Crystal structure of OxyC,a cytochrome P450 implicated in an oxidative C-C coupling reaction during vancomycin biosynthesis

Gene inactivation studies point to the involvement of OxyC in catalyzing the last oxidative phenol coupling reaction during glycopeptide antibiotic biosynthesis. Presently, the substrate and exact timing of the OxyC reaction are unknown. The substrate might be the bicyclic heptapeptide or a thioester derivative bound to a protein carrier domain. OxyC from the vancomycin producer Amycolatopsis orientalis was produced in Escherichia coli and crystallized, and its structure was determined to 1.9 A resolution. OxyC gave UV-visible spectra characteristic of a P450-like hemoprotein in the low spin ferric state. After reduction to the ferrous state by dithionite the CO-ligated form gave a 450-nm peak in a UV-difference spectrum. The addition of vancomycin aglycone to OxyC produced type I changes to the UV spectrum. OxyC exhibits the typical P450-fold, with the Cys ligand loop containing the signature sequence FGHGX-HXCLG and Cys-356 being the proximal axial thiolate ligand of the heme iron. The observation of a water molecule bound to the heme iron is consistent with the UV-visible spectra of OxyC indicating a low spin heme. A polyethylene glycol molecule occupying the active site might mimic the bicyclic heptapeptide substrate. Analysis of the structure of Oxy-proteins and other P450s indicates regions that might be involved in binding of the redox partner and possibly the protein carrier domain.     

Crystal structure of OxyB,a cytochrome P450 implicated in an oxidative phenol coupling reaction during vancomycin biosynthesis

Gene-inactivation studies point to the involvement of OxyB in catalyzing the first oxidative phenol coupling reaction during glycopeptide antibiotic biosynthesis. The oxyB gene has been cloned and sequenced from the vancomycin producer Amycolatopsis orientalis, and the hemoprotein has been produced in Escherichia coli, crystallized, and its structure determined to 1.7-A resolution. OxyB gave UV-visible spectra characteristic of a P450-like hemoprotein in the low spin ferric state. After reduction to the ferrous state by dithionite or by spinach ferredoxin and ferredoxin reductase, the CO-ligated form gave a 450-nm peak in a UV-difference spectrum. Addition of putative heptapeptide substrates to resting OxyB produced type I changes to the UV spectrum, but no turnover was observed in the presence of ferredoxin and ferredoxin reductase, showing that either the peptides or the reduction system, or both, are insufficient to support a full catalytic cycle. OxyB exhibits the typical P450-fold, with helix L containing the signature sequence FGHGXHXCLG and Cys(347) being the proximal axial thiolate ligand of the heme iron. The structural similarity of OxyB is highest to P450nor, P450terp, CYP119, and P450eryF. In OxyB, the F and G helices are rotated out of the active site compared with P450nor, resulting in a much more open active site, consistent with the larger size of the presumed heptapeptide substrate.     

X‐ray crystal structure of cytochrome P450 monooxygenase CYP101J2 from Sphingobium yanoikuyae strain B2

The cytochrome P450 monooxygenases (P450s) catalyze a vast array of oxygenation reactions that can be useful in biocatalytic applications. CYP101J2 from Sphingobium yanoikuyae is a P450 that catalyzes the hydroxylation of 1,8‐cineole. Here we report the crystallization and X‐ray structure elucidation of recombinant CYP101J2 to 1.8 Å resolution. The CYP101J2 structure shows the canonical P450‐fold and has an open conformation in the absence of substrate. Analysis of the structure revealed that CYP101J2, in the absence of substrate, forms a well‐ordered substrate‐binding channel that suggests a unique form of substrate guidance in comparison to other bacterial 1,8‐cineole‐hydroxylating P450 enzymes. Proteins 2017; 85:945–950. © 2016 Wiley Periodicals, Inc.     

The 1.92-A structure of Streptomyces coelicolor A3(2) CYP154C1. A new monooxygenase that functionalizes macrolide ring systems

Evolutionary links between cytochrome P450 monooxygenases, a superfamily of extraordinarily divergent heme-thiolate proteins catalyzing a wide array of NADPH/NADH- and O(2)-dependent reactions, are becoming better understood because of availability of an increasing number of fully sequenced genomes. Among other reactions, P450s catalyze the site-specific oxidation of the precursors to macrolide antibiotics in the genus Streptomyces introducing regiochemical diversity into the macrolide ring system, thereby significantly increasing antibiotic activity. Developing effective uses for Streptomyces enzymes in biosynthetic processes and bioremediation requires identification and engineering of additional monooxygenases with activities toward a diverse array of small molecules. To elucidate the molecular basis for substrate specificity of oxidative enzymes toward macrolide antibiotics, the x-ray structure of CYP154C1 from Streptomyces coelicolor A3(2) was determined (Protein Data Bank code ). Relocation of certain common P450 secondary structure elements, along with a novel structural feature involving an additional beta-strand transforming the five-stranded beta-sheet into a six-stranded variant, creates an open cleft-shaped substrate-binding site between the two P450 domains. High sequence similarity to macrolide monooxygenases from other microbial species translates into catalytic activity of CYP154C1 toward both 12- and 14-membered ring macrolactones in vitro.     

Thoughts on thiolate tethering. Tribute and thanks to a teacher

A unique feature of P450 enzymes is in the presence of a thiolate ligand heme but its exact function in catalysis is a matter of debate. For P450 dependent monooxygenases the "active oxygen" complex seems to exist only as a transition state in which the thiolate ligand provides electron density in order to prevent pi-backbonding of the oxygen to the iron (-S-Fe-O(z.rad;)). The corresponding ground state (Compound I) would be a ferryl species (Fe(IV)z.dbnd6;O) with an electron hole either at the porphyrin or at the sulfur. Apart from this role we postulate that a second function is related to the electronic structure of Compound II as an electron acceptor and this property is shared among monooxygenases, thromboxane synthase, prostacyclin synthase, allene oxide synthase, P450(NOR(-)) and chloroperoxidase. As a common step in all P450 enzymes an extremely rapid electron uptake by Compound II allows that the primary substrate radicals are oxidized to cations which immediately combine with a neighbouring nucleophile. Thus "electron transfer" may substitute for "oxygen rebound" as the final step leading to product formation. The same principle also applies methane monooxygenases in which the role of the thiyl sulfur is replaced by a ferryl-oxyl entity.     

Regioselective deacetylation based on teicoplanin-complexed Orf2* crystal structures

Lipoglycopeptide antibiotics are more effective than vancomycin against MRSA as they carry an extra aliphatic acyl side chain on glucosamine (Glm) at residue 4 (r4). The biosynthesis of the r4 N-acyl Glc moiety at teicoplanin (Tei) or A40926 has been elucidated, in which the primary amine nucleophile of Glm is freed from the r4 GlcNac pseudo-Tei precursor by Orf2* for the subsequent acylation reaction to occur. In this report, two Orf2* structures in complex with β-D-octyl glucoside or Tei were solved. Of the complexed structures, the substrate binding site and a previously unknown hydrophobic cavity were revealed, wherein r4 GlcNac acts as the key signature for molecular recognition and the cavity allows substrates carrying longer acyl side chains in addition to the acetyl group. On the basis of the complexed structures, a triple-mutation mutant S98A/V121A/F193Y is able to regioselectively deacetylate r6 GlcNac pseudo-Tei instead of that at r4. Thereby, novel analogs can be made at the r6 sugar moiety.     

Comparison of intrinsic dynamics of cytochrome p450 proteins using normal mode analysis

Cytochrome P450 enzymes are hemeproteins that catalyze the monooxygenation of a wide‐range of structurally diverse substrates of endogenous and exogenous origin. These heme monooxygenases receive electrons from NADH/NADPH via electron transfer proteins. The cytochrome P450 enzymes, which constitute a diverse superfamily of more than 8,700 proteins, share a common tertiary fold but < 25% sequence identity. Based on their electron transfer protein partner, cytochrome P450 proteins are classified into six broad classes. Traditional methods of protein classification are based on the canonical paradigm that attributes proteins’ function to their three‐dimensional structure, which is determined by their primary structure that is the amino acid sequence. It is increasingly recognized that protein dynamics play an important role in molecular recognition and catalytic activity. As the mobility of a protein is an intrinsic property that is encrypted in its primary structure, we examined if different classes of cytochrome P450 enzymes display any unique patterns of intrinsic mobility. Normal mode analysis was performed to characterize the intrinsic dynamics of five classes of cytochrome P450 proteins. The present study revealed that cytochrome P450 enzymes share a strong dynamic similarity (root mean squared inner product > 55% and Bhattacharyya coefficient > 80%), despite the low sequence identity (< 25%) and sequence similarity (< 50%) across the cytochrome P450 superfamily. Noticeable differences in C_α atom fluctuations of structural elements responsible for substrate binding were noticed. These differences in residue fluctuations might be crucial for substrate selectivity in these enzymes.     

A heme peroxidase with a functional role as an L-tyrosine hydroxylase in the biosynthesis of anthramycin

We report the first characterization and classification of Orf13 (S. refuineus) as a heme-dependent peroxidase catalyzing the ortho-hydroxylation of L-tyrosine to L-DOPA. The putative tyrosine hydroxylase coded by orf13 of the anthramycin biosynthesis gene cluster has been expressed and purified. Heme b has been identified as the required cofactor for catalysis, and maximal L-tyrosine conversion to L-DOPA is observed in the presence of hydrogen peroxide. Preincubation of L-tyrosine with Orf13 prior to the addition of hydrogen peroxide is required for L-DOPA production. However, the enzyme becomes inactivated by hydrogen peroxide during catalysis. Steady-state kinetic analysis of L-tyrosine hydroxylation revealed similar catalytic efficiency for both L-tyrosine and hydrogen peroxide. Spectroscopic data from a reduced-CO(g) UV-vis spectrum of Orf13 and electron paramagnetic resonance of ferric heme Orf13 are consistent with heme peroxidases that have a histidyl-ligated heme iron. Contrary to the classical heme peroxidase oxidation reaction with hydrogen peroxide that produces coupled aromatic products such as o,o'-dityrosine, Orf13 is novel in its ability to catalyze aromatic amino acid hydroxylation with hydrogen peroxide, in the substrate addition order and for its substrate specificity for L-tyrosine. Peroxygenase activity of Orf13 for the ortho-hydroxylation of L-tyrosine to L-DOPA by a molecular oxygen dependent pathway in the presence of dihydroxyfumaric acid is also observed. This reaction behavior is consistent with peroxygenase activity reported with horseradish peroxidase for the hydroxylation of phenol. Overall, the putative function of Orf13 as a tyrosine hydroxylase has been confirmed and establishes the first bacterial class of tyrosine hydroxylases.     

Preparative use of isolated CYP102 monooxygenases -- a critical appraisal

Isolated P450 monooxygenases have for long been neglected catalysts in enzyme technology. This is surprising as they display a remarkable substrate specificity catalyzing reactions, which represent a challenge for classic organic chemistry. On the other hand, many P450 monooxygenases are membrane bound, depend on rather complicated electron transfer systems and require expensive cofactors such as NAD(P)H. Their activities are low, and stability leaves much to be desired. The use of bacterial P450 monooxygenases from CYP102 family allows overcoming some of these handicaps. They are soluble and their turnovers are high, presumably because their N-terminal heme monooxygenase and their C-terminal diflavin reductase domain are covalently linked. In recent years, protein engineering approaches have been successfully used to turn CYP102 monooxgenases into powerful biocatalysts.     

Cytochrome P450 is present in both ferrous and ferric forms in the resting state within intact Escherichia coli and hepatocytes

Cytochrome P450 enzymes (P450s) are exceptionally versatile monooxygenases, mediating hydroxylations of unactivated C-H bonds, epoxidations, dealkylations, and N- and S-oxidations as well as other less common reactions. In the conventional view of the catalytic cycle, based upon studies of P450s in vitro, substrate binding to the Fe(III) resting state facilitates the first 1-electron reduction of the heme. However, the resting state of P450s in vivo has not been examined. In the present study, whole cell difference spectroscopy of bacterial (CYP101A1 and CYP176A1, i.e. P450cam and P450cin) and mammalian (CYP1A2, CYP2C9, CYP2A6, CYP2C19, and CYP3A4) P450s expressed within intact Escherichia coli revealed that both Fe(III) and Fe(II) forms of the enzyme are present in the absence of substrates. The relevance of this finding was supported by similar observations of Fe(II) P450 heme in intact rat hepatocytes. Electron paramagnetic resonance (EPR) spectroscopy of the bacterial forms in intact cells showed that a proportion of the P450 in cells was in an EPR-silent form in the native state consistent with the presence of Fe(II) P450. Coexpression of suitable cognate electron donors increased the degree of endogenous reduction to over 80%. A significant proportion of intracellular P450 remained in the Fe(II) form after vigorous aeration of cells. The addition of substrates increased the proportion of Fe(II) heme, suggesting a kinetic gate to heme reduction in the absence of substrate. In summary, these observations suggest that the resting state of P450s should be regarded as a mixture of Fe(III) and Fe(II) forms in both aerobic and oxygen-limited conditions.     

Heteroactivator effects on the coupling and spin state equilibrium of CYP2C9

The cytochromes P450 are capable of oxidizing a variety of xenobiotics. Binding of a small molecule heteroactivator to a P450 can alter the coupling of substrate oxidation during P450 catalysis, but the degree to which coupling or shunting via one of the three catalytic cycle branch points is linked to the heteroactivator-modified position of bound substrate is unknown. Using reconstituted CYP2C9, stoichiometric measurements were gathered with three substrates and two classes of heteroactivators to further understand the mechanisms involved in heteroactivation. Heteroactivation of P450 metabolism appeared to involve, but not require, changes in coupling and that increased uncoupling to a specific byproduct like H(2)O(2) does not necessarily correlate to the degree of coupling. In addition, spectroscopy demonstrated that every heteroactivator tested influenced the spin equilibrium of the heme iron even in the presence of saturating substrate suggesting that both substrate proximity and the ability to desolvate the heme can be involved in heteroactivation.     

Plant Cytochrome P450 Monooxygenases

Plant systems utilize a diverse array of cytochrome P450 monooxygenases (P450s) in their biosynthetic and detoxification pathways. The classic forms of these enzymes are heme-dependent mixed function oxidases that utilize NADPH or NADH and molecular oxygen to produce functionalized organic products. The nonclassical forms are monooxygenases that either do not utilize flavoproteins for dioxygen activation or fail to incorporate molecular oxygen into their final product. Biosynthetic P450s play paramount roles in the synthesis of lignin intermediates, sterols, terpenes, flavonoids, isoflavonoids, furanocoumarins, and a variety of other secondary plant products. Other catabolic P450s metabolize toxic herbicides and insecticides into nontoxic products or, conversely, activate nontoxic substances into toxic products. Biochemical and molecular characterizations on a number of plant P450s have indicated that the relationships between these heme proteins and their substrates are at least as complex as those that exist in mammalian systems. Examples now exist of plant P450s that metabolize: a narrow range of substrates to yield different products, a single substrate to yield different products, multiple substrates to yield the same product, or a single substrate sequentially to yield discrete intermediates in the biosynthesis of a single product. Extensive divergence of catalytic site as well as noncatalytic site residues accounts for the high degree of primary structure variation in the P450 gene superfamily and the diverse array of substrates synthesized and/or detoxified by these proteins. Classic P450s still retain a highly conserved F-G-R-C-G motif in their catalytic site and conserved amino acids in their oxygen binding pocket; nonclassical P450s diverge at several of these positions. A broad range of cloning and transient expression strategies are suitable for plant P450 studies and these have allowed for the isolation and characterization of a number of P450 cDNAs and genes. Because many of these sequences have been cloned only recently, much remains to be learned about the substrate specificities of P450 reactions in plants and the mechanisms by which their genes are regulated.     

Smart peptide libraries are accessible via enzymatic modifications

Summary The minireview summarizes the recent preparation of the following unusually modified combinatorial peptide collections useful for diagnostics and screening in drug finding. Tissue transglutaminase catalyzes cross couplings with transamidation between Gln and Lys peptide chains resulting in libraries with isopeptide bonds. The enzyme is involved in the triggering of autoantigenic B- and T-cell epitopes of coeliac disease. The microbial enzyme EpiD involved in lantibiotic biosynthesis catalyzes oxidative decarboxylation of C-terminal cysteine residues in peptide libraries transforming peptidyl-cysteines to peptide (2-mercaptovinyl)amides. Novel backbone modified peptide libraries are prepared using oxazole and thiazole building blocks carrying amino acid side chains. These amino acids have been found in many biologically active natural products from marine and microbial organisms such as microcin B17. Dityrosine and isodityrosine linked peptide dimer libraries are accessible by oxidative phenol coupling using horseradish peroxidase. Such structural elements are found for example in the polycyclic glycopeptide antibiotics of the vancomycin type. Microstructured layers of linear and cyclic peptide libraries are generated on transducer surfaces for cellular assays, sensor developments and even chiral recognition. Examples include a light-directed and microstructured electrochemical polymerization of phenol labelled peptides.     

New insights into the first oxidative phenol coupling reaction during vancomycin biosynthesis

OxyB catalyzes the first oxidative phenol coupling reaction in vancomycin biosynthesis. OxyB is a P450 hemoprotein whose activity is strictly dependent upon the presence of molecular oxygen. Here, it was shown that label from (18)O(2) is not incorporated into the monocyclic product during catalysis by OxyB. In addition, it was shown that OxyB can convert a model hexapeptide substrate containing (R)-Tyr6, instead of (S)-Tyr6, covalently linked as a C-terminal thioester to a peptidyl carrier protein (PCP-7S) derived from the vancomycin non-ribosomal peptide synthetase (NRPS), into the corresponding epimeric monocyclic product. The binding of this epimeric hexapeptide-PCP conjugate to the Fe(III) form of OxyB, as monitored by UV-vis spectroscopy, revealed a K(d)=35+/-5 microM. Thus, the enzyme reveals a surprising lack of stereospecificity in the binding and transformation of these epimeric substrates.     

Coexpression of genetically engineered fused enzyme between yeast NADPH-P450 reductase and human cytochrome P450 3A4 and human cytochrome b5 in yeast

Human hepatic cytochrome P450 3A4 (CYP3A4) was expressed in yeast Saccharomyces cerevisiae. While the expression level was high as compared with other human hepatic cytochrome P450s, CYP3A4 showed almost no catalytic activity toward testosterone. Coexpression of CYP3A4 with yeast NADPH-P450 reductase did not give a full activity. Low monooxygenase activity of CYP3A4 was attributed to the insufficient reduction of heme iron of CYP3A4 by NADPH-P450 reductase. To enhance the efficiency of electron transfer from NADPH-P450 reductase to CYP3A4, a fused enzyme was constructed between CYP3A4 and yeast NADPH-P450 reductase. The rapid reduction of the heme iron of the fused enzyme by NADPH was observed. The fused enzyme showed a high testosterone 6beta-hydroxylation activity with a sigmoidal velocity saturation curve. However, the coupling efficiency between NADPH utilization and testosterone 6beta-hydroxylation was only 10%. Finally, coexpression of the fused enzyme and human cytochrome b5 was examined. A significant decrease in the Km value and a remarkable increase in the coupling efficiency were observed. Substrate-induced spectra revealed that the dissociation constant of the fused enzyme for testosterone significantly decreased with coexpression of human cytochrome b5. These results strongly suggest that human cytochrome b5 directly interacts with the CYP3A4 domain of the fused enzyme and modifies the tertiary structure of substrate binding pocket, resulting in tight binding of the substrate and high coupling efficiency.     

Cytochrome P450‐catalyzed O‐dealkylation coupled with photochemical NADPH regeneration

Cytochrome P450 monooxygenases are multifunctional enzymes with potential applications in chemoenzymatic synthesis of complex chemicals as well as in studies of metabolism and xenobiotics. Widespread application of cytochrome P450s, however, is encumbered by the critical need for redox equivalents in their catalytic function. To overcome this limitation, we studied visible light‐driven regeneration of NADPH for P450‐catalyzed O‐dealkylation reaction; we used eosin Y as a photosensitizing dye, triethanolamine as an electron donor, and [Cp*Rh(bpy)H₂O] as an electron mediator. We analyzed catalytic activity of cell‐free synthesized P450 BM3 monooxygenase variant (Y51F/F87A, BM3m2) in the presence of key components for NADPH photoregeneration. The P450‐catalyzed O‐dealkylation reaction sustainably maintained its turnover with the continuous supply of photoregenerated NADPH. Visible light‐driven, non‐enzymatic NADPH regeneration provides a new route for efficient, sustainable utilization of P450 monooxygenases. Biotechnol. Bioeng. 2013; 110: 383–390. © 2012 Wiley Periodicals, Inc.     

Conservation analysis of class‐specific positions in cytochrome P450 monooxygenases: Functional and structural relevance

Cytochrome P450 monooxygenases (CYPs) constitute a ubiquitous, highly divergent protein family. Nevertheless, all CYPs share a common fold and conserved catalytic machinery. Based on the electron donor system, 10 classes of CYPs have been described, but most CYPs are members of class I accepting electrons from ferredoxin which is being reduced by FAD‐containing reductase, or class II accepting electrons from FAD‐ and FMN‐containing CPR‐type reductase. Because of the low sequence conservation inside the two classes, the conserved class‐specific positions are expected to be involved in aspects of electron transfer that are specific to the two types of reductases. In this work we present results from a conservation analysis of 16,732 CYP sequences derived from an updated version of the Cytochrome P450 Engineering Database (CYPED), using two class‐specific numbering schemes. While no position was conserved on the distal, substrate‐binding surface of the CYPs, several class‐specific residues were found on the proximal, reductase‐interacting surface; two class I‐specific residues that were negatively charged, and three class II‐specific residues that were aromatic or charged. The class‐specific conservation of glycine and proline residues in the cysteine pocket indicates that there are class‐specific differences in the flexibility of this element. Four heme‐interacting arginines were conserved differently in each class, and a class‐specific substitution of a heme‐interacting tyrosine by histidine was found, pointing to a link between heme stabilization and the reductase type. Proteins 2014; 82:491–504. © 2013 Wiley Periodicals, Inc.     

Structure of the UDP-glucosyltransferase GtfB that modifies the heptapeptide aglycone in the biosynthesis of vancomycin group antibiotics

BACKGROUND: Members of the vancomycin group of glycopeptide antibiotics have an oxidatively crosslinked heptapeptide scaffold decorated at the hydroxyl groups of 4-OH-Phegly4 or beta-OH-Tyr6 with mono- (residue 6) or disaccharides (residue 4). The disaccharide in vancomycin itself is L-vancosamine-1,2-glucose, and in chloroeremomycin it is L-4-epi-vancosamine-1,2-glucose. The sugars and their substituents play an important role in efficacy, particularly against vancomycin-resistant pathogenic enterococci. RESULTS: The glucosyltransferase, GtfB, that transfers the glucose residue from UDP-glucose to the 4-OH-Phegly4 residue of the vancomycin aglycone, initiating the glycosylation pathway in chloroeremomycin maturation, has been crystallized, and its structure has been determined by X-ray analysis at 1.8 A resolution. The enzyme has a two-domain structure, with a deep interdomain cleft identified as the likely site of UDP-glucose binding. A hydrophobic patch on the surface of the N-terminal domain is proposed to be the binding site of the aglycone substrate. Mutagenesis has revealed Asp332 as the best candidate for the general base in the glucosyltransfer reaction. CONCLUSIONS: The structure of GtfB places it in a growing group of glycosyltransferases, including Escherichia coli MurG and a beta-glucosyltransferase from T4 phage, which together form a subclass of the glycosyltransferase superfamily and give insights into the recognition of the NDP-sugar and aglycone cosubstrates. A single major interdomain linker between the N- and C- terminal domains suggests that reprogramming of sugar transfer or aglycone recognition in the antibiotic glycosyltransferases, including the glycopeptide and also the macrolide antibiotics, will be facilitated by this structural information.     

Identification of selectivity-determining residues in cytochrome P450 monooxygenases: a systematic analysis of the substrate recognition site 5

The large and diverse family of cytochrome P450 monooxygenases (CYPs) was systematically analyzed to identify selectivity- and specificity-determining residues in the substrate recognition site 5, which is located in close vicinity to the heme center. A positively charged heme-interacting residue was identified in the structures of 29 monooxygenases and in 97.7% of the 6379 CYP sequences investigated here. This heme-interacting residue restricts the conformation of the substrate recognition site 5 and is preferentially located at position 10 or 11 after the conserved ExxR motif (in 94.4% of the sequences), in 3.3% of the sequences at position 9 or 12. As a result, a classification by the position of the heme-interacting residue allows to predict residues that are closest to the heme center and restrict its accessibility. In 98.4% of all CYP sequences a preferentially hydrophobic residue is located at position 5 after the ExxR motif that is predicted to point close to the heme center. Replacing this residue by hydrophobic residues of different size has been shown to change substrate specificity and regioselectivity for CYPs of different superfamilies. Twenty-seven percent of all CYPs are predicted to contain a second selectivity-determining residue at position 9 after the ExxR motif that can be identified by the pattern EXXR-X(7)-{P}-x-P-[HKR].     

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.