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Oxidase , aerobic

Scheme 5.19 Asymmetric oxidase aerobic coupling reactions utilizing copper-amine complexes, (a) Ligand = (+)-PMP,... Scheme 5.19 Asymmetric oxidase aerobic coupling reactions utilizing copper-amine complexes, (a) Ligand = (+)-PMP,...
The aerobic degradation of nicotine produces an A-methylpyrrolidine as the first metabolite by dehydrogenation. This is then hydroxylated at the benzylic carbon atom by an FAD-containing oxidase (Dai et al. 1968), and the y-A-methylaminobutyrate that is produced by fission of the A-methylpyrolidine ring is demethylated by an oxidase to 4-aminobutyrate (Chiribau et al. 2004). [Pg.132]

Figure 18.2 Summary of respiratory energy flows. Foods ate converted into the reduced form of nicotinamide adenine dinucleotide (NADH), a strong reductant, which is the most reducing of the respiratory electron carriers (donors). Respiration can he based on a variety of terminal oxidants, such as O2, nitrate, or fumarate. Of those, O2 is the strongest, so that aerobic respiration extracts the largest amount of free energy from a given amount of food. In aerobic respiration, NADH is not oxidized directly by O2 rather, the reaction proceeds through intermediate electron carriers, such as the quinone/quinol couple and cytochrome c. The most efficient respiratory pathway is based on oxidation of ferrocytochrome c (Fe ) with O2 catalyzed by cytochrome c oxidase (CcO). Of the 550 mV difference between the standard potentials of c)Tochrome c and O2, CcO converts 450 mV into proton-motive force (see the text for further details). Figure 18.2 Summary of respiratory energy flows. Foods ate converted into the reduced form of nicotinamide adenine dinucleotide (NADH), a strong reductant, which is the most reducing of the respiratory electron carriers (donors). Respiration can he based on a variety of terminal oxidants, such as O2, nitrate, or fumarate. Of those, O2 is the strongest, so that aerobic respiration extracts the largest amount of free energy from a given amount of food. In aerobic respiration, NADH is not oxidized directly by O2 rather, the reaction proceeds through intermediate electron carriers, such as the quinone/quinol couple and cytochrome c. The most efficient respiratory pathway is based on oxidation of ferrocytochrome c (Fe ) with O2 catalyzed by cytochrome c oxidase (CcO). Of the 550 mV difference between the standard potentials of c)Tochrome c and O2, CcO converts 450 mV into proton-motive force (see the text for further details).
Recently, great advancement has been made in the use of air and oxygen as the oxidant for the oxidation of alcohols in aqueous media. Both transition-metal catalysts and organocatalysts have been developed. Complexes of various transition-metals such as cobalt,31 copper [Cu(I) and Cu(II)],32 Fe(III),33 Co/Mn/Br-system,34 Ru(III and IV),35 and V0P04 2H20,36 have been used to catalyze aerobic oxidations of alcohols. Cu(I) complex-based catalytic aerobic oxidations provide a model of copper(I)-containing oxidase in nature.37 Palladium complexes such as water-soluble Pd-bathophenanthroline are selective catalysts for aerobic oxidation of a wide range of alcohols to aldehydes, ketones, and carboxylic acids in a biphasic... [Pg.150]

Some Internal Metallo-Oxidases in Aerobic Prokaryotes... [Pg.259]

Berkeley96 investigated oxidase action in preparations obtained from the crystalline style of the mollusc, Saxidomus giganteus. He demonstrated the aerobic and anaerobic production of D-glucosone by separate systems, each of which comprised a component in the style and another in the diatomaceous food of the mollusc. The osone was identified through the formation of D-glucose m-nitrophenylosazone and by reduction with zinc... [Pg.82]

As mentioned before, the main problem for the application of such oxidizing enzymes in organic synthesis is the availability of an effective reactivation method for the prosthetic groups or the freely dissociated cofactors. Especially, the long-term stability of the whole system is the limiting factor [25]. All oxidases mentioned previously can be reactivated by an aerobic... [Pg.95]


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See also in sourсe #XX -- [ Pg.2 , Pg.3 ]




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