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NADPH and cytochrome

If cyclohexanecarboxaldehyde is incubated with CYP2B4, NADPH, and cytochrome P450 reductase, the aldehyde-cyclohexyl ring carbon-carbon bond is cleaved generating cyclohexene and formic acid (150) (Fig. 4.81). The reaction is supported if hydrogen peroxide replaces NADPH and cytochrome P450 reductase but is not supported if other oxidants at the same oxidation equivalent as peroxide but bypass the peroxy form of P450 such as iodosobenzene, m-chloroperbenzoic acid, or cumyl hydroperoxide are used. These... [Pg.94]

Desaturation of fatty acids is a complex process that requires 02, NADPH, and cytochrome b5. [Pg.194]

Aromatic and aliphatic sulphides, thioethers, thiols, thioamides and thiocarbamates may undergo oxidation to form sulphoxides and then, after further oxidation, sulphones (figure 4,23). This is catalysed by a microsomal mono-oxygenase requiring NADPH and cytochromes P-450. The FAD-containing mono-oxygenases will also catalyse -oxidation reactions. [Pg.166]

Figure 15.25 Enzymatic hydroxylation involving NADPH and cytochrome P450. [Pg.1985]

The elaboration of androgen in male rats triggers an increase in microsomal enzyme activity which can be abolished or prevented by castration. However, it should not be inferred that all hepatic microsomal enzymes reach their peak activities concomitant with sexual maturation. Indeed, glucuronyl transferase activity toward p-nitrophenol is maximal in new-bom rats and tends to decline thereafter whereas transferase activi towards bilirubin or phenolphthalein is very low at birth and progressively increases to adult levels. Similarly, NADPH and cytochrome P-4S0-dependent microsomal enzymes have developmental patterns unrelated to each other and to cytochrome P-4S0. For example, aniline hydroxylase in male rats reaches peak activity at 2 weeks of age which is 2 4 weeks prior to sexual maturation, whereas ethylmorphine N-demethylase activity does not become maximal until about 4 5 weeks of age. During the first S weeks of life, these activities increase by about 100% but cytochrome P-4S0 changes only insignificantly. [Pg.606]

Asymmetric oxidation of this sulphide was also catalyzed by two isocytochromes P 450 purified from phenobarbital induced rat liver309. Both P 450 isocytochromes, termed PB-1 and PB-4, when reconstituted with purified rat liver NADPH-cytochrome P 450 reductase and cytochrome b5 afforded ethyl p-tolyl sulphoxide with S-configuration at the sulphur atom. In the case of PB-1 optical purity of this sulphoxide was 58% whereas with PB-4 it was 78%. [Pg.293]

A more detailed study of the biological oxidation of sulphoxides to sulphones has been reported165. In this study cytochrome P-450 was obtained in a purified form from rabbit cells and was found to promote the oxidation of a series of sulphoxides to sulphones by NADPH and oxygen (equation 56). Kinetic measurements showed that the process proceeds by a one-electron transfer to the activated enzymatic intermediate [an oxenoid represented by (FeO)3+] according to equation (57). [Pg.987]

Cytochrome P450s catalyze reactions that introduce one atom of oxygen derived from molecular oxygen into the substrate, yielding a hydroxylated product. NADPH and NADPH-cytochrome P450 reductase are involved in the complex reaction mechanism. [Pg.632]

Hydrocarbon formation involves the removal of one carbon from an acyl-CoA to produce a one carbon shorter hydrocarbon. The mechanism behind this transformation is controversial. It has been suggested that it is either a decarbonylation or a decarboxylation reaction. The decarbonylation reaction involves reduction to an aldehyde intermediate and then decarbonylation to the hydrocarbon and releasing carbon monoxide without the requirement of oxygen or other cofactors [88,89]. In contrast, other work has shown that acyl-CoA is reduced to an aldehyde intermediate and then decarboxylated to the hydrocarbon, releasing carbon dioxide [90]. This reaction requires oxygen and NADPH and is apparently catalyzed by a cytochrome P450 [91]. Whether or not a decarbonylation reaction or a decarboxylation reaction produces hydrocarbons in insects awaits further research on the specific enzymes involved. [Pg.114]

The catalytic activity of CYP enzymes requires functional coupling with its redox partners, cytochrome P450 NADPH oxidoreductase (OR) and cytochrome bs. Measurable levels of these two proteins are natively expressed in most cell lines. Therefore, introduction of only the CYP cDNA is generally needed for detectable catalytic activity. However, the levels of expression of the redox partner proteins may not support maximal CYP catalytic activity, and therefore enhancement of OR levels may be desirable. This approach has been used successfully with an adenovirus expression system in LLC-PKi cells [12],... [Pg.333]

Saito et al. (134) found that the cytosolic nitroreductase activity was due to DT-diaphorase, aldehyde oxidase, xanthine oxidase plus other unidentified nitroreductases. As anticipated, the microsomal reduction of 1-nitropyrene was inhibited by 0 and stimulated by FMN which was attributed to this cofactor acting as an electron shuttle between NADPH-cytochrome P-450 reductase and cytochrome P-450. Carbon monoxide and type II cytochrome P-450 inhibitors decreased the rate of nitroreduction which was consistent with the involvement of cytochrome P-450. Induction of cytochromes P-450 increased rates of 1-aminopyrene formation and nitroreduction was demonstrated in a reconstituted cytochrome P-450 system, with isozyme P-448-IId catalyzing the reduction most efficiently. [Pg.386]

While cytochrome P-450 catalyzes the interaction with substrates, a final step of microsomal enzymatic system, flavoprotein NADPH-cytochrome P-450 reductase catalyzes the electron transfer from NADPH to cytochrome P-450. As is seen from Reaction (1), this enzyme contains one molecule of each of FMN and FAD. It has been suggested [4] that these flavins play different roles in catalysis FAD reacts with NADPH while FMN mediates electron... [Pg.764]

If the mechanism of superoxide production in microsomes by NADPH-cytochrome P-450 reductase, NADH-cytochrome b5 reductase, and cytochrome P-450 is well documented, it cannot be said about microsomal hydroxyl radical production. There are numerous studies, which suggest the formation of hydroxyl radicals in various mitochondrial preparations and by isolated microsomal enzymes. It has been shown that the addition of iron complexes to microsomes stimulated the formation of hydroxyl radicals supposedly via the Fenton... [Pg.766]

LOX-dependent superoxide production was also registered under ex vivo conditions [55]. It has been shown that the intravenous administration of lipopolysaccharide to rats stimulated superoxide production by alveolar and peritoneal macrophages. O Donnell and Azzi [56] proposed that a relatively high rate of superoxide production by cultured human fibroblasts in the presence of NADH was relevant to 15-LOX-catalyzed oxidation of unsaturated acids and was independent of NADPH oxidase, prostaglandin H synthase, xanthine oxidase, and cytochrome P-450 activation or mitochondrial respiration. LOX might also be involved in the superoxide production by epidermal growth factor-stimulated pheochromo-cytoma cells [57]. [Pg.811]

Hexachloroethane is metabolized by the mixed function oxidase system by way of a two-step reduction reaction involving cytochrome P-450 and either reduced nicotinamide adenine dinucleotide phosphate (NADPH) or cytochrome b5 as an electron donor. The first step of the reduction reaction results in the formation of the pentachloroethyl free radical. In the second step, tetrachloroethene is formed as the primary metabolite. Two chloride ions are released. Pentachloroethane is a minor metabolic product that is generated from the pentachloroethyl free radical. [Pg.72]

Servent and colleagues [52] reported that GTN is metabolised in rat liver microsomes by an NADPH-dependent cytochrome P-450 system, yielding GDN, glyceryl mononitrate (GMN) and NO. Moreover, Schroeder and Schroer [53] showed that inhibitors of cytochrome P-450 reduce cGMP stimulation by GTN in kidney epithelial cells. [Pg.37]

The marker enzymes used in this experiment are as follows vanadate-sensitive H+-ATPase (plasma membrane), nitrate-sensitive H+-ATPase or pyrophosphatase (tonoplast), TritonX-100 stimulated-UDPase or IDPase (Golgi complex), antimycin A-insensitive NADPH cytochrome c reductase (ER), and cytochrome c oxidase (mitochondria inner membrane). NADH cytochrome c reductase activity is found to be 10 times higher than NADPH cytochrome c reductase activity. Chlorophyll content can be measured as the chloroplast marker. The chlorophyll content is calculated by the following equation. Before measurement, auto zero is performed at 750 ran. [Pg.164]

See other pages where NADPH and cytochrome is mentioned: [Pg.226]    [Pg.364]    [Pg.91]    [Pg.339]    [Pg.36]    [Pg.291]    [Pg.317]    [Pg.36]    [Pg.157]    [Pg.433]    [Pg.445]    [Pg.54]    [Pg.226]    [Pg.364]    [Pg.91]    [Pg.339]    [Pg.36]    [Pg.291]    [Pg.317]    [Pg.36]    [Pg.157]    [Pg.433]    [Pg.445]    [Pg.54]    [Pg.218]    [Pg.181]    [Pg.42]    [Pg.212]    [Pg.109]    [Pg.155]    [Pg.212]    [Pg.325]    [Pg.145]    [Pg.753]    [Pg.757]    [Pg.765]    [Pg.765]    [Pg.767]    [Pg.863]    [Pg.236]    [Pg.76]    [Pg.184]    [Pg.214]    [Pg.272]   
See also in sourсe #XX -- [ Pg.450 , Pg.657 ]



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