Replacement of Thr-303 of P450 2E1 with Serine Modifies the Regioselectivity of Its Fatty Acid Hydroxylase Activity

Abstract

Threonine-303 of rabbit P450 2E1, ³ which is putatively located at the distal heme surface, was replaced by serine and valine via site-directed mutagenesis. In the oxidized state, the Ser-mutated P450 exhibited a low- and high-spin mixed-type (low⟩high) absorption spectrum, whereas the Val-mutated P450, like the wild-type P450, exhibited a nearly high-spin type spectrum. The reduced CO complexes of the Ser- and Val-mutated P450s, as well as that of the wild-type P450, showed a Soret absorption maximum at 452 nm. Both mutated P450s were active in the hydroxylation of C₁₀ to C₁₈ fatty acids at somewhat lower rates than the wild-type P450. The Val-mutated P450 gave the same two products (the major one is probably the ω-1 hydroxy analog) as the wild-type P450, while additional products were formed on incubation with C₁₁ to C₁₇ fatty acids as substrates of the Ser-mutated P450; a total of four products was detected for each of the C₁₂ to C₁₅ fatty acids, and three for each of the C₁₁, C₁₆, and C₁₇ homologues. The metabolites of laurate were determined by GC-MS analysis to be the ω-1, ω-2, ω-3, and ω-4 hydroxy counterparts. The Ser-mutated P450 hydroxylated drug substrates at almost the same rates as the wild-type P450, while the mutation to valine significantly lowered the drug hydroxylase activities. These findings indicate that Thr-303 of P450 2E1 plays an important role in determining its substrate specificity (hydroxylation position), probably by fixing the fatty acid substrate at the proper position on the P450 protein through the interaction between the γ-methyl group of Thr-303 and the side chain of the fatty acid.