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Kinetic deuterium isotope effects for 7‐alkoxycoumarin O ‐dealkylation reactions catalyzed by human cytochromes P450 and in liver microsomes
Author(s) -
Kim KeonHee,
Isin Emre M.,
Yun ChulHo,
Kim DongHyun,
Guengerich F.
Publication year - 2006
Publication title -
the febs journal
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.981
H-Index - 204
eISSN - 1742-4658
pISSN - 1742-464X
DOI - 10.1111/j.1742-4658.2006.05235.x
Subject(s) - kinetic isotope effect , deuterium , microsome , chemistry , substrate (aquarium) , cytochrome p450 , catalysis , limiting , alkylation , stereochemistry , enzyme , biochemistry , biology , physics , mechanical engineering , engineering , ecology , quantum mechanics
7‐Ethoxy (OEt) coumarin has been used as a model substrate in many cytochrome P450 (P450) studies, including the use of kinetic isotope effects to probe facets of P450 kinetics. P450s 1A2 and 2E1 are known to be the major catalysts of 7‐OEt coumarin O ‐deethylation in human liver microsomes. Human P450 1A2 also catalyzed 3‐hydroxylation of 7‐methoxy (OMe) coumarin at appreciable rates but P450 2E1 did not. Intramolecular kinetic isotope effects were used as estimates of the intrinsic kinetic deuterium isotope effects for both 7‐OMe and 7‐OEt coumarin dealkylation reactions. The apparent intrinsic isotope effect for P450 1A2 (9.4 for O ‐demethylation, 6.1 for O ‐deethylation) showed little attenuation in other competitive and noncompetitive experiments. With P450 2E1, the intrinsic isotope effect (9.6 for O ‐demethylation, 6.1 for O ‐deethylation) was attenuated in the noncompetitive intermolecular experiments. High noncompetitive intermolecular kinetic isotope effects were seen for 7‐OEt coumarin O ‐deethylation in a baculovirus‐based microsomal system and five samples of human liver microsomes (7.3–8.1 for O ‐deethylation), consistent with the view that P450 1A2 is the most efficient P450 catalyzing this reaction in human liver microsomes and indicating that the C‐H bond‐breaking step makes a major contribution to the rate of this P450 (1A2) reaction. Thus, the rate‐limiting step appears to be the chemistry of the breaking of this bond by the activated iron‐oxygen complex, as opposed to steps involved in the generation of the reactive complex. The conclusion about the rate‐limiting step applies to all of the systems studied with this model P450 1A2 reaction including human liver microsomes, the most physiologically relevant.

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