Abstract
Testosterone 6beta-hydroxylation is a prototypic reaction of cytochrome P450 (P450) 3A4, the major human P450. Biomimetic reactions produced a variety of testosterone oxidation products with 6beta-hydroxylation being only a minor reaction, indicating that P450 3A4 has considerable control over the course of steroid hydroxylation because 6beta-hydroxylation is not dominant in a thermodynamically controlled oxidation of the substrate. Several isotopically labeled testosterone substrates were prepared and used to probe the catalytic mechanism of P450 3A4: (i) 2,2,4,6,6-(2)H(5); (ii) 6,6-(2)H(2); (iii) 6alpha-(2)H; (iv) 6beta-(2)H; and (v) 6beta-(3)H testosterone. Only the 6beta-hydrogen was removed by P450 3A4 and not the 6alpha, indicating that P450 3A4 abstracts hydrogen and rebounds oxygen only at the beta face. Analysis of the rates of hydroxylation of 6beta-(1)H-, 6beta-(2)H-, and 6beta-(3)H-labeled testosterone and application of the Northrop method yielded an apparent intrinsic kinetic deuterium isotope effect ((D)k) of 15. The deuterium isotope effects on k(cat) and k(cat)/K(m) in non-competitive reactions were only 2-3. Some "switching" to other hydroxylations occurred because of 6beta-(2)H substitution. The high (D)k value is consistent with an initial hydrogen atom abstraction reaction. Attenuation of the high (D)k in the non-competitive experiments implies that C-H bond breaking is not a dominant rate-limiting step. Considerable attenuation of a high (D)k value was also seen with a slower P450 3A4 reaction, the O-dealkylation of 7-benzyloxyquinoline. Thus P450 3A4 is an enzyme with regioselective flexibility but also considerable regioselectivity and stereoselectivity in product formation, not necessarily dominated by the ease of C-H bond breaking.
Highlights
P4501 enzymes are found in organisms from Archebacter to humans and catalyze oxidations of a great variety of chemicals
Many of the expressed kinetic isotope effects cited in the literature are low and there has been a tendency to regard C–H bond breaking as generally being relatively rapid, our own work (40 – 45) has shown relatively high expressed kinetic isotope effects for several reactions catalyzed by mammalian P450 enzymes
The results provide a view of this enzyme that differs from some current conceptions regarding P450 3A4 selectivity and the nature of rate-limiting steps in the catalytic cycle
Summary
P450, cytochrome P450; MS, mass [1, 2]. The human P450s are the major enzymes involved in the clearance of drugs, and P450 3A4, the most abundant P450 in liver and small intestine, is involved in the oxidation of one-half of the drugs used today [3, 4]. Little information is available regarding what step is rate-limiting in P450 3A4 reactions. Kinetic isotope effect studies have been used with P450 reactions for Ͼ30 years (29 –33). In principle, such experiments can sense the degree to which step 7 is rate-limiting (Scheme 1). Reports of kinetic isotope effect studies with P450 3A4 reacspectrometry; HPLC, high pressure liquid chromatography; APCI, atmospheric pressure chemical ionization; LC, liquid chromatography; HRMS, high resolution mass spectra; FAB, fast atom bombardment; NBA, 3-nitrobenzoic acid; MeOH, methanol; EtOAc, ethyl acetate; THF, tetrahydrofuran; MS, mass spectrometry. The results provide a view of this enzyme that differs from some current conceptions regarding P450 3A4 selectivity and the nature of rate-limiting steps in the catalytic cycle
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