Construction of a thermostable cytochrome P450 chimera derived from self-sufficient mesophilic parents

The P450 monooxygenases CYP102A1 from Bacillus megaterium and CYP102A3 from Bacillus subtilis are fusion flavocytochromes comprising of a P450 heme domain and a FAD/FMN reductase domain. This protein organization is responsible for the extraordinary catalytic activities making both monooxygenases promising enzymes for biocatalysis. CYP102A1 and CYP102A3 are fatty acid hydroxylases that share 65% identity, and their mutants are able to oxidize a wide range of substrates. In an attempt to increase the process stability of CYP102A1, we exchanged the more unstable reductase domain of CYP102A1 with the more stable reductase domain of CYP102A3. Stability of the chimeric fusion protein was determined spectrophotometrically as well as by measuring the hydroxylation activity towards 12-para-nitrophenoxydodecanoic acid (12-pNCA) after incubation at elevated temperatures. In the reaction with 12-pNCA, the new chimeric protein exhibited 88 and 38% of the activity of CYP102A3 and CYP102A1, respectively, but was able to hydroxylate substrates within a wider temperature range compared with the parental enzymes. Maximum activity was obtained at 51°C, and the half-life at 50°C was with 100 min more than ten times longer than that of CYP102A1 (8 min).     

Cloning,expression and characterisation of CYP102A7, a self-sufficient P450 monooxygenase from <Emphasis Type="Italic">Bacillus licheniformis</Emphasis>

Cytochrome P450 monooxygenases of the CYP102A subfamily are single-component natural fusion proteins consisting of a heme domain and a diflavin reductase. The characterised CYP102A enzymes are fatty acid hydroxylases with turnover rates of several thousands per minute. In search of new P450s with similar activities, but with a broader substrate spectrum, we cloned, expressed and characterised CYP102A7 from Bacillus licheniformis. As expected, CYP102A7 was active towards medium-chain fatty acids but showed a strong preference for saturated over unsaturated fatty acids, which could not be observed for either of the CYP102A members so far. Besides fatty acids, CYP102A7 was able to catalyse the oxidation of cyclic and acyclic terpenes with high activity and coupling efficiency. For example, (R)-(+)-limonene was converted with activity of 220 nmol nmol P450(-1) min(-1) and 80% coupling. Unusual for enzymes of the CYP102A subfamily was the deethylation activity of CYP102A7 towards 7-ethoxycoumarin. Furthermore, this monooxygenase, though having a moderate thermal stability, exhibited 50% of its initial activity in the presence of 26% DMSO. Comparison of the homology models of CYP102A7 and other members of the CYP102A subfamily revealed distinct differences in the shape of the substrate access channel and the active site, which might explain differences in catalytic properties of these homologous enzymes.     

Cloning, expression and characterization of a fast self-sufficient P450: CYP102A5 from Bacillus cereus

CYP102s represent a family of natural self-sufficient fusions of cytochrome P450 and cytochrome P450 reductase found in some bacteria. One member of this family, named CYP102A1 or more traditionally P450BM-3, has been widely studied as a model of human P450 cytochromes. Remarkable detail of P450 structure and function has been revealed using this highly efficient enzyme. The recent rapid expansion of microbial genome sequences has revealed many relatives of CYP102A1, but to date only two from Bacillus subtilis have been characterized. We report here the cloning and expression of CYP102A5, a new member of this family that is very closely related to CYP102A4 from Bacillus anthracis. Characterization of the substrate specificity of CYP102A5 shows that it, like the other CYP102s, will metabolize saturated and unsaturated fatty acids as well as N-acylamino acids. CYP102A5 catalyzes very fast substrate oxidation, showing one of the highest turnover rates for any P450 monooxygenase studied so far. It does so with more specificity than other CYP102s, yielding primarily ω-1 and ω-2 hydroxylated products. Measurement of the rate of electron transfer through the reductase domain reveals that it is significantly faster in CYP102A5 than in CYP102A1, providing a likely explanation for the increased monooxygenation rate. The availability of this new, very fast fusion P450 will provide a great tool for comparative structure-function studies between CYP102A5 and the other characterized CYP102s.     

Substrate specificity of native and mutated cytochrome P450 (CYP102A3) from Bacillus subtilis

Within the Bacillus subtilis genome sequencing project, two monooxygenases (CYP102A2 and CYP102A3) were discovered which revealed a similarity of 76% to the well-known cytochrome P450 BM-3 (CYP102A1) of Bacillus megaterium. All enzymes are natural fusion proteins consisting of a heme domain and a reductase domain. We here report the cloning, expression and characterization of B. subtilis enzyme CYP102A3. The substrate specificity of this enzyme is similar to that of B. megaterium CYP102A1, which hydroxylates medium-chain fatty acids in subterminal positions. A double mutant was prepared that hydroxylates a number of other substrates, which do not bear any resemblance to the natural substrate of this enzyme family.     

The bacterial P450 BM3: a prototype for a biocatalyst with human P450 activities

The use of cytochrome P450 (P450 or CYP) enzymes as biocatalysts for the production of fine chemicals, including pharmaceuticals, has been of increasing interest, primarily owing to their catalytic diversity and broad substrate range. CYP102A1 (P450 BM3) from Bacillus megaterium integrates an entire monooxygenase system into one polypeptide and represents an appropriate prokaryotic model for industrial applications of mammalian P450 activities. CYP102A1 not only exhibits the highest catalytic activity ever detected in a P450 monooxygenase but also provides a potentially versatile biocatalyst for the production of human P450 metabolites. CYP102A1 can be further engineered to be a drug-metabolizing enzyme, making it a promising candidate to use as a biocatalyst in drug discovery and synthesis.     

Arabidopsis CYP72C1 is an atypical cytochrome P450 that inactivates brassinosteroids

Cytochrome P450 monooxygenases (P450s) are a diverse family of proteins that have specialized roles in secondary metabolism and in normal cell development. Two P450s in particular, CYP734A1 and CYP72C1, have been identified as brassinosteroid-inactivating enzymes important for steroid-mediated signal transduction in Arabidopsis thaliana. Genetic analyses have demonstrated that these P450s modulate growth throughout plant development. While members of the CYP734A subfamily inactivate brassinosteroids through C-26 hydroxylation, the biochemical activity of CYP72C1 is unknown. Because CYP734A1 and CYP72C1 in Arabidopsis diverge more than brassinosteroid inactivating P450s in other plants, this study examines the structure and biochemistry of each enzyme. Three-dimensional models were generated to examine the substrate binding site structures and determine how they might affect the function of each P450. These models have indicated that the active site of CYP72C1 does not contain several conserved amino acids typically needed for substrate hydroxylation. Heterologous expression of these P450s followed by substrate binding analyses have indicated that CYP734A1 binds active brassinosteroids, brassinolide and castasterone, as well as their upstream precursors whereas CYP72C1 binds precursors more effectively. Seedling growth assays have demonstrated that the genetic state of CYP734A1, but not CYP72C1, affected responsiveness to high levels of exogenous brassinolide supporting our observations that CYP72C1 acts on brassinolide precursors. Although there may be some overlap in their physiological function, the distinct biochemical functions of these proteins in Arabidopsis has significant potential to fine-tune the levels of different brassinosteroid hormones throughout plant growth and development.     

Cytochrome P450 Monooxygenase CYP53 Family in Fungi: Comparative Structural and Evolutionary Analysis and Its Role as a Common Alternative Anti-Fungal Drug Target

Cytochrome P450 monooxygenases (CYPs/P450s) are heme-thiolate proteins whose role as a drug target against pathogenic microbes has been explored because of their stereo- and regio-specific oxidation activity. We aimed to assess the CYP53 family''s role as a common alternative drug target against animal (including human) and plant pathogenic fungi and its role in fungal-mediated wood degradation. Genome-wide analysis of fungal species revealed the presence of CYP53 members in ascomycetes and basidiomycetes. Basidiomycetes had a higher number of CYP53 members in their genomes than ascomycetes. Only two CYP53 subfamilies were found in ascomycetes and six subfamilies in basidiomycetes, suggesting that during the divergence of phyla ascomycetes lost CYP53 P450s. According to phylogenetic and gene-structure analysis, enrichment of CYP53 P450s in basidiomycetes occurred due to the extensive duplication of CYP53 P450s in their genomes. Numerous amino acids (103) were found to be conserved in the ascomycetes CYP53 P450s, against only seven in basidiomycetes CYP53 P450s. 3D-modelling and active-site cavity mapping data revealed that the ascomycetes CYP53 P450s have a highly conserved protein structure whereby 78% amino acids in the active-site cavity were found to be conserved. Because of this rigid nature of ascomycetes CYP53 P450s'' active site cavity, any inhibitor directed against this P450 family can serve as a common anti-fungal drug target, particularly toward pathogenic ascomycetes. The dynamic nature of basidiomycetes CYP53 P450s at a gene and protein level indicates that these P450s are destined to acquire novel functions. Functional analysis of CYP53 P450s strongly supported our hypothesis that the ascomycetes CYP53 P450s ability is limited for detoxification of toxic molecules, whereas basidiomycetes CYP53 P450s play an additional role, i.e. involvement in degradation of wood and its derived components. This study is the first report on genome-wide comparative structural (gene and protein structure-level) and evolutionary analysis of a fungal P450 family.     

Sequence-based screening for self-sufficient P450 monooxygenase from a metagenome library

AIMS: Cytochrome P450 monooxygenases (CYPs) are useful catalysts for oxidation reactions. Self-sufficient CYPs harbour a reductive domain covalently connected to a P450 domain and are known for their robust catalytic activity with great potential as biocatalysts. In an effort to expand genetic sources of self-sufficient CYPs, we devised a sequence-based screening system to identify them in a soil metagenome. METHODS AND RESULTS: We constructed a soil metagenome library and performed sequence-based screening for self-sufficient CYP genes. A new CYP gene, syk181, was identified from the metagenome library. Phylogenetic analysis revealed that SYK181 formed a distinct phylogenic line with 46% amino-acid-sequence identity to CYP102A1 which has been extensively studied as a fatty acid hydroxylase. The heterologously expressed SYK181 showed significant hydroxylase activity towards naphthalene and phenanthrene as well as towards fatty acids. CONCLUSIONS: Sequence-based screening of metagenome libraries is expected to be a useful approach for searching self-sufficient CYP genes. The translated product of syk181 shows self-sufficient hydroxylase activity towards fatty acids and aromatic compounds. SIGNIFICANCE AND IMPACT OF THE STUDY: SYK181 is the first self-sufficient CYP obtained directly from a metagenome library. The genetic and biochemical information on SYK181 are expected to be helpful for engineering self-sufficient CYPs with broader catalytic activities towards various substrates, which would be useful for bioconversion of natural products and biodegradation of organic chemicals.     

Oxidation of human cytochrome P450 1A2 substrates by Bacillus megaterium cytochrome P450 BM3

Cytochrome P450 enzymes (P450s or CYPs) are good candidates for biocatalysis in the production of fine chemicals, including pharmaceuticals. Despite the potential use of mammalian P450s in various fields of biotechnology, these enzymes are not suitable as biocatalysts due to their low stability, low catalytic activity, and limited availability. Recently, wild-type and mutant forms of bacterial P450 BM3 (CYP102A1) from Bacillus megaterium have been found to metabolize various. It has therefore been suggested that CYP102A1 may be used to generate the metabolites of drugs and drug candidates. In this report, we show that the oxidation reactions of typical human CYP1A2 substrates (phenacetin, ethoxyresorufin, and methoxyresorufin) are catalyzed by both wild-type and mutant forms of CYP102A1. In the case of phenacetin, CYP102A1 enzymes show only O-deethylation product, even though two major products are produced as a result of O-deethylation and 3-hydroxylation reactions by human CYP1A2. Formation of the metabolites was confirmed by HPLC analysis and LC–MS to compare the metabolites with the actual biological metabolites produced by human CYP1A2. The results demonstrate that CYP102A1 mutants can be used for cost-effective and scalable production of human CYP1A2 drug metabolites. Our computational findings suggest that a conformational change in the cavity size of the active sites of the mutants is dependent on activity change. The modeling results further suggest that the activity change results from the movement of several specific residues in the active sites of the mutants.     

Metabolism of linear and angular furanocoumarins by Papilio polyxenes CYP6B1 co-expressed with NADPH cytochrome P450 reductase

One challenge in the heterologous expression of microsomal cytochrome P450 monooxygenases (P450s) is fulfilling their obligatory requirement for electrons transferred from NADPH P450 reductase. We have established co-expression parameters for Papilio polyxenes CYP6B1 and house fly P450 reductase in baculovirus-infected Sf9 cells that allow for efficient expression of both components and significantly enhance metabolic turnover of this insect P450's substrates. These expression conditions have allowed us to reexamine the turnover capacities of CYP6B1 toward linear and angular furanocoumarins present in the host plants for the specialist caterpillar P. polyxenes. Coexpression of CYP6B1 and P450 reductase at equivalent viral concentrations [MOI (multiplicity of infection) ratio of 1] results in turnover rates for the linear furanocoumarins xanthotoxin and psoralen, which are increased 32-33 fold over the turnover rates obtained with CYP6B1 expressed alone. The turnover rate for the angular furanocoumarin angelicin is also significantly increased to 4.76 nmol/min/nmol P450 compared to its barely detectable level obtained with CYP6B1 expressed alone. Substrate binding analyses indicate that all three of these compounds elicit typical type I binding spectra but with varying magnitudes and affinities that are indicative of each substrate's effectiveness at coordinating with the heme iron. The relative proportions of high spin state generated with these substrates are consistent with CYP6B1 metabolizing these furanocoumarins in the rank order xanthotoxin>psoralen>angelicin. These differential activities for CYP6B1 suggest that it may have been an ancient participant in the coevolutionary arms race between papilionid butterflies and their apiaceous host plants. Due to its ability to handle a range of furanocoumarin structures, CYP6B1 may have contributed to P. polyxenes' early colonization of linear furanocoumarin-containing plants and to its subsequent colonization of angular furanocoumarin-containing plants.     

Identification of universal selectivity‐determining positions in cytochrome P450 monooxygenases by systematic sequence‐based literature mining

Cytochrome P450 monooxygenases (CYPs) are a large, highly diverse protein family with a common fold. The sequences, structures, and functions of CYPs have been extensively studied resulting in more than 53,000 scientific articles. A sequence‐based literature mining algorithm was designed to systematically analyze this wealth of information on SNPs, designed mutations, structural interactions, or functional roles of individual residues. Structurally corresponding positions in different CYPs were compared and universal selectivity‐determining positions were identified. Based on the Cytochrome P450 Engineering Database ( www.CYPED.BioCatNet.de ) and a standard numbering scheme for all CYPs, 4000 residues in 168 CYPs mentioned in 2400 articles could be assigned to 440 structurally corresponding standard positions of the CYP fold, covering 96% of all standard positions. Seventeen individual standard positions were mentioned in the context of more than 32 different CYPs. The majority of these most frequently mentioned positions are located on the six substrate recognition sites and are involved in control of selectivity, such as the well‐studied position 87 in CYP102A1 (P450_BM‐3) which was mentioned in the articles on 63 different CYPs. The recurrent citation of the 17 frequently mentioned positions for different CYPs suggests their universal functional relevance. Proteins 2015; 83:1593–1603. © 2015 Wiley Periodicals, Inc.     

Expression, purification, and characterization of Bacillus subtilis cytochromes P450 CYP102A2 and CYP102A3: flavocytochrome homologues of P450 BM3 from Bacillus megaterium

The cyp102A2 and cyp102A3 genes encoding the two Bacillus subtilis homologues (CYP102A2 and CYP102A3) of flavocytochrome P450 BM3 (CYP102A1) from Bacillus megaterium have been cloned, expressed in Escherichia coli, purified, and characterized spectroscopically and enzymologically. Both enzymes contain heme, flavin adenine dinucleotide (FAD) and flavin mononucleotide (FMN) cofactors and bind a variety of fatty acid molecules, as demonstrated by conversion of the low-spin resting form of the heme iron to the high-spin form induced by substrate-binding. CYP102A2 and CYP102A3 catalyze the fatty acid-dependent oxidation of reduced nicotinamide adenine dinucleotide phosphate (NADPH) and reduction of artificial electron acceptors at high rates. Binding of carbon monoxide to the reduced forms of both enzymes results in the shift of the heme Soret band to 450 nm, confirming the P450 nature of the enzymes. Reverse-phase high-performance liquid chromatography (HPLC) of products from the reaction of the enzymes with myristic acid demonstrates that both catalyze the subterminal hydroxylation of this substrate, though with different regioselectivity and catalytic rate. Both P450s 102A2 and 102A3 show kinetic and binding preferences for long-chain unsaturated and branched-chain fatty acids over saturated fatty acids, indicating that the former two molecule types may be the true substrates. P450s 102A2 and 102A3 exhibit differing substrate selectivity profiles from each other and from P450 BM3, indicating that they may fulfill subtly different cellular roles. Titration curves for binding and turnover kinetics of several fatty acid substrates with P450s 102A2 and 102A3 are better described by sigmoidal (rather than hyperbolic) functions, suggesting binding of more than one molecule of substrate to the P450s, or possibly cooperativity in substrate binding. Comparison of the amino acid sequences of the three flavocytochromes shows that several important amino acids in P450 BM3 are not conserved in the B. subtilis homologues, pointing to differences in the binding modes for the substrates that may explain the unusual sigmoidal kinetic and titration properties.     

Cloning,expression in yeast,and functional characterization of CYP71D14, a root-specific cytochrome P450 from <Emphasis Type="Italic">Petunia hybrida</Emphasis>

Alkaloids, which are naturally occurring amines, are biosynthesized and accumulated in plant tissues such as roots, leaves, and stems. Many alkaloids have pharmacological effects on humans and animals. Cytochrome P450 (P450 or CYP) monooxygenases are known to play key roles in the biosynthesis of alkaloids in higher plants. A cDNA clone encoding a P450 protein consisting of 502 amino acids was isolated from Petunia hybrida. The deduced amino acid sequence of the cDNA clone showed a high level of similarity with the other P450 species in the CYP71D family; hence, this novel P450 was named CYP71D14. Among plant P450 species, CYP71D14 had 45.7% similarity in its amino acid sequence to CYP71D12, which is involved in the biosynthesis of the indole alkaloids vinblastine and vincristine. Expression of CYP71D14 mRNA in Petunia plants was examined by Northern blot analysis by using a full-length cDNA of CYP71D14 as a probe. CYP71D14 mRNA was expressed most abundantly in the roots. The nucleotide sequence of CYP71D14 has been submitted to the DDBJ, EMBL, and GenBank nucleotide databases under the accession number AB028462. An erratum to this article can be found at     

Conversion and synthesis of chemicals catalyzed by fungal cytochrome P450 monooxygenases: A review

Cytochrome P450s (also called CYPs or P450s) are a superfamily of heme-containing monooxygenases. They are distributed in all biological kingdoms. Most fungi have at least two P450-encoding genes, CYP51 and CYP61, which are housekeeping genes that play important roles in the synthesis of sterols. However, the kingdom fungi is an interesting source of numerous P450s. Here, we review reports on fungal P450s and their applications in the bioconversion and biosynthesis of chemicals. We highlight their history, availability, and versatility. We describe their involvement in hydroxylation, dealkylation, oxygenation, C═C epoxidation, C–C cleavage, C–C ring formation and expansion, C–C ring contraction, and uncommon reactions in bioconversion and/or biosynthesis pathways. The ability of P450s to catalyze these reactions makes them promising enzymes for many applications. Thus, we also discuss future prospects in this field. We hope that this review will stimulate further study and exploitation of fungal P450s for specific reactions and applications.     

Transgenic rice plants expressing human p450 genes involved in xenobiotic metabolism for phytoremediation

Phytoremediation is the use of plants to remove xenobiotic compounds from the environment. Plants have the inherent ability to detoxify xenobiotic pollutants, but they are generally poor at degrading them. The introduction of genes involved in xenobiotic degradation is aimed at enhancing plants' potential further. Rice (Oryza sativa) is a good candidate for this purpose and has been transformed with genes encoding cytochrome P450 monooxygenases CYP1A1, CYP2B6, and CYP2C19. The transgenic plants were more tolerant to various herbicides than nontransgenic Nipponbare rice plants, owing to enhanced metabolism by the introduced P450 enzymes. Transgenic plants were able to remove atrazine and metolachlor from soil. Field testing and risk assessment are very important for developing transgenic plants for phytoremediation. Transgenic rice plants should become useful as herbicide-tolerant crops and for phytoremediation of xenobiotic pollutants in future.     

CYP6B1 and CYP6B3 of the black swallowtail (Papilio polyxenes): adaptive evolution through subfunctionalization

Gene duplication provides essential material for functional divergence of proteins and hence allows organisms to adapt to changing environments. Following duplication events, redundant paralogs may undergo different evolutionary paths via processes known as nonfunctionalization, neofunctionalization, or subfunctionalization. Studies of adaptive evolution at the molecular level have progressed rapidly by computationally analyzing nucleotide substitution patterns but such studies are limited by the absence of information relating to alterations of function of the encoded enzymes. In this respect, evolution of the Papilio polyxenes cytochrome P450 monooxygenases (P450s) responsible for the adaptation of this insect to furanocoumarin-containing host plants provides an excellent model for elucidating the evolutionary fate of duplicated genes. Evidence from sequence and functional analysis in combination with molecular modeling indicates that the paralogous CYP6B1 and CYP6B3 genes in P. polyxenes have probably evolved via subfunctionalization after the duplication event by which they arose. Both enzymes have been under independent purifying selection as evidenced by the low dN/dS ratio in both the coding region and substrate recognition sites. Both enzymes have maintained their ability to metabolize linear and angular furanocoumarins albeit at different efficiencies. Comparisons of molecular models developed for the CYP6B3 and CYP6B1 proteins highlight differences in their binding modes that account for their different activities toward linear and angular furanocoumarins. That P. polyxenes maintains these 2 furanocoumarin-metabolizing loci with somewhat different activities and expression patterns provides this species with the potential to acquire P450s with novel functions while maintaining those most critical to its exclusive feeding on its current range of host plants.     

Molecular docking of substrates and inhibitors in the catalytic site of CYP6B1, an insect cytochrome p450 monooxygenase

Furanocoumarins represent plant toxins that are used in the treatment of a variety of skin diseases and are metabolized by cytochrome p450 monooxygenases (p450s) existing in insects such as Papilio polyxenes (the black swallowtail). To elucidate the active site in the CYP6B1 protein that is the principal p450 existing in this species, we have constructed a homology model of it based on sequence and structure alignments with the bacterial CYP102 protein whose crystal structure has been defined and with the insect CYP6B4 protein that also metabolizes furanocoumarins. In the derived CYP6B1 model, Phe116 and His117 in SRS1, Phe371 in SRS5 and Phe484 in SRS6 contribute to the formation of a resonant network that stabilizes the p450's catalytic site and allows for interactions with its furanocoumarin substrates. The first two of these residues are absolutely conserved in all members of the insect CYP6B subfamily and the last two are variable in different members of the CYP6B subfamily. A combination of theoretical and experimental docking analyses of two substrates (xanthotoxin and bergapten) and two inhibitors (coumarin and pilocarpine) of this p450 provide significant information on the positioning of furanocoumarins within this catalytic pocket. Molecular replacement models based on the results of variations at two of these critical amino acids provide support for our furanocoumarin-docked model and begin to rationalize the altered substrate reactivities observed in experimental analyses.     

Transcriptional regulation of the grape cytochrome P450 monooxygenase gene CYP736B expression in response to <Emphasis Type="Italic">Xylella fastidiosa</Emphasis> infection

Background  

Plant cytochrome P450 monooxygenases (CYP) mediate synthesis and metabolism of many physiologically important primary and secondary compounds that are related to plant defense against a range of pathogenic microbes and insects. To determine if cytochrome P450 monooxygenases are involved in defense response to Xylella fastidiosa (Xf) infection, we investigated expression and regulatory mechanisms of the cytochrome P450 monooxygenase CYP736B gene in both disease resistant and susceptible grapevines.