Direct Hydroxylation of Benzene to Phenol by Cytochrome P450BM3 Triggered by Amino Acid Derivatives

The selective hydroxylation of benzene to phenol, without the formation of side products resulting from overoxidation, is catalyzed by cytochrome P450BM3 with the assistance of amino acid derivatives as decoy molecules. The catalytic turnover rate and the total turnover number reached 259 min⁻¹ P450BM3⁻¹ and 40 200 P450BM3⁻¹ when N‐heptyl‐l ‐proline modified with l ‐phenylalanine (C7‐l ‐Pro‐l ‐Phe) was used as the decoy molecule. This work shows that amino acid derivatives with a totally different structure from fatty acids can be used as decoy molecules for aromatic hydroxylation by wild‐type P450BM3. This method for non‐native substrate hydroxylation by wild‐type P450BM3 has the potential to expand the utility of P450BM3 for biotransformations.     

Whole‐Cell Biotransformation of Benzene to Phenol Catalysed by Intracellular Cytochrome P450BM3 Activated by External Additives

An Escherichia coli whole‐cell biocatalyst for the direct hydroxylation of benzene to phenol has been developed. By adding amino acid derivatives as decoy molecules to the culture medium, wild‐type cytochrome P450BM3 (P450BM3) expressed in E.coli can be activated and non‐native substrates hydroxylated, without supplementing with NADPH. The yield of phenol reached 59 % when N‐heptyl‐l ‐prolyl‐l ‐phenylalanine (C7‐Pro‐Phe) was employed as the decoy molecule. It was shown that decoy molecules, especially those lacking fluorination, reached the cytosol of E. coli, thus imparting in vivo catalytic activity for the oxyfunctionalisation of non‐native substrates to intracellular P450BM3.     

Improved Cyclopropanation Activity of Histidine‐Ligated Cytochrome P450 Enables the Enantioselective Formal Synthesis of Levomilnacipran

Engineering enzymes capable of modes of activation unprecedented in nature will increase the range of industrially important molecules that can be synthesized through biocatalysis. However, low activity for a new function is often a limitation in adopting enzymes for preparative‐scale synthesis, reaction with demanding substrates, or when a natural substrate is also present. By mutating the proximal ligand and other key active‐site residues of the cytochrome P450 enzyme from Bacillus megaterium (P450‐BM3), a highly active His‐ligated variant of P450‐BM3 that can be employed for the enantioselective synthesis of the levomilnacipran core was engineered. This enzyme, BM3‐Hstar, catalyzes the cyclopropanation of N,N‐diethyl‐2‐phenylacrylamide with an estimated initial rate of over 1000 turnovers per minute and can be used under aerobic conditions. Cyclopropanation activity is highly dependent on the electronic properties of the P450 proximal ligand, which can be used to tune this non‐natural enzyme activity.     

Co‐crystals with Acetylene: Small Is not Simple!

Acetylene is an amazingly versatile component for the formation of co‐crystals. It requires careful handling and special techniques for crystallisation, but the efforts seem to be rewarding when attaining co‐crystals with small molecules as partners. Many basic questions such as the dominance of specific heterogeneous intermolecular interactions, their driving force for the formation of multicomponent crystals instead of neat ones are expected to be easily analysed. The underlying packing patterns and resulting stoichiometries based on the known supramolecular synthons seem to be straightforward for such small molecules and crystal engineering, considered as the prototype of supramolecular synthesis, should be a simple task. Nineteen co‐crystals with acetylene are presented in this paper, some of which have been previously reported individually. An attempt has been made to find features shared by the groups of co‐crystals, including those that could not be co‐crystallised. But in spite of clear ideas and experiences from previous experiments, surprisingly almost none of systems reached our expectations. Our intuitive approach was not fulfilled, which demonstrates that multicomponent crystals even of small molecules will remain a great challenge for theoretical methods and the crystal structures shown herein represent good candidates for future testing. On the other hand, we wish to encourage other groups to present their views on the crystal structures with an unbiased approach that may offer a better explanation than we are able to outline in this article.     

Cofactor‐Free Light‐Driven Whole‐Cell Cytochrome P450 Catalysis

Cytochromes P450 can catalyze various regioselective and stereospecific oxidation reactions of non‐functionalized hydrocarbons. Here, we have designed a novel light‐driven platform for cofactor‐free, whole‐cell P450 photo‐biocatalysis using eosin Y (EY) as a photosensitizer. EY can easily enter into the cytoplasm of Escherichia coli and bind specifically to the heme domain of P450. The catalytic turnover of P450 was mediated through the direct transfer of photoinduced electrons from the photosensitized EY to the P450 heme domain under visible light illumination. The photoactivation of the P450 catalytic cycle in the absence of cofactors and redox partners is successfully conducted using many bacterial P450s (variants of P450 BM3) and human P450s (CYPs 1A1, 1A2, 1B1, 2A6, 2E1, and 3A4) for the bioconversion of different substrates, including marketed drugs (simvastatin, lovastatin, and omeprazole) and a steroid (17β‐estradiol), to demonstrate the general applicability of the light‐driven, cofactor‐free system.     

Laser photoexcitation of NAD(P)H induces reduction of P450 BM3 heme domain on the microsecond time scale

We demonstrate that photoexcitation of NAD(P)H at 355 nm using a Nd:YAG laser leads to rapid reduction of the heme domain of the Bacillus megaterium fatty acid hydroxylase flavocytochrome P450 BM3. An aqueous electron derived from photoexcited NAD(P)H is rapidly transferred to the heme domain, enabling the formation of a carbon monoxy complex of the ferrous P450 (FeII-CO) on the microsecond time scale. Using this approach we have determined the limiting rate constant (1770 s-1 for substrate-free heme domain) for formation of the FeII-CO complex. We find no dependence of the observed rate of FeII-CO complex formation on NAD(P)H concentration but demonstrate a hyperbolic dependence on carbon monoxide concentration. The apparent dissociation constant for the complex of carbon monoxide bound noncovalently to the ferric form of the BM3 heme domain (and with NADH as reductant) is 323 microM. Binding of a P450 substrate (N-palmitoylglycine) weakened the complex between carbon monoxide and the ferric BM3 heme domain (Kd increased to 1404 microM) but enhanced the rate of formation of the FeII-CO complex (3036 s-1 for substrate-free heme domain). This study demonstrates the applicability of NAD(P)H photoexcitation as a method for rapid electron delivery to P450 enzymes and provides a new route to probing the P450 catalytic cycle and its transient intermediates.     

DNA-mediated assembly of cytochrome P450 BM3 subdomains

Cytochrome P450 BM3 is a versatile enzyme, which holds great promise for applications in biocatalysis and biomedicine. We here report on the generation of a hybrid DNA-protein device based on the two subdomains of BM3, the reductase domain BMR and the porphyrin domain BMP. Both subdomains were fused genetically to the HaloTag protein, a self-labeling enzyme, allowing for the bioconjugation with chloroalkane-modified oligonucleotides. The subdomain-DNA-chimeras could be reassembled by complementary oligonucleotides, thus leading to reconstitution of the monooxygenase activity of BM3 holoenzyme, as demonstrated by conversion of the reporter substrate 12-pNCA. Arrangement of the two chimeras on a switchable DNA scaffold allowed one to control the distance between both subdomains, as indicated by the DNA-dependent activity of the holoenzyme. Furthermore, a switchable chimeric device was constructed, in which monooxygenase activity could be turned off by DNA strand displacement. This study demonstrates that P450 BM3 engineering and strategies of DNA nanotechnology can be merged to open up novel ways for the development of novel screening systems or responsive catalysts with potential applications in drug delivery.     

Structure, electronic properties and catalytic behaviour of an activity-enhancing CYP102A1 (P450(BM3)) variant

The substrate-free crystal structure of a five-mutation directed evolution variant of CYP102A1 (P450(BM3)) with generic activity-enhancing properties ("KT2") has been determined to 1.9-? resolution. There is a close resemblance to substrate-bound structures of the wild-type enzyme (WT). The disruption of two salt bridges that link the G- and I-helices in WT causes conformational changes that break several hydrogen bonds and reduce the angle of the kink in the I-helix where dioxygen activation is thought to take place. The side-chain of a key active site residue, Phe87, is rotated in one molecule of the asymmetric unit, and the side-chains of Phe158 and Phe261 cascade into the orientations found in fatty-acid-bound forms of the enzyme. The iron is out of the porphyrin plane, towards the proximal cysteine. Unusually, the axial water ligand to the haem iron is not hydrogen-bonded to Ala264. The first electron transfer from the reductase domain to the haem domain of substrate-free KT2 is almost as fast as in palmitate-bound WT even though the reduction potential of the haem domain is only slightly more oxidising than that of substrate-free WT. However, NADPH is turned over slowly in the absence of substrate, so the catalytic cycle is gated by a step subsequent to the first electron transfer-a contrast to WT. Propylbenzene binding slightly raises the first electron transfer rate in WT but not in KT2. It is proposed that the generic rate accelerating properties of KT2 arise from the substrate-free form being in a catalytically ready conformation, such that substrate-induced changes to the structure play a less significant role in promoting the first electron transfer than in WT.     

Engineering artificial redox chains by molecular 'Lego'

This work reports on a novel approach for building artificial redox chains: the molecular 'Lego' approach. This exploits the scaffold of natural redox proteins by fusing together functional protein modules with the desired properties. The molecular 'Lego' mimics the natural molecular evolution that proceeded by modular assembly of genes/DNA segments. Non-physiological electron transfer partners, flavodoxin (fld) and cytochrome c553 (c553) from Desulfovibrio vulgaris and the haem domain of P450 BM3 (BMP) from Bacillus megaterium have been used as building blocks in different combinations to build artificial redox chains. The kinetic characterization of the electron transfer (ET) between the separate building blocks has been carried out. Under pseudo-first order conditions, a limiting ET rate, klim, of 0.48 +/- 0.05 s-1 and 43.77 +/- 2.18 s-1 and an apparent binding constant, Kapp, of 21 +/- 6 microM and 1.23 +/- 0.32 microM have been found for the fld/c553 and fld/BMP redox pairs, respectively. These results show that fld can be used as a module for transferring electrons to c553 and BMP. A 3D model of the fld/c553 and fld/BMP complexes was used to guide the construction of covalently linked assemblies via engineered disulfide bridges or by fusion of the relevant genes via an engineered loop. The first approach led to the construction, expression and characterization of the S35C and S64C mutants of fld and M23C and G51C mutants of c553. Although the redox potentials of the separate mutants were found to be the same as those of recombinant wild type proteins (-408 mV for the semiquinone/hydroquinone couple of fld and +32 mV for the c553), the c553 homo-dimers M23C-M23C and G51C-G51C were found to have redox potentials of +88 and +105 mV, respectively. These differences have been analysed in terms of exposure of the haem cofactors to the solvent, and these lead to some interesting questions on the redox potentials of the transient redox complexes in physiological systems. The fld-c553 S64C-M23C and S35C-M23C chimeras were constructed, expressed and purified but the FMN was found to be destabilised resulting in the apo-form of these proteins. The gene fusion strategy was used to produce covalently linked assemblies of both fld-c553 and fld-BMP. The former was expressed using a seven amino acid (GPGPGPG) loop linking the C-terminus of fld to the N-terminus of c553. The fld-BMP fusion protein was successfully expressed by using the naturally occurring loop of the P450 BM3 (residues 471-479) to link the BMP domain at the N-terminus with fld domain at the C-terminus. This fusion was found to be correctly folded and functional. Efficient ET from the FMN to the haem domain (370 s-1) was also found to be in the same region of the physiological redox partners (250 s-1). This work demonstrates the feasibility of the molecular 'Lego' approach in generating functional multi-domain proteins with designed properties, beyond the restrictions imposed by the naturally occurring protein domains.     

Metal-substituted protein MRI contrast agents engineered for enhanced relaxivity and ligand sensitivity

Engineered metalloproteins constitute a flexible new class of analyte-sensitive molecular imaging agents detectable by magnetic resonance imaging (MRI), but their contrast effects are generally weaker than synthetic agents. To augment the proton relaxivity of agents derived from the heme domain of cytochrome P450 BM3 (BM3h), we formed manganese(III)-containing proteins that have higher electron spin than their native ferric iron counterparts. Metal substitution was achieved by coexpressing BM3h variants with the bacterial heme transporter ChuA in Escherichia coli and supplementing the growth medium with Mn3+-protoporphyrin IX. Manganic BM3h variants exhibited up to 2.6-fold higher T1 relaxivities relative to native BM3h at 4.7 T. Application of ChuA-mediated porphyrin substitution to a collection of thermostable chimeric P450 domains resulted in a stable, high-relaxivity BM3h derivative displaying a 63% relaxivity change upon binding of arachidonic acid, a natural ligand for the P450 enzyme and an important component of biological signaling pathways. This work demonstrates that protein-based MRI sensors with robust ligand sensitivity may be created with ease by including metal substitution among the toolkit of methods available to the protein engineer.     

Selective C–H bond functionalization with light-driven P450 biocatalysts

The unique photochemical properties of Ru(II)-diimine photosensitizers have enabled light-induced electron transfers in hybrid P450 heme domain enzymes. Rapid quenching of the excited state by soluble molecules generates either a highly oxidative or reductive species depending on the nature of the quencher. Under flash quench oxidative conditions, the heme cofactor of the P450 BM3 enzyme is oxidized to a high-valent ferryl species. Meanwhile, a photogenerated reductive species is able to deliver the necessary electrons to P450 heme active sites and sustain photocatalytic activity in the selective hydroxylation of substrate C–H bonds.     

Reduction of dioxygen catalyzed by pyrene-wired heme domain cytochrome P450 BM3 electrodes

We have electronically wired the cytochrome P450 BM3 heme domain to a graphite electrode with the use of a pyrene-terminated tether. AFM images clearly reveal that pyrene-wired enzyme molecules are adsorbed to the electrode surface. The enzyme-electrode system undergoes rapid and reversible electron transfer, displaying a standard rate constant higher than that of any other P450-electrode system. We also show that the graphite-pyrene-BM3 system catalyzes the four-electron reduction of dioxygen to water.     

Light-initiated hydroxylation of lauric acid using hybrid P450 BM3 enzymes

We have developed hybrid P450 BM3 enzymes consisting of a Ru(II)-diimine photosensitizer covalently attached to non-native single cysteine residues of P450 BM3 heme domain mutants. These enzymes are capable, upon light activation, of selectively hydroxylating lauric acid with 40 times higher total turnover numbers compared to the peroxide shunt.     

A Compound I Mimic Reveals the Transient Active Species of a Cytochrome P450 Enzyme: Insight into the Stereoselectivity of P450-Catalysed Oxidations

Catching the structure of cytochrome P450 enzymes in flagrante is crucial for the development of P450 biocatalysts, as most structures collected are found trapped in a precatalytic conformation. At the heart of P450 catalysis lies Cpd I, a short-lived, highly reactive intermediate, whose recalcitrant nature has thwarted most attempts at capturing catalytically relevant poses of P450s. We report the crystal structure of P450BM3 mimicking the state in the precise moment preceding epoxidation, which is in perfect agreement with the experimentally observed stereoselectivity. This structure was attained by incorporation of the stable Cpd I mimic oxomolybdenum mesoporphyrin IX into P450BM3 in the presence of styrene. The orientation of styrene to the Mo-oxo species in the crystal structures sheds light onto the dynamics involved in the rotation of styrene to present its vinyl group to Cpd I. This method serves as a powerful tool for predicting and modelling the stereoselectivity of P450 reactions.     

Dual‐Functional Small Molecules for Generating an Efficient Cytochrome P450BM3 Peroxygenase

We report a unique strategy for the development of a H₂O₂‐dependent cytochrome P450BM3 system, which catalyzes the monooxygenation of non‐native substrates with the assistance of dual‐functional small molecules (DFSMs), such as N‐(ω‐imidazolyl fatty acyl)‐l ‐amino acids. The acyl amino acid group of DFSM is responsible for bounding to enzyme as an anchoring group, while the imidazolyl group plays the role of general acid–base catalyst in the activation of H₂O₂. This system affords the best peroxygenase activity for the epoxidation of styrene, sulfoxidation of thioanisole, and hydroxylation of ethylbenzene among those P450–H₂O₂ system previously reported. This work provides the first example of the activation of the normally H₂O₂‐inert P450s through the introduction of an exogenous small molecule. This approach improves the potential use of P450s in organic synthesis as it avoids the expensive consumption of the reduced nicotinamide cofactor NAD(P)H and its dependent electron transport system. This introduces a promising approach for exploiting enzyme activity and function based on direct chemical intervention in the catalytic process.     

Fluorescence detection of ligand binding to labeled cytochrome P450 BM3

The cytochrome P450 superfamily of monoxygenases are highly relevant for pharmaceutical, environmental and biocatalytical applications. The binding of a substrate to their catalytic site is usually detectable by UV-vis spectroscopy as a low-to-high spin state transition of the heme iron. However, the discovery of potential new substrates is limited by the fact that some compounds do not cause the typical spin-shift even if they are oxidised by P450 enzymes. Here we report a fluorescence-based method able to detect the binding of such substrates to the heme domain of cytochrome P450 BM3 from Bacillus megaterium. The protein was labeled with the fluorescent probe N,N'-dimethyl-N-(iodoacetyl)-N'-(7-nitrobenz-2-oxa-1,3-diazol-4-Yl)-ethylenediamine (IANBD). Arachidonic and lauric acids are substrates of P450 BM3 and were used to validate the method, as their binding can be detected both by a spin-shift of the Soret peak from 419 to 397 nm and by the fluorescence change of the labelled protein. The fluorescence emission of the probe linked to the protein increased by a value corresponding to 121 ± 9% and 52 ± 5% with respect to the initial one, upon titration with arachidonic or lauric acids respectively. The dissociation constants were calculated by both UV-vis and fluorescence spectroscopy. Three drugs, propranolol, chlorzoxazone and nifedipine, known to be oxidized by P450 BM3 and that bind without causing spin-shift, were also tested and the fluorescence emission of IANBD was found to decrease by 29 ± 5%, 21 ± 2% and 23 ± 3%, respectively, allowing the measurement of their dissociation constants.     

Assembly and Purification of Enzyme‐Functionalized DNA Origami Structures

The positioning of enzymes on DNA nanostructures for the study of spatial effects in interacting biomolecular assemblies requires chemically mild immobilization procedures as well as efficient means for separating unbound proteins from the assembled constructs. We herein report the exploitation of free‐flow electrophoresis (FFE) for the purification of DNA origami structures decorated with biotechnologically relevant recombinant enzymes: the S‐selective NADP⁺/NADPH‐dependent oxidoreductase Gre2 from S. Cerevisiae and the reductase domain of the monooxygenase P450 BM3 from B. megaterium. The enzymes were fused with orthogonal tags to facilitate site‐selective immobilization. FFE purification yielded enzyme–origami constructs whose specific activity was quantitatively analyzed. All origami‐tethered enzymes were significantly more active than the free enzymes, thereby suggesting a protective influence of the large, highly charged DNA nanostructure on the stability of the proteins.     

Anchoring a Structurally Editable Proximal Cofactor-like Module to Construct an Artificial Dual-center Peroxygenase

A recent novel strategy for constructing artificial metalloenzymes (ArMs) that target new-to-nature functions uses dual-functional small molecules (DFSMs) with catalytic and anchoring groups for converting P450BM3 monooxygenase into a peroxygenase. However, this process requires excess DFSMs (1000 equivalent of P450) owing to their low binding affinity for P450, thus severely limiting its practical application. Herein, structural optimization of the DFSM-anchoring group considerably enhanced their binding affinity by three orders of magnitude (K_d≈10⁻⁸ M), thus approximating native cofactors, such as FMN or FAD in flavoenzymes. An artificial cofactor-driven peroxygenase was thus constructed. The co-crystal structure of P450BM3 bound to a DFSM clearly revealed a precatalytic state in which the DFSM participates in H₂O₂ activation, thus facilitating peroxygenase activity. Moreover, the increased binding affinity substantially decreases the DFSM load to as low as 2 equivalents of P450, while maintaining increased activity. Furthermore, replacement of catalytic groups showed disparate selectivity and activity for various substrates. This study provides an unprecedented approach for assembling ArMs by binding editable organic cofactors as a co-catalytic center, thereby increasing the catalytic promiscuity of P450 enzymes.     

Multi‐Functional Oxidase Activity of CYP102A1 (P450BM3) in the Oxidation of Quinolines and Tetrahydroquinolines

Tetrahydroquinoline, quinoline, and dihydroquinolinone are common core motifs in drug molecules. Screening of a 48‐variant library of the cytochrome P450 enzyme CYP102A1 (P450BM3), followed by targeted mutagenesis based on mutation‐selectivity correlations from initial hits, has enabled the hydroxylation of substituted tetrahydroquinolines, quinolines, and 3,4‐dihydro‐2‐quinolinones at most positions around the two rings in good to high yields at synthetically relevant scales (1.5 g L^?1 day^?1). Other oxidase activities, such as C?C bond desaturation, aromatization, and C?C bond formation, were also observed. The enzyme variants, with mutations at the key active site residues S72, A82, F87, I263, E267, A328, and A330, provide direct and sustainable routes to oxy‐functionalized derivatives of these building block molecules for synthesis and drug discovery.     

Three-dimensional modelling of human cytochrome P450 1A2 and its interaction with caffeine and MeIQ

The three-dimensional modelling of proteins is a useful tool to fill the gap between the number of sequenced proteins and the number of experimentally known 3D structures. However, when the degree of homology between the protein and the available 3D templates is low, model building becomes a difficult task and the reliability of the results depends critically on the correctness of the sequence alignment. For this reason, we have undertaken the modelling of human cytochrome P450 1A2 starting by a careful analysis of several sequence alignment strategies (multiple sequence alignments and the TOPITS threading technique). The best results were obtained using TOPITS followed by a manual refinement to avoid unlikely gaps. Because TOPITS uses secondary structure predictions, several methods that are available for this purpose (Levin, Gibrat, DPM, NnPredict, PHD, SOPM and NNSP) have also been evaluated on cytochromes P450 with known 3D structures. More reliable predictions on -helices have been obtained with PHD, which is the method implemented in TOPITS. Thus, a 3D model for human cytochrome P450 1A2 has been built using the known crystal coordinates of P450 BM3 as the template. The model was refined using molecular mechanics computations. The model obtained shows a consistent location of the substrate recognition segments previously postulated for the CYP2 family members. The interaction of caffeine and a carcinogenic aromatic amine (MeIQ), which are characteristic P450 1A2 substrates, has been investigated. The substrates were solvated taking into account their molecular electrostatic potential distributions. The docking of the solvated substrates in the active site of the model was explored with the AUTODOCK programme, followed by molecular mechanics optimisation of the most interesting complexes. Stable complexes were obtained that could explain the oxidation of the considered substrates by cytochrome P450 1A2 and could offer an insight into the role played by water molecules.