Cytochrome P450cam Research Articles

Infrared spectroscopic and mutational studies on putidaredoxin-induced conformational changes in ferrous CO-P450cam.

Ferrous-carbon monoxide bound form of cytochrome P450cam (CO-P450cam) has two infrared (IR) CO stretching bands at 1940 and 1932 cm(-1). The former band is dominant (>95% in area) for CO-P450cam free of putidaredoxin (Pdx), while the latter band is dominant (>95% in area) in the complex of CO-P450cam with reduced Pdx. The binding of Pdx to CO-P450cam thus evokes a conformational change in the heme active site. To study the mechanism involved in the conformational change, surface amino acid residues Arg79, Arg109, and Arg112 in P450cam were replaced with Lys, Gln, and Met. IR spectroscopic and kinetic analyses of the mutants revealed that an enzyme that has a larger 1932 cm(-1) band area upon Pdx-binding has a larger catalytic activity. Examination of the crystal structures of R109K and R112K suggested that the interaction between the guanidium group of Arg112 and Pdx is important for the conformational change. The mutations did not change a coupling ratio between the hydroxylation product and oxygen consumed. We interpret these findings to mean that the interaction of P450cam with Pdx through Arg112 enhances electron donation from the proximal ligand (Cys357) to the O-O bond of iron-bound O(2) and, possibly, promotes electron transfer from reduced Pdx to oxyP450cam, thereby facilitating the O-O bond splitting.

Crystallization of proteins from soluble cytochrome P-450cam to membrane protein cytochrome bc1 complex

Crystallization of proteins from soluble cytochrome P-450cam to membrane protein cytochrome bc1 complex

Compressibility and uncoupling of cytochrome P450cam: high pressure FTIR and activity studies

The effect of the hydrostatic pressure on the CO ligand stretch vibration in cytochrome P450cam-CO bound with various substrates is studied by FTIR. The vibration frequency is linearily shifted to lower values with increasing pressure. The slope of the shift gives the isothermal compressibility of the heme pocket and is found to be related to the high-spin state content in an opposite direction to that previously observed from the pressure-induced shift of the Soret band. This opposite behaviour is explained by the dual effect of heme pocket water molecules both on the CO ligand and on electrostatic potentials produced by the protein at the distal side. The latter effect disturbs ligand-distal side contacts which are needed for a specific proton transfer in oxygen activation when dioxygen is the ligand. Their loss results in uncoupled H 2O 2 formation.

Crystal Structure of Putidaredoxin, the [2Fe–2S] Component of the P450cam Monooxygenase System from Pseudomonas putida

Stability of the [2Fe–2S]-containing putidaredoxin (Pdx), the electron donor to cytochrome P450cam in Pseudomonas putida, was improved by mutating non-ligating cysteine residues, Cys73 and Cys85, to serine singly and in combination. The increasing order of stability is Cys73Ser/Cys85Ser>Cys73Ser>Cys85Ser>WT Pdx. Crystal structures of Cys73Ser/Cys85Ser and Cys73Ser mutants of Pdx, solved by single-wavelength anomalous dispersion phasing using the [2Fe–2S] iron atoms to 1.47 Å and 1.65 Å resolution, respectively, are nearly identical and very similar to those of bovine adrenodoxin (Adx) and Escherichia coli ferredoxin. However, unlike the Adx structure, no motion between the core and interaction domains of Pdx is observed. This higher conformational stability of Pdx might be due to the presence of a more extensive hydrogen bonding network at the interface between the two structural domains around the conserved His49. In particular, formation of a hydrogen bond between the side-chain of Tyr51 and the carbonyl oxygen atom of Glu77 and the presence of two well-ordered water molecules linking the interaction domain and the C-terminal peptide to the core of the molecule are unique to Pdx. The folding topology of the NMR model is similar to that of the X-ray structure of Pdx. The overall rmsd of C α positions between the two models is 1.59 Å. The largest positional differences are observed for residues 18–21 and 33–37 in the loop regions and the C terminus. The latter two peptides display conformational heterogeneity in the crystal structures. Owing to flexibility, the aromatic ring of the C-terminal Trp106 can closely approach the side-chains of Asp38 and Thr47 (3.2–3.9 Å) or move away and leave the active site solvent-exposed. Therefore, Trp106, previously shown to be important in the Pdr-to-Pdx and Pdx-to-P450cam electron transfer reactions is in a position to regulate and/or mediate electron transfer to or from the [2Fe–2S] center of Pdx.

Crystallographic Studies on the Complex Behavior of Nicotine Binding to P450cam (CYP101)†

Crystallographic and spectroscopic studies have been undertaken to characterize the binding behavior of the non-native substrate nicotine in the active site of the monooxygenase hemoprotein cytochrome P450cam. Despite the existence of a theoretical model that is consistent with the observed distribution of monooxygenation products, the crystal structure of the complex indicates that the primary binding mode of nicotine is unproductive. The structure is confirmed by spectral data that indicate direct coordination of substrate pyridine nitrogen with the heme iron. This would be the proper structure for evaluating binding affinity and inhibition. Reduction of the heme from Fe(III) to Fe(II) and introduction of carbon monoxide into crystals of the nicotine-P450cam complex, to simulate molecular oxygen binding, produces reorientation of the nicotine. This orientation is the appropriate one for predicting regioselectivity and the kinetic features of substrate oxidation. While it is not clear that such complicated behavior will be exhibited for other enzyme-substrate interactions, it is clear that a single crystal structure for a given substrate-enzyme interaction may not provide a good description of the binding mode responsible for product formation.

Nanosecond photoreduction of cytochrome p450cam by channel-specific Ru-diimine electron tunneling wires.

We report the synthesis and characterization of Ru-diimine complexes designed to bind to cytochrome p450cam (CYP101). The sensitizer core has the structure [Ru(L(2))L'](2+), where L' is a perfluorinated biphenyl bridge (F(8)bp) connecting 4,4'-dimethylbipyridine to an enzyme substrate (adamantane, F(8)bp-Ad), a heme ligand (imidazole, F(8)bp-Im), or F (F(9)bp). The electron-transfer (ET) driving force (-deltaG degrees ) is varied by replacing the ancillary 2,2'-bipyridine ligands with 4,4',5,5'-tetramethylbipyridine (tmRu). The four complexes all bind p450cam tightly: Ru-F(8)bp-Ad (1, K(d) = 0.077 microM); Ru-F(8)bp-Im (2, K(d) = 3.7 microM); tmRu-F(9)bp (3, K(d) = 2.1 microM); and tmRu-F(8)bp-Im (4, K(d) = 0.48 microM). Binding is predominantly driven by hydrophobic interactions between the Ru-diimine wires and the substrate access channel. With Ru-F(8)bp wires, redox reactions can be triggered on the nanosecond time scale. Ru-wire 2, which ligates the heme iron, shows a small amount of transient heme photoreduction (ca. 30%), whereas the transient photoreduction yield for 4 is 76%. Forward ET with 4 occurs in roughly 40 ns (k(f) = 2.8 x 10(7) s(-)(1)), and back ET (Fe(II) --> Ru(III), k(b) approximately 1.7 x 10(8) s(-)(1)) is near the coupling-limited rate (k(max)). Direct photoreduction was not observed for 1 or 3. The large variation in ET rates among the Ru-diimine:p450 conjugates strongly supports a through-bond model of Ru-heme electronic coupling.

Effect of camphor on the stability of heme in cytochrome P450cam: Urea mediated unfolding studies

Effect of camphor on the stability of heme in cytochrome P450cam: Urea mediated unfolding studies

Engineering substrate recognition in catalysis by cytochrome P450cam.

We have a continuing interest in applying the current knowledge of cytochrome P450cam substrate recognition to engineer the enzyme for the biotransformation of unnatural substrates with the long-term aim of applications in the synthesis of fine chemicals and bioremediation of environmental contaminants. Comparisons of the structure of target substrates with that of camphor, the natural substrate, led to the design of active-site mutants with greatly enhanced activity for the oxidation of chlorinated benzenes and selectivity of (+)-alpha-pinene oxidation. The crystal structures of the F87W/Y96F/V247L mutant with 1,3,5-trichlorobenzene or (+)-alpha-pinene bound have revealed the enzyme-substrate contacts and provided insights into the activity and selectivity patterns. The structures have also provided a novel basis for further engineering of P450cam for increased activity in the oxidation of the highly inert pentachlorobenzene and hexachlorobenzene, and increased selectivity of (+)-alpha-pinene oxidation.

Remote Effects Modulating the Spin Equilibrium of the Resting State of Cytochrome P450cam –An Investigation Using Active Site Analogues

AbstractThe crystal structure of the resting state of cytochrome P450cam (CYP101), a heme thiolate protein, shows a cluster of six water molecules in the substrate binding pocket, one of which is coordinating to iron(III) as sixth ligand. The resting state is low‐spin and changes to high‐spin when substrate camphor binds and H2O is removed. In contrast to the protein, previously synthesised enzyme models such as H2OFeIII(porph)(ArS−) were shown to be purely high‐spin. Iron(S−)porphyrins with different distal sites mimicking proposed remote effects have been prepared and studied by cw‐EPR. The results indicate that the low‐spin of the resting state of P450cam is due to the fact that the water molecule coordinating to iron has an OH−‐like character because of hydrogen bonding and polarisation of the water cluster, respectively.

A model for effector activity in a highly specific biological electron transfer complex: the cytochrome P450(cam)-putidaredoxin couple.

The camphor hydroxylase cytochrome P450(cam) (CYP101) catalyzes the 5-exo hydroxylation of camphor in the first step of camphor catabolism by Pseudomonas putida. CYP101 forms a specific electron transfer complex with its physiological reductant, the Cys(4)Fe(2)S(2) ferredoxin putidaredoxin (Pdx). Pdx, along with other proteins and small molecules, has also been shown to be an effector for turnover by CYP101. Multidimensional nuclear magnetic resonance (NMR) techniques have been used to make extensive sequential (1)H, (15)N, and (13)C resonance assignments in CYP101 that permit a more complete characterization of the complex formed by CYP101 and Pdx. NMR-detected perturbations in CYP101 upon Pdx binding encompass regions of the CYP101 remote from the putative Pdx binding site, including in particular a region of the CYP101 molecule that has been implicated in substrate access to the active site via dynamical processes. A model for effector activity is proposed in which the primary role of the effector is to prevent uncoupling (formation of reduced oxo species without formation of hydroxycamphor) by enforcing conformations of CYP101 that prevent loss of substrate and/or intermediates prior to turnover. A secondary role could also be to enforce conformations that permit efficient proton transfer into the active site for coupled proton/electron transfer.

Protein side-chain motion and hydration in proton-transfer pathways. Results for cytochrome p450cam.

Proton-transfer reactions form an integral part of bioenergetics and enzymatic catalysis. The identification of proton-conducting pathways inside a protein is a key to understanding the mechanisms of biomolecular proton transfer. Proton pathways are modeled here as hydrogen bonded networks of proton-conducting groups, including proton-exchanging groups of amino acid side chains and bound water molecules. We focus on the identification of potential proton-conducting pathways inside a protein of known structure. However, consideration of the static structure alone is often not sufficient to detect suitable proton-transfer paths, leading, for example, from the protein surface to the active site buried inside the protein. We include dynamic fluctuations of amino acid side chains and water molecules into our analysis. To illustrate the method, proton transfer into the active site of cytochrome P450cam is studied. The cooperative rotation of amino acids and motion of water molecules are found to connect the protein surface to the molecular oxygen. Our observations emphasize the intrinsic dynamical nature of proton pathways where critical connections in the network may be transiently provided by mobile groups.

Epoxidation of olefins by hydroperoxo-ferric cytochrome P450.

The T252A mutant of cytochrome P450cam is unable to form the oxoferryl "active oxygen" intermediate, as judged by its inability to hydroxylate its normal substrate, camphor. In the present study, we demonstrate that T252A P450cam is nonetheless able to epoxidize olefins, due to the action of a second oxidant. However, as shown in earlier radiolytic studies and by the ability of T252A to reduce dioxygen to hydrogen peroxide, the mutant retains the ability to form the hydroperoxo-ferric reaction cycle intermediate. The present results provide strong evidence that hydroperoxo-ferric P450 can serve as a second electrophilic oxidant capable of olefin epoxidation.

Toxicity screening by electrochemical detection of DNA damage by metabolites generated in situ in ultrathin DNA-enzyme films.

Rapid detection of DNA damage could serve as a basis for in vitro genotoxicity screening for new organic compounds. Ultrathin films (20-40 nm) containing myoglobin or cytochrome P450(cam) and DNA grown layer-by-layer on electrodes were activated by hydrogen peroxide, and the enzyme in the film generated metabolite styrene oxide from styrene. This styrene oxide reacted with double stranded (ds)-DNA in the same film, mimicking metabolism and DNA damage in human liver. DNA damage was detected by square wave voltammetry (SWV) by using catalytic oxidation with Ru(bpy)(3)(2+) (bpy = 2,2'-bipyridine) and by monitoring the binding of Co(bpy)(3)(3+). Damaged DNA reacts more rapidly than intact ds-DNA with Ru(bpy)(3)(3+), giving SWV peaks at approximately 1 V versus SCE that grow larger with reaction time. Co(bpy)(3)(3+) binds more strongly to intact ds-DNA, and its SWV peaks at 0.04 V decreased as DNA was damaged. Little change in SWV signals was found for incubations of DNA/enzyme films with unreactive organic controls or hydrogen peroxide. Capillary electrophoresis and HPLC-MS suggested the formation of styrene oxide adducts of DNA bases under similar reaction conditions in thin films and in solution. The catalytic SWV method was more sensitive than the Co(bpy)(3)(3+) binding assay, providing multiple measurements over a 5 min reaction time.

Optimization of electrochemical and peroxide-driven oxidation of styrene with ultrathin polyion films containing cytochrome P450cam and myoglobin.

The catalytic and electrochemical properties of myoglobin and cytochrome P450(cam) in films constructed with alternate polyion layers were optimized with respect to film thickness, polyion type, and pH. Electrochemical and hydrogen peroxide driven epoxidation of styrene catalyzed by the proteins was used as the test reaction. Ionic synthetic organic polymers such as poly(styrene sulfonate), as opposed to SiO(2) nanoparticles or DNA, supported the best catalytic and electrochemical performance. Charge transport involving the iron heme proteins was achieved over 40-320 nm depending on the polyion material and is likely to involve electron hopping facilitated by extensive interlayer mixing. However, very thin films (ca. 12-25 nm) gave the largest turnover rates for the catalytic epoxidation of styrene, and thicker films were subject to reactant transport limitations. Classical bell-shaped activity/pH profiles and turnover rates similar to those obtained in solution suggest that films grown layer-by-layer are applicable to turnover rate studies of enzymes for organic oxidations. Major advantages include enhanced enzyme stability and the tiny amount of protein required.

Engineering cytochrome P450cam into an alkane hydroxylase

The haem monooxygenase cytochrome P450cam from Pseudomonas putida has been engineered into an alkane hydroxylase. Active site amino acid residues were substituted with residues that have bulkier and more hydrophobic side-chains. The residues F87, Y96, V247 and V396, which are further away from the haem, were targeted first for substitution in order to constrain the small alkanes n-butane and propane to bind closer to the haem. We found that just two mutations could increase the alkane oxidation activity of P450cam by two orders of magnitude. The F87W/Y96F/V247L triple mutant was then used as a basis for introducing further substitutions, at the residues T101, L244, V395 and D297 which are closer to the haem, to improve the enzyme/alkane fit and hence the alkane hydroxylase activity. The F87W/Y96F/T101L/V247L mutant oxidised n-butane with a catalytic turnover rate of 755 nmol(nmol P450cam)−1(min)−1, which is comparable to the camphor oxidation activity of the wild-type (1000 min−1). The F87W/Y96F/T101L/L244M/V247L mutant had lower n-butane oxidation activity but the highest propane oxidation rate (176 min−1) of the P450cam enzymes studied. All P450cam enzymes gave 2-butanol and 2-propanol as the only products. Determination of the extent of uncoupling showed that hydrogen peroxide generation was the dominant uncoupling mechanism. The data indicate that further mutations at residues higher up in the active site are required to localise the substrates close to the haem and to reduce substrate mobility. These next-generation mutants will have higher activity, and may be able to catalyse the oxidation of ethane and methane.

The origin of the low-spin character of the resting state of cytochrome P450cam investigated by means of active site analogues.

Crown-capped iron(S-) porphyrins 1 x H2O and 2 x H2O and their corresponding Ba2+ complexes have been prepared as active site analogues of the resting state of cytochrome P450cam. cw-EPR studies and electronic structure calculations at the density functional theory (DFT) level of model systems suggest a functional role of the water cluster of P450cam.

Molecular recognition in (+)-alpha-pinene oxidation by cytochrome P450cam.

Oxygenated derivatives of the monoterpene (+)-alpha-pinene are found in plant essential oils and used as fragrances and flavorings. (+)-alpha-Pinene is structurally related to (+)-camphor, the natural substrate of the heme monooxygenase cytochrome P450(cam) from Pseudomonas putida. The aim of the present work was to apply the current understanding of P450 substrate binding and catalysis to engineer P450(cam) for the selective oxidation of (+)-alpha-pinene. Consideration of the structures of (+)-camphor and (+)-alpha-pinene lead to active-site mutants containing combinations of the Y96F, F87A, F87L, F87W, and V247L mutations. All mutants showed greatly enhanced binding and rate of oxidation of (+)-alpha-pinene. Some mutants had tighter (+)-alpha-pinene binding than camphor binding by the wild-type. The most active was the Y96F/V247L mutant, with a (+)-alpha-pinene oxidation rate of 270 nmol (nmol of P450(cam))(-)(1) min(-)(1), which was 70% of the rate of camphor oxidation by wild-type P450(cam). Camphor is oxidized by wild-type P450(cam) exclusively to 5-exo-hydroxycamphor. If the gem dimethyl groups of (+)-alpha-pinene occupied similar positions to those found for camphor in the wild-type structure, (+)-cis-verbenol would be the dominant product. All P450(cam) enzymes studied gave (+)-cis-verbenol as the major product but with much reduced selectivity compared to camphor oxidation by the wild-type. (+)-Verbenone, (+)-myrtenol, and the (+)-alpha-pinene epoxides were among the minor products. The crystal structure of the Y96F/F87W/V247L mutant, the most selective of the P450(cam) mutants initially examined, was determined to provide further insight into P450(cam) substrate binding and catalysis. (+)-alpha-Pinene was bound in two orientations which were related by rotation of the molecule. One orientation was similar to that of camphor in the wild-type enzyme while the other was significantly different. Analysis of the enzyme/substrate contacts suggested rationalizations of the product distribution. In particular competition rather than cooperativity between the F87W and V247L mutations and substrate movement during catalysis were proposed to be major factors. The crystal structure lead to the introduction of the L244A mutation to increase the selectivity of pinene oxidation by further biasing the binding orientation toward that of camphor in the wild-type structure. The F87W/Y96F/L244A mutant gave 86% (+)-cis-verbenol and 5% (+)-verbenone. The Y96F/L244A/V247L mutant gave 55% (+)-cis-verbenol but interestingly also 32% (+)-verbenone, suggesting that it may be possible to engineer a P450(cam) mutant that could oxidize (+)-alpha-pinene directly to (+)-verbenone. Verbenol, verbenone, and myrtenol are naturally occurring plant fragrance and flavorings. The preparation of these compounds by selective enzymatic oxidation of (+)-alpha-pinene, which is readily available in large quantities, could have applications in synthesis. The results also show that the protein engineering of P450(cam) for high selectivity of substrate oxidation is more difficult than achieving high substrate turnover rates because of the subtle and dynamic nature of enzyme-substrate interactions.

Atomic force microscopy detection of molecular complexes in multiprotein P450cam containing monooxygenase system.

The application of atomic force microscopy (AFM) technique in proteomic research, identification and visualization of individual molecules and molecular complexes within the P450cam containing monooxygenase system was demonstrated. The method distinguishes between the binary protein complexes and appropriate monomeric proteins and, also, between the binary and ternary complexes. The AFM images of the components of a cytochrome P450cam containing monooxygenase system - cytochrome P450cam (P450cam), putidaredoxin (Pd) and putidaredoxin reductase (PdR) - were obtained on a mica support. The molecules of P450cam, Pd and PdR were found to have typical heights of 2.6 +/- 0.3 nm, 2.0 +/- 0.3 and 2.8 +/- 0.3 nm, respectively. The measured heights of the binary Pd/PdR and P450cam/PdR complexes were 4.9 +/- 0.3 nm and 5.1 +/- 0.3 nm, respectively. The binary P450cam/Pd complexes were found to have a typical height of about (3.9 / 5.7 nm) and the ternary PdR/Pd/P450cam complexes, a typical height of about 9.1 +/- 0.3 nm.

Structural alterations of the heme environment of cytochrome P450cam and the Y96F mutant as deduced by resonance Raman spectroscopy.

Resonance Raman spectroscopy at 2.5cm(-1) resolution was used to probe differences in wild-type and Y96F mutant P450cam (CYP101), both with and without bound camphor or styrene substrates. In the substrate-free state, the spin state equilibrium is shifted from 6-coordinate low spin (6CLS) toward more 5-coordinate high spin (5CHS) when tyrosine-96 in the substrate pocket is replaced by phenylalanine. About 25% of substrate-free Y96F mutant is 5CHS as opposed to 8% for substrate-free wild-type P450cam. Spin equilibrium constants calculated from Raman intensities indicate that the driving force for electron transfer from putidaredoxin, the natural redox partner of P450cam, is significantly smaller on styrene binding than for camphor binding. Spectral differences suggest that there is a tilt in camphor toward the pyrrole III ring on Y96F mutation. This finding is consistent with the altered product distribution found for camphor hydroxylation by the Y96F mutant relative to the single enantiomer produced by the wild-type enzyme.

Role of protein and substrate dynamics in catalysis by Pseudomonas putida cytochrome P450cam.

The role of protein structural flexibility and substrate dynamics in catalysis by cytochrome P450 enzymes is an area of current interest. We have addressed these in cytochrome P450(cam) (P450(cam)) and its Y96A mutant with camphor and its related compounds using fluorescence spectroscopy. Previously [Prasad et al. (2000) FEBS Lett. 477, 157-160], we provided experimental support to dynamic fluctuations in P450(cam), and substrate access into the active site region via the channel next to the flexible F-G helix-loop-helix segment. In the investigation described here, we show that the dynamic fluctuations in the enzyme are substrate dependent as reflected by tryptophan fluorescence quenching experiments. The orientation of tryptophan relative to heme (kappa(2)) for W42 obtained from time-resolved tryptophan fluorescence measurements show variation with type of substrate bound to P450(cam) suggesting regions distant from heme-binding site are affected by physicochemical and steric characteristics/protein-substrate interactions of P450(cam) active site. We monitored substrate dynamics in the active site region of P450(cam) by time-resolved substrate anisotropy measurements. The anisotropy decay of substrates bound to P450(cam) indicate that mobility of substrates is modulated by physicochemical and steric characteristics/protein-substrate interactions of local active site structure, and provides an understanding of factors controlling observed hydroxylated products for substrate bound P450(cam) complexes. The present study shows that P450(cam) local and peripheral structural flexibility and heterogeneity along with substrate mobility play an important role in regulating substrate binding orientation during catalysis and accommodating diverse range of substrates within P450(cam) heme pocket.