NAD(P)H, no formation of amines or formaldehyde from trimethylamine N-oxide was detected. The trimethylamine N-oxide reductase activity was inhibited by quinacrine, Cu²⁺ ions, triethylamine N-oxide (apparent K _i 0.43 mM) and dimethyl sulphoxide (K _i 0.94 mM). Chlorate and nitrate failed to inhibit the enzyme. The K _m for trimethylamine N-oxide was 29 M. Triethylamine N-oxide was also reduced by the microsomal preparation with the formation of acetaldehyde, and this reduction was sensitive to the same inhibitors as trimethylamine N-oxide, suggesting that both amine oxides are metabolized by the same enzyme(s). It is concluded that trimethylamine N-oxide is metabolized in this yeast via an NAD(P)H-dependent reductase.Abbreviations TMAO triemthylamine N-oxide     

Hepatic microsomal N-oxidation and N-demethylation of N,N-dimethylaniline in red-winged blackbird compared with rat and other birds.

Hepatic microsomes prepared from red-winged blackbirds ($\text{Agelaius phoeniceus}$) and albino rats were incubated with $\text{N}$,$\text{N}$-dimethylaniline (DMA)_in complete incubation mixtures at pH 7.9 and 37°C for 10 min. Formaldehyde and $\text{N}$,$\text{N}$-dimethylaniline-$\text{N}$-oxide produced from DMA were measured. Redwings were found to have significantly lower $\text{N}$-demethylation activities than rats, and redwings had only marginal or no $\text{N}$-oxidation activities. Hepatic microsomes from redwings did not further metabolize the $\text{N}$-oxide. The $\text{N}$-oxidation and $\text{N}$-demethylation activities of brown-headed cowbirds ($\text{Molothrus ater}$), common grackles ($\text{Quiscalus quiscula}$), and starlings ($\text{Sturnus vulgaris}$) were similar to those of redwings.     

Studies on the mechanism of microbial N-demethylation of codeine by cell-free extracts of Cunninghamella bainieri

Cell-free extracts have been prepared from the fungus Cunninghamella bainieri which retain high levels of N-demethylase activity against codeine and other drug molecules. Extraction required both disruption and solubilization, indicating that the N-demethylase enzyme is probably membrane bound. The carbon monoxide-reduced u.v. difference spectrum of the extract suggests the presence of a cytochrome P-450. The effect of specific inhibitors and the generation of formaldehyde during the transformation suggest a mono-oxygenase mediated mechanism. Kinetic studies have shown that N-demethylation is unlikely to occur via the N-oxide intermediate. Instead it is proposed that N-demethylation proceeds via the transient N-hydroxymethyl intermediate.     

Flavin-containing monooxygenase mediated metabolism of benzydamine in perfused brain and liver

Benzydamine (BZY) N-oxidation mediated by flavin-containing monooxygenase (FMO) was evaluated in perfused brain and liver. Following 20 min of perfusion with modified Ringer solution, the infusion of BZY into brain or liver led to production of BZY N-oxide. BZY N-oxide, a metabolite of BZY oxidized exclusively by FMO, was mostly recovered in the effluent without undergoing further metabolism or reduction back to the parent substrate. The BZY N-oxide formation rate increased as the infusion concentration of BZY increased both in perfused brain and perfused liver. BZY N-oxidation activities in perfused rat brain and liver were 4.2 nmol/g brain/min and 50 nmol/g liver/min, respectively, although the BZY N-oxidation activity in brain homogenates was one 4000th that in liver homogenates. This is the first study of FMO activity in brain in situ.     

Determination of nicotinamide N-oxide—a human excretory product

A method for the determination of nicotinamide N-oxide has been developed. It is based on the ability of the N-oxide to function as an electron acceptor in the xanthine oxidase catalyzed oxidation of xanthine. In simple mixtures the N-oxide can be converted quantitatively to nicotinamide and the latter determined by the cyanogen bromide method. The conversion is not always quantitative in complex mixtures, such as urine; an isotope dilution variation on the basic method permits the determination of the N-oxide in such situations. The basic method is applicable over the range 0.02–0.3 μmole of nicotinamide N-oxide.The new method has been used to verify the prominent excretory role of nicotinamide N-oxide in rodents. Application of the method to a study of human urines has permitted the detection of the N-oxide as an excretory metabolite in man. Only vanishingly small quantities of the N-oxide are excreted under normal conditions. However after the ingestion of 200 mg of nicotinamide, significant quantities of the N-oxide are detectable in human urine. Urine samples obtained from a number of other mammalian species contained little or no detectable nicotinamide N-oxide.     

(+)-5,17-dehydromatrine N-oxide,a new alkaloid in Euchresta japonica

A new lupin alkaloid, (+)-5,17-dehydromatrine N-oxide, was isolated from the fresh aerial parts of Euchresta japonica. Its structure was confirmed by spectrometric data and by direct comparison with a synthetic sample, prepared from (+)-sophoranol ((+)-5-hydroxymatrine). It was also concluded that (+)-5,17-dehydromatrine N-oxide and (+)-matrine N-oxide possess the same configuration with respect to the asymmetric nitrogen by NMR spectra.     

Hydrogen peroxide formation and stoichiometry of hydroxylation reactions catalyzed by highly purified liver microsomal cytochrome P-450.

The stoichiometry of hydroxylation reactions catalyzed by cytochrome P-450 was studied in a reconstituted enzyme system containing the highly purified cytochrome from phenobarbital-induced rabbit liver microsomes. Hydrogen peroxide was shown to be formed in the reconstituted system in the presence of NADPH and oxygen; the amount of peroxide produced varied with the substrated added. NADPH oxidation, oxygen consumption, and total product formation (sum of hydroxylated compound and hydrogen peroxide) were shown to be equimolar when cyclohexane, benzphetamine, or dimethylaniline served as the substrate. The stoichiometry observed represents the sum of two activities associated with cytochrome P-450. These are (1) hydroxylase activity: NADPH + H⁺ + O₂ + RH → NADP⁺ + H₂O + ROH; and (2) oxidase activity: NADPH + H⁺ + O₂ → NADP⁺ + H₂O₂. Benzylamphetamine (desmethylbenzphetamine) acts as a pseudosubstrate in that it stimulates peroxide formation to the same extent as the parent compound (benzphetamine), but does not undergo hydroxylation. Accordingly, when benzylamphetamine alone is added in control experiments to correct for the NADPH and O₂ consumption not associated with benzphetamine hydroxylation, the expected 1:1:1 stoichiometry for NADPH oxidation, O₂ consumption, and formaldehyde formation in the hydroxylation reaction is observed.     

Fates of N′-Methylnicotinamide and Nicotinamide N-Oxide in Mice

This experiment was performed to investigate the possibility that N′ -methylnicotinamide (N′-methyl-3-pyridinecarboxamide) and nicotinamide N-oxide have niacin activity or not in animals. When 20 mg N′-methylnicotinamide per mouse was administered, urinary excretion of nicotinamide, N¹-methylnicotinamide (MNA), N¹-methyl-2-pyridone-5-carboxamide (2-Py), and N¹-methyl-4-pyridone-3-carboxamide (4-Py) increased 24-, 3-, 3-, and 3-fold, respectively, compared with the control values. The increased ratios of MNA, 2-Py, and 4-Py were almost the same as those when 20 mg nicotinamide was administered. Therefore, the relative activity of N′-methylnicotinamide to nicotinamide as niacin was considered to be about 1. When 20 mg nicotinamide N-oxide per mouse was administered, urinary excretion of nicotinamide, MNA, 2-Py, and 4-Py increased 6.4-, 1.8-, 1.6-, and 1.7-fold, respectively, compared with the control values. The increased ratios of MNA, 2-Py, and 4-Py were about 1/2 of those when 20 mg nicotinamide was administered, so the relative activity of nicotinamide N-oxide to nicotinamide as niacin is considered to be about 1/2. In conclusion, it was found the possibility that the reactions N′-methylnicotinamide → nicotinamide and nicotinamide N-oxide → nicotinamide occur, at least in mice, and that therefore N′-methylnicotinamide and nicotinamide N-oxide have niacin activity.     

NADPH-cytochrome P450 reductase.

The rate of reduction of cytochrome P450 in hepatic microsomes in the presence of NADPH has been measured with a dual wavelength stopped-flow spectrophotometer. The results obtained, with microsomes prepared from phenobarbital-pretreated rats, indicate that the reduction process is biphasic and most probably composed of two concurrent first-order reactions. The rate constant for the reduction of cytochrome P450 in the fast phase in the presence of ethylmorphine is 1.74 s^?1. Since approximately 50% or more of the cytochrome P450 is reduced in the fast phase under these conditions, the rate of reduction of cytochrome P450 is approximately 150 nmol min^?1 (mg of protein)^?1. Under similar conditions the rate of ethylmorphine N-demethylation is 8.6 nmol min^?1 (mg of protein)^?1. Thus the rate-limiting step in ethylmorphine N-demethylation cannot be the introduction of the first electron into cytochrome P450 by NADPH-cytochrome P450 reductase.     

Novel N-oxide derivatives of benzyltetrahydroisoquinoline alkaloid from the tubers of Stephania viridiflavens H.S. Lo et M. Yang

An investigation on the phytochemistry of the medicinal plant Stephania viridiflavens H.S. Lo et M. Yang led to isolate two new naturally occurring benzyltetrahydroisoquinoline alkaloids, (+)-1S, 2R-laudanidine-N_β-oxide 2 and (+)-1S, 2S-laudanidine-N_α-oxide 3, along with four known benzyltetrahydroisoquinoline alkaloids: (+)-laudanidine 1, (+)-reticuline 4, (+)-1S, 2R-reticuline-N_β-oxide 5 and (+)-1S, 2S-reticuline-N_α-oxide 6. The structure and the stereochemistry of these compounds were determined on the basis of spectroscopic methods and also confirmed by partial synthesis. To examine putative acetycholinesterase (AChE) inhibitory or cytotoxic activities, various bioassays were performed, the N-oxide derivatives (5 and 6) demonstrated more potent cytotoxicity than the corresponding free base.     

Synthesis and characterization of 5-hydroxymethyl-5-methyl-pyrroline N-oxide and its derivatives

Synthesis and spin trapping behavior of three novel DMPO derivatives, namely 5-hydroxymethyl-5-methyl-pyrroline N-oxide (HMMPO), 5-(2-furanyl)-oxymethyl-5-methyl-pyrroline N-oxide (FMMPO), and 5-(2-pyranyl)-oxymethyl-5-methyl-pyrroline N-oxide (PMMPO) towards different oxygen- and carbon-centered radicals are described. The stabilizing effect of a series of cyclodextrins on the superoxide adducts was tested.     

Hydroperoxide specificity of plant and human tissue lipoxygenase: an in vitro evaluation using N-demethylation of phenothiazines

Since hydroperoxide specificity of lipoxygenase (LO) is poorly understood at present, we investigated the ability of cumene hydroperoxide (CHP) and tert-butyl hydroperoxide (TBHP) to support cooxidase activity of the enzyme toward the selected xenobiotics. Considering the fact that in the past, studies of xenobiotic N-demethylation have focused on heme-proteins such as P450 and peroxidases, in this study, we investigated the ability of non-heme iron proteins, namely soybean LO (SLO) and human term placental LO (HTPLO) to mediate N-demethylation of phenothiazines. In addition to being dependent on peroxide concentration, the reaction was dependent on enzyme concentration, substrate concentration, incubation time, and pH of the medium. Using Nash reagent to estimate formaldehyde production, the specific activity under optimal assay conditions for the SLO mediated N-demethylation of chlorpromazine (CPZ), a prototypic phenothiazine, in the presence of TBHP, was determined to be 117±12 nmol HCHO/min/mg protein, while that of HTPLO was 3.9±0.40 nmol HCHO/min/mg protein. Similar experiments in the presence of CHP yielded specific activities of 106±11 nmol HCHO/min/mg SLO, and 3.2±0.35 nmol HCHO/min/mg HTPLO. As expected, nordihydroguaiaretic acid and gossypol, the classical inhibitors of LOs, as well as antioxidants and free radical reducing agents, caused a marked reduction in the rate of formaldehyde production from CPZ by SLO in the reaction media fortified with either CHP or TBHP. Besides chlorpromazine, both SLO and HTPLO also mediated the N-demethylation of other phenothiazines in the presence of these organic hydroperoxides.     

N-Demethylation and N-oxidation of imipramine in rat thoracic aortic endothelial cells

The aim of this study was to examine whether cultured rat thoracic aortic endothelial cells (TAECs) have the ability to metabolize the tertiary amine, imipramine. In rat TAECs, imipramine was biotransformed into N-demethylate and N-oxide by cytochrome P450 (CYP) and flavin-containing monooxygenase (FMO), respectively. The intrinsic clearance (V _max/K _m) for the N-oxide formation was approximately five times as high as that for the N-demethylate formation, indicating that oxidation by CYP was much higher than that by FMO. Moreover, we suggest that CYP2C11 and CYP3A2 are key players in the metabolism to N-demethylate in rat TAECs using the respective anti-rat CYP antibodies (anti-CYP2C11 and anti-CYP3A2). The presence of CYP2C11 and CYP3A2 proteins was also confirmed in cultured rat TAECs using a polyclonal anti-CYP antibody and immunofluorescence microscopy. In contrast, the formation rate of N-oxide at pH 8.4 was higher than that at pH 7.4. Inhibition of N-oxide formation by methimazole was found to be the best model of competitive inhibition yielding an apparent K _i value of 0.80 μmol/L, demonstrating that N-oxidation was catalyzed by FMO in rat TAECs. These results suggest that rat TAEC enzymes can convert substrates of exogenous origin such as imipramine, indicating that TAECs have an important function for metabolic products, besides hepatic cells.     

Bacterial degradation of p-methoxybenzoic acid

Summary A cell-free system from a Pseudomonas sp., strain PM3, catalysed the oxidative demethylation, hydroxylation and subsequent ring cleavage of p-methoxybenzoate. Demethylation, to yield p-hydroxybenzoate, involved absorption of 1.0 mole of oxygen/mole of p-methoxybenzoate, and required reduced pyridine nucleotide (either NADH or NADPH) as cofactor. p-Hydroxybenzoate was hydroxylated to yield protocatechuate with the absorption of 1 mole of oxygen/mole of substrate, and required NADPH as cofactor. Protocatechuate was oxidized, with absorption of 1 mole of oxygen/mole of substrate, to 3-oxoadipate. The methyl group of p-methoxybenzoate was removed as formaldehyde, and oxidized to formate and carbon dioxide by formaldehyde dehydrogenase, which required GSH and NAD⁺, and formate dehydrogenase, which required NAD⁺.     

Detoxification of the phytoalexin pisatin by a fungal cytochrome P-450

The fungus Nectria haematococca, a pathogen of garden pea (Pisum sativum), can demethylate pisatin, an antimicrobial compound synthesized by infected pea tissue. The phenolic product is less toxic than pisatin to many microorganisms. Cell extracts catalyzing pisatin demethylation were obtained from N. haematococca, and the properties of the reaction were examined. The enzyme activity was greatest in the high-speed pellet fraction, in which rates up to 20 nmol/min/mg protein were observed. The K_m for pisatin was relatively low, less than 5 μm. The reaction was dependent on NADPH, which could not be replaced by any other cofactor tested. However, in the presence of NADPH, NADH increased the rate of demethylation. Oxygen uptake by the enzyme was stimulated by addition of pisatin, the increment of oxygen utilization being approximately equimolar with pisatin added. Formaldehyde was a product of the reaction. The effects of various inhibitors were tested to determine whether this reaction is mediated by cytochrome P-450. The respiratory inhibitors KCN (1 mm) and antimycin A strongly inhibited the demethylation of pisatin by intact cells of the fungus, but not by the NADPH-supplemented enzyme. The cytochrome P-450 inhibitors SKF 525-A and 1-(2-isopropylphenyl)imidazole inhibited demethylation both in whole cells and in the enzyme preparation, though the latter compound was effective only at high concentrations. Most other cytochrome P-450 inhibitors tested had little effect. However the reaction was quite sensitive to CO, and this inhibition was readily reversed by light at wavelengths near 450 nm. It is concluded that pisatin demethylase is a cytochrome P-450 monooxygenase.     

Evidence for a free radical mechanism of N-demethylation of N,N-dimethylaniline and an analog by hemeprotein--H2O2 systems.

Horseradish peroxidase and metmyoglobin catalyze the H₂O₂-supported N-demethylation of N,N-dimethylaniline and N,N-dimethyl-p-toluidine. The catalytic activities of horseradish peroxidase are more than 100-fold larger than those of metmyoglobin or those previously reported for liver microsomal cytochrome P-450. Distinct free radical species of these N-methyl substrates were detected with both catalysts. These findings establish the general validity of a recently proposed free radical mechanism of oxidative N-demethylation (Griffin, B. W., and Ting, P. L., Biochemistry (1978), 2206–2211), which is quite different from that previously suggested for the analogous cytochrome P-450-dependent reactions.     

Spectral evidence for the formation of active intermediates from RuCl3 and RuCl2(PPh3)3 with N-methylmorpholine N-oxide (NMO) and phenyliodosoacetate (PIA) as mild oxidants

Electronic, EPR and IR spectral evidence are given for the formation of the following active species: (1) ruthenium(VIII) in ruthenium(III)-PIA system, (2) ruthenium(V) oxo species in ruthenium(III)-N- oxide system, and (3) ruthenium(II)-phosphine oxide complex in ruthenium(II) N-oxide system. Cyclic voltammetric studies also suggest the formation of Ru(V) in ruthenium(III)-N-oxide system.