CYP154C8 from Streptomyces sp. has been identified as a new cytochrome P450 with substrate flexibility towards different sets of steroids. In vitro treatment of these steroids with CYP154C8 revealed interesting product formation patterns with the same group of steroids. NMR study revealed the major product of corticosterone to be hydroxylated at the C21 position, whereas progesterone, androstenedione, testosterone, and 11-ketoprogesterone were exclusively hydroxylated at the 16α position. However, the 16α-hydroxylated product of progesterone was further hydroxylated to yield dihydroxylated products. 16-hydroxyprogesterone was hydroxylated at two positions to yield dihydroxylated products: 2α,16α-dihydroxyprogesterone and 6β,16α-dihydroxyprogesterone. To the best of our knowledge, this is the first report of generation of such products through enzymatic hydroxylation by a CYP450. In view of the importance of modified steroids as pharmaceutical components, CYP154C8 has immense potential for utilization in bioproduction of hydroxylated derivative compounds to be directly employed for pharmaceutical applications.
In this study, we investigate the ability of ethanol-inducible CYP2E1 to interact with other cytochrome P450 species and affect the metabolism of their substrates. As a model system, we used CYP2E1-enriched human liver microsomes (HLM) obtained by the incorporation of purified CYP2E1. Using a technique based on homo-FRET in oligomers of CYP2E1 labeled with BODIPY 577/618 maleimide we demonstrated that the interactions of CYP2E1 with HLM result in the formation of its mixed oligomers with other P450 species present in the microsomal membrane. Incorporation of CYP2E1 results in a multifold increase in the rate of metabolism of CYP2E1-specific substrates p-Nitrophenol and Chlorzaxozone. The rate of their oxidation remains proportional to the amount of incorporated CYP2E1 up to the content of 0.3–0.4 nmol/mg protein (or ∼50% CYP2E1 in the P450 pool). The incorporated CYP2E1 becomes a fully functional member of the P450 ensemble and do not exhibit any detectable functional differences with the endogenous CYP2E1. Enrichment of HLM with CYP2E1 results in pronounced changes in the metabolism of 7-ethoxy-4-cyanocoumarin (CEC), the substrate of CYP2C19 and CYP1A2 suggesting an increase in the involvement of the latter in its metabolism. This effect goes together with an augmentation of the rate of dealkylation of CYP1A2-specific substrate 7-ethoxyresorufin. Furthermore, probing the interactions of CYP2E1 with model microsomes containing individual P450 enzymes we found that CYP2E1 efficiently interacts with CYP1A2, but lacks any ability to form complexes with CYP2C19. This finding goes inline with CYP2E1-induced redirection of the main route of CEC metabolism from CYP2C19 to CYP1A2.
CYP154C8 catalyzes the hydroxylation of diverse steroids, as has previously been demonstrated, by using an NADH-dependent system including putidaredoxin and putidaredoxin reductase as redox partner proteins carrying electrons from NADH. In other reactions, CYP154C8 reconstituted with spinach ferredoxin and NADPH-dependent ferredoxin reductase displayed catalytic activity different from that of the NADH-dependent system. The NADPH-dependent system showed multistep oxidation of progesterone and other substrates including androstenedione, testosterone, and nandrolone. (Diacetoxyiodo)benzene was employed to generate compound I (FeO ), actively supporting the redox reactions catalyzed by CYP154C8. In addition to 16α-hydroxylation, progesterone and 11-oxoprogesterone also underwent hydroxylation at the 6β-position in reactions supported by (diacetoxyiodo)benzene. CYP154C8 was active in the presence of high concentrations (>10 mm) of H O , with optimum conversion surprisingly being achieved at ≈75 mm H O . More importantly, H O tolerance by CYP154C8 was evident in the very low heme oxidation rate constant (K) even at high concentrations of H O . Our results demonstrate that alternative redox partners and oxidizing agents influence the catalytic efficiency and product distribution of a cytochrome P450 enzyme. More importantly, these choices affected the type and selectivity of reaction catalyzed by the P450 enzyme.
Bacterial cytochrome P450 (CYP) enzymes are involved in the hydroxylation of various endogenous substrates while using a heme molecule as a cofactor. CYPs have gained biotechnological interest as useful biocatalysts capable of altering chemical structures by adding a hydroxyl group in a regiospecific manner. Here, we identified, purified, and characterized two CYP154C4 proteins from Streptomyces sp. W2061 (StCYP154C4‐1) and Streptomyces sp. ATCC 11861 (StCYP154C4‐2). Activity assays showed that both StCYP154C4‐1 and StCYP154C4‐2 can produce 2′‐hydroxylated testosterone, which differs from the activity of a previously described NfCYP154C5 from Nocardia farcinica in terms of its 16α‐hydroxylation of testosterone. To better understand the molecular basis of the regioselectivity of these two CYP154C4 proteins, crystal structures of the ligand‐unbound form of StCYP154C4‐1 and the testosterone‐bound form of StCYP154C4‐2 were determined. Comparison with the previously determined NfCYP154C5 structure revealed differences in the substrate‐binding residues, suggesting a likely explanation for the different patterns of testosterone hydroxylation, despite the high sequence similarities between the enzymes (54% identity). These findings provide valuable insights that will enable protein engineering for the development of artificial steroid‐related CYPs exhibiting different regiospecificity.
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