Progress towards the easier use of P450 enzymes

Discovery of 2-naphthoic acid monooxygenases by genome mining and their use as biocatalysts

The large pool of cytochrome P450 (P450) open-reading frames identified in genome sequences has attracted much attention as a resource for new oxidation biocatalysts. P450 genes were cloned from genome-sequenced bacteria and coexpressed with putidaredoxin and its reductase genes to provide the redox partners of P450 in Escherichia coli. Whole-cell assays were performed with 2-naphthoic acid as a substrate. Hydroxylated naphthoic acid products were rapidly detected with two reagents showing different colors in the presence of the products. Two P450s, CYP199A1 and CYP199A2, were found to hydroxylate the substrate to 7- and 8-hydroxy-2-naphthoic acids. The CYP199A1 whole-cell biocatalyst converted 1 mM 2-naphthoic acid to 0.27 mM 7-hydroxy-2-naphthoic acid and 0.53 mM 8-hydroxy-2-naphthoic acid. CYP199A2 exhibited similar regioselectivity to CYP199A1. Furthermore, we found that 8-hydroxy-2-naphthoic acid emits near-white fluorescence when exposed to UV light. These P450s will provide a facile and environmentally friendly synthetic approach to the hydroxynaphthoic acids.

Screening for cytochrome p450 reactivity by harnessing catalase as reporter enzyme

Cytochrome P450 enzymes are known to catalyze a variety of reactions that are difficult to perform by standard organic synthesis, such as the oxidation of unactivated C--C bonds. Cytochrome P450 enzymes can also be used in artificial systems in which organic peroxides act as cosubstrates. To find substrates that are converted by a certain P450 catalyst in the presence of an organic peroxide, various screening assays have been established, however, most of them are limited to one or only a few specific substrates. Here, we report a simple and rapid screening assay that works independently of the nature of the substrate and utilizes a previously undescribed reactivity of catalase as reporter enzyme. In an initial demonstration of this assay, we screened 180 enzyme/peroxide/substrate combinations for potential bioconversions. As shown by subsequent verification of the screening results with liquid chromatography/multistage mass spectrometry (LC/MS(n)), we were able to identify three new substrates for the enzyme CYP152A1 and at least two previously undescribed conversions by the enzyme CYP119.

Molecular evolution of a steroid hydroxylating cytochrome P450 using a versatile steroid detection system for screening

Molecular evolution is a powerful tool for improving or changing activities of enzymes for their use in biotechnological processes. Cytochromes P450 are highly interesting enzymes for biotechnological purposes because they are able to hydroxylate a broad variety of substrates with high regio- and stereoselectivity. One promising steroid hydroxylating cytochrome P450 for biotechnological applications is CYP106A2 from Bacillus megaterium ATCC 13368. It is one of a few known bacterial cytochromes P450 able to transform steroids such as progesterone and 11-deoxycortisol. CYP106A2 can be easily expressed in Escherichia coli with a high yield and can be reconstituted using the adrenal redox proteins, adrenodoxin and adrenodoxin reductase. We developed a simple screening assay for this system and performed random mutagenesis of CYP106A2, yielding variants with improved 11-deoxycortisol and progesterone hydroxylation activity. After two generations of directed evolution, we were able to improve the k (cat)/K (m) of the 11-deoxycortisol hydroxylation by a factor of more than four. At the same time progesterone conversion was improved about 1.4-fold. Mapping the mutations identified in catalytically improved CYP106A2 variants into the structure of a CYP106A2 model suggests that these mutations influence the mobility of the F/G loop, and the interaction with the redox partner adrenodoxin. The results show the evolution of a soluble steroid hydroxylase as a potential new catalyst for the production of steroidogenic compounds.

Characterization of the peroxidase activity of CYP119, a thermostable P450 from Sulfolobus acidocaldarius

We report the cloning, expression, and purification of CYP119, a thermostable enzyme previously thought to derive from Sulfolobus solfataricus. Sequence analysis suggested that, in contrast to the conclusions of earlier studies, the enzyme stems from the closely related Sulfolobus acidocaldarius, and we were indeed able to clone the gene from the genomic DNA of this organism. For the first time, we report here on the peroxidase activity of this enzyme and the optimization of the associated reaction parameters. The optimized reaction conditions were then applied to the biocatalytic epoxidation of styrene. The values obtained for k(cat) (78.2+/-20.6 min(-1)) and K(M) (9.2+/-4.3 mM) indicated an approximately 100-fold increased catalytic activity over previously reported results.

Cytochrome P450/redox partner fusion enzymes: biotechnological and toxicological prospects

Cytochromes P450 (CYPs) are versatile oxidase catalysts that play pivotal roles in drug metabolism. They are highly regarded as biotechnological tools for their capacity to perform regio- and stereo-selective oxidations. Human CYPs source electrons for oxygen activation from one or more separate redox partner enzymes. However, several CYP enzymes are now known in which the CYP is covalently linked to a reductase system. Some of these systems offer distinct advantages over typical CYPs as efficient, self-contained units capable of important biotransformations, including synthesis of high value chemicals and pharmaceuticals. Protein engineering has been widely applied to produce variant CYP fusions with desirable activities. The review focuses on the nature and diversity of CYP/redox partner fusion enzymes and their biocatalytic potential.

Activity of human P450 2D6 in biphasic solvent systems

Several limitations have restricted the use of P450 enzymes in synthesis, including the narrow substrate specificity of some P450 isoforms, the need for a redox partner and an expensive cofactor, incompatibility with organic solvents, and poor stability. We previously demonstrated that the natural redox partner and cofactor of the promiscuous P450s 3A4 and 2D6 can be efficiently substituted with some cheap hydrogen peroxide donors or organic peroxides. We report here that P450 2D6 maintains as much as 76% of its activity when used in buffer/organic emulsions. Product formation in biphasic solvent systems is comparable whether the natural redox partner and cofactor are used, or a surrogate. As reported for other enzymes, a correlation is observed between the logP and the suitability of a solvent for enzymatic activity. Moreover, the utility of our system was established by demonstrating the transformation of a novel hydrophobic substrate, not modified by P450 2D6 in the absence of organic solvent.

CYP3A4 Activity in the Presence of Organic Cosolvents, Ionic Liquids, or Water-Immiscible Organic Solvents

P450 enzymes have attracted the attention of chemists for decades because of their impressive ability to catalyze the hydroxylation of inactivated C--H bonds. However, their use for synthesis in aqueous systems is limited. We report here a survey of the activity of purified human CYP3A4 in the presence of organic solvents or ionic liquids. We show that CYP3A4 tolerates only small amounts (<15 %) of water-miscible organic cosolvents or ionic liquids before its activity toward testosterone drops below detection. [BMIM][PF(6)] in a biphasic system was less detrimental to enzyme activity, with 20 % of the activity remaining in the presence of 15 % of this ionic liquid. CYP3A4 activity in the absence of buffer was only >or=10 % in solvents of the alkane series, with a minimum of 0.85 % water, and with the addition of sucrose and testosterone before enzyme lyophilization. Biphasic solvent systems were more promising, with approximately 85 % of the activity retained.

Sugar-mediated lyoprotection of purified human CYP3A4 and CYP2D6

P450 enzymes are of great interest for drug metabolism and as potential biocatalysts. Like most P450s, purified CYP3A4 is normally handled and stored in solution because lyophilization greatly reduces its activity. We show here that colyophilization of this enzyme with sucrose or trehalose, but not mannitol, crown ethers or cyclodextrins, allow recovery of full enzymatic activity after rehydration. Sorbitol was almost as efficient, with 85% retention of the original activity. We also show that similar protection is observed through colyophilization of CYP2D6 with trehalose. This procedure should greatly facilitate handling, storage, or use of these enzymes in anhydrous media.

Evaluation of cytochrome P450BSβ reactivity against polycyclic aromatic hydrocarbons and drugs

The oxidation of 10 polycyclic aromatic hydrocarbons (PAH) by cytochrome P450(BSbeta) using three different electron acceptors is reported. Three PAH were found to be substrates for the oxidation by P450(BSbeta), namely anthracene, 9-methyl-anthracene and azulene. The respective oxidation products were identified by reversed-phase high-performance liquid chromatography coupled to electrospray ionization-mass spectrometry. In addition, 10 drug-like compounds were investigated for their effects on the catalytic activity of P450(BSbeta) by carrying out inhibition studies. The stability of P450(BSbeta) against hydrogen peroxide, cumene, and ter-butyl hydroperoxide was determined. Overall, the results of this study suggested that the P450(BSbeta) enzyme represents a powerful catalyst in terms of the catalytic activity and operational stability.