Reactivities of organic phase biosensors: 6. Square-wave and differential pulse studies of genetically engineered cytochrome P450(cam) (CYP101) bioelectrodes in selected solvents

Cytochrome P450(cam) (CYP101) bioelectrodes suitable for application in organic phases were prepared from genetically engineered CYP101 and vesicular dispersions of didodecyldimethylammonium bromide. The amperometric biosensor system was characterised under anaerobic conditions by cyclic and square-wave voltammetric methods. Cyclic- and square-wave-voltammetry studies showed that the biosensors exhibited direct reversible electron transfer between the haem iron atom and the glassy carbon electrode surface. The formal redox potential estimated for the electrode in acetonitrile was -380 mV/Ag-AgCl. The formal potential shifted anodically as the organic phase biosensor responded irreversibly to substrate (camphor) under anaerobic and aerobic conditions in acetonitrile. Differential pulse analysis of the reactivities of the CYP101 enzyme electrode confirmed the square-wave voltammetry result, which showed that the binding of substrate decreased the redox potential necessary for initiating the monooxygenation reaction of cytochrome P450(cam).     

Crystal structure of substrate-free Pseudomonas putida cytochrome P-450

The crystal structure of Pseudomonas putida cytochrome P-450cam in the substrate-free form has been refined at 2.20-A resolution and compared to the substrate-bound form of the enzyme. In the absence of the substrate camphor, the P-450cam heme iron atom is hexacoordinate with the sulfur atom of Cys-357 providing one axial heme ligand and a water molecule or hydroxide ion providing the other axial ligand. A network of hydrogen-bonded solvent molecules occupies the substrate pocket in addition to the iron-linked aqua ligand. When a camphor molecule binds, the active site waters including the aqua ligand are displaced, resulting in a pentacoordinate high-spin heme iron atom. Analysis of the Fno camphor - F camphor difference Fourier and a quantitative comparison of the two refined structures reveal that no detectable conformational change results from camphor binding other than a small repositioning of a phenylalanine side chain that contacts the camphor molecule. However, large decreases in the mean temperature factors of three separate segments of the protein centered on Tyr-96, Thr-185, and Asp-251 result from camphor binding. This indicates that camphor binding decreases the flexibility in these three regions of the P-450cam molecule without altering the mean position of the atoms involved.     

Effect of alcohols on binding of camphor to cytochrome P450cam: spectroscopic and stopped flow transient kinetic studies

Addition of alcohols to cytochrome P450cam (CYP101) was shown to release the substrate camphor from the heme pocket of the enzyme. The release of the substrate was found to be caused both due to increased solubility of the substrate in solution in presence of alcohol and due to change in the tertiary structure of the active site of the enzyme. The far-UV CD and near-UV CD spectra reveal that addition of alcohols to cytochrome P450cam cause a small change in the secondary structural elements but a significant change in the tertiary structural organization of this enzyme. The CD spectra at the heme region at various concentrations of alcohols indicate a substantial change in the tertiary structural organization around the heme moiety too. The equilibrium constant associated with the binding of camphor to Cyt P450cam is strongly dependent on the concentration of alcohols and the corresponding free energy associated with the binding is found to scale linearly with the concentration of alcohols. Kinetic experiments on binding of camphor to Cyt P450cam show that both k(on) and k(off) rate constants are strongly affected by addition of alcohols suggesting that alcohol expel camphor out of the heme cavity of Cyt P450cam by affecting tertiary structure of Cyt P450cam as well as by modifying the solubility properties of camphor in aqueous medium.     

The 2.6-A crystal structure of Pseudomonas putida cytochrome P-450

The crystal structure of Pseudomonas putida cytochrome P-450cam in the ferric, camphor bound form has been determined and partially refined to R = 0.23 at 2.6 A. The single 414 amino acid polypeptide chain (Mr = 45,000) approximates a triangular prism with a maximum dimension of approximately 60 A and a minimum of approximately 30 A. Twelve helical segments (A through L) account for approximately 40% of the structure while antiparallel beta pairs account for only approximately 10%. The unexposed iron protoporphyrin IX is sandwiched between two parallel helices designated the proximal and distal helices. The heme iron atom is pentacoordinate with the axial sulfur ligand provided by Cys 357 which extends from the N-terminal end of the proximal (L) helix. A substrate molecule, 2-bornanone (camphor), is buried in an internal pocket just above the heme distal surface adjacent to the oxygen binding site. The substrate molecule is held in place by a hydrogen bond between the side chain hydroxyl group of Tyr 96 and the camphor carbonyl oxygen atom in addition to complementary hydrophobic contacts between the camphor molecule and neighboring aliphatic and aromatic residues. The camphor is oriented such that the exo-surface of C5 would contact an iron bound, "activated" oxygen atom for stereoselective hydroxylation.     

A recombinant Escherichia coli whole cell biocatalyst harboring a cytochrome P450cam monooxygenase system coupled with enzymatic cofactor regeneration

A cytochrome P450cam monooxygenase (P450cam) system from the soil bacterium Pseudomonas putida requires electron transfer among three different proteins and a cofactor, nicotinamide adenine dinucleotide (NADH), for oxygenation of its natural substrate, camphor. Herein, we report a facile way to significantly enhance the catalytic efficiency of the P450cam system by the coupling of its native electron transfer system with enzymatic NADH regeneration catalyzed by glycerol dehydrogenase (GLD) in Escherichia coli whole cell biocatalysts. Recombinant E. coli harboring the P450cam system, but lacking GLD, exhibited little activity for camphor hydroxylation. In contrast, coexpression of GLD with the proteinaceous electron transfer components of P450cam resulted in about tenfold improvement in the substrate conversion, implying that the whole cell biocatalyst utilized molecular oxygen, endogenous NADH, and glycerol in the cell for catalysis. The addition of glycerol to the reaction media further promoted camphor hydroxylation, suggesting that exogenous glycerol is also available for GLD in the host cell and actively participates in the catalytic cycle. These results clearly show the utility of GLD towards functional reconstruction of the native P450cam system. The present approach may also be useful for E. coli whole cell biocatalysts with the other NADH-dependent oxygenases and oxidoreductases.     

Substrate modulates compound I formation in peroxide shunt pathway of Pseudomonas putida cytochrome P450(cam)

The active oxygenating intermediate, a ferryl-oxo-(II) porphyrin cation radical (compound I), in substrate-bound cytochrome P450(cam) (P450(cam)) has eluded detection and kinetic analysis for several decades. Upon rapid mixing of peroxides-H(2)O(2) and m-CPBA with substrate-bound forms of P450(cam), we observed an intermediate with spectral features characteristic of compound I. Unlike in H(2)O(2), kinetic investigation on the reaction of m-CPBA with various substrate (camphor, adamantone, and norcamphor)-bound P450(cam) and its Y96A mutant shows a preferential binding of the aromatic end group of m-CPBA to the active-site of the enzyme and modulation of compound I formation by the local environment of heme active-site. The results presented in this paper describe the importance of heme environment in modulating formation of compound I, and form the first kinetic analysis of this intermediate in the peroxide shunt pathway of substrate-bound P450(cam).     

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.     

Spring-loading the active site of cytochrome P450cam

A hydrogen bond network has been identified that adjusts protein-substrate contacts in cytochrome P450(cam) (CYP101A1). Replacing the native substrate camphor with adamantanone or norcamphor causes perturbations in NMR-detected NH correlations assigned to the network, which includes portions of a β sheet and an adjacent helix that is remote from the active site. A mutation in this helix reduces enzyme efficiency and perturbs the extent of substrate-induced spin state changes at the haem iron that accompany substrate binding. In turn, the magnitude of the spin state changes induced by alternate substrate binding parallel the NMR-detected perturbations observed near the haem in the enzyme active site.     

Mutations of glutamate-84 at the putative potassium-binding site affect camphor binding and oxidation by cytochrome p450cam.

Cytochrome P450cam (CYP101) from Pseudomonas putida is unusual among P450 enzymes in that it exhibits co-operative binding between the substrate camphor and a potassium ion. This behaviour has been investigated by mutagenesis of Glu84, a surface residue which forms part of the cation-binding site. Substitutions that neutralize or reverse the charge of this side chain are shown to disrupt the co-operativity of potassium and camphor binding by P450cam, and also to influence the catalytic activity. In particular, replacement of Glu84 by positively charged residues such as lysine results in increased high-spin haem fractions and camphor turnover activities in the absence of potassium, along with decreased camphor dissociation constants. However, in the presence of potassium the camphor dissociation constants of these mutants are significantly increased compared with the wild-type, although the camphor turnover activities remain marginally higher. In contrast, substitution by aspartate results in tighter binding of both potassium and camphor, but has little effect on the enzymatic activity. In all cases the reaction remains essentially 100% coupled and gives 5-exo-hydroxycamphor as the only product. These results suggest that an anionic side chain at the 84 position is crucial for the co-operativity of camphor and cation binding, and that the physiological role for potassium binding by cytochrome P450cam is to promote camphor binding even at the expense of turnover rate, thus allowing the organism to utilize low environmental concentrations of this substrate for growth.     

Molecular modeling of the 3-D structure of cytochrome P-450scc.

Sequence-alignment studies of the bovine mitochondrial cholesterol side-chain cleavage enzyme cytochrome P-450scc with the bacterial cytochrome P-450cam (camphor hydroxylating enzyme) have been undertaken. Our novel alignment of the sequences revealed 69 identical residues and many highly conserved regions. The results of the sequence alignment studies were used to model the 3-D structure of P-450scc based on the available crystal structure of P-450cam. The major insertions in the sequence are found mainly on four external-loop regions of the molecule, while the core structure of P-450cam is retained with subtle internal modifications. The most hydrophobic of these four external loops is proposed as a candidate for membrane attachment.     

Proximal cysteine residue is essential for the enzymatic activities of cytochrome P450cam.

To investigate the functional and structural roles of the proximal thiolate ligand in cytochrome P450cam, we prepared the C357H mutant of the enzyme in which the axial cysteine residue (Cys357) was replaced with a histidine residue. We obtained the unstable C357H mutant by developing a new preparation procedure involving in vitro folding of P450cam from the inclusion bodies. The C357H mutant in the ferrous-CO form exhibited the Soret peak at 420 nm and the Fe-CO stretching line at 498 cm-1, indicating a neutral histidine residue as the axial ligand. However, another internal ligand is coordinated to the heme iron as the sixth ligand in the ferric and ferrous forms of the C357H mutant, suggesting the collapse of the substrate-binding site. The C357H mutant showed no catalytic activity for camphor hydroxylation and the reduced heterolytic/homolytic ratio of the O-O bond scission in the reaction with cumene hydroperoxide. The present observations indicate that the thiolate coordination in P450cam is important for the construction of the heme pocket and the heterolysis of the O-O bond.     

The roles of active site hydrogen bonding in cytochrome P-450cam as revealed by site-directed mutagenesis

The role of the active site hydrogen bond of cytochrome P-450cam has been studied utilizing a combination of site-directed mutagenesis and substrate analogues with altered hydrogen bonding capabilities. Cytochrome P-450cam normally catalyzes the regiospecific hydroxylation of the monoterpene camphor. The x-ray crystal structure of this soluble bacterial cytochrome P-450 (Poulos, T. L., Finzel, B. C., Gunsalus, I. C., Wagner, G. C., and Kraut, J. (1985) J. Biol. Chem. 260, 16122-16128) indicates a specific hydrogen bond between tyrosine 96 and the carbonyl moiety of the camphor substrate. The site-directed mutant in which tyrosine 96 has been changed to a phenylalanine and the substrate analogues thiocamphor and camphane have been used to probe this interaction in several aspects of catalysis. At room temperature, both the mutant enzyme with camphor and the wild type enzyme with thiocamphor bound result in 59 and 65% high-spin ferric enzyme as compared to the 95% high spin population obtained with native enzyme and camphor as substrate. The equilibrium dissociation constant is moderately increased, from 1.6 microM for the wild type protein to 3.0 and 3.3 microM for wild type-thiocamphor and mutant-camphor complexes, respectively. Camphane bound to cytochrome P-450cam exhibits a larger decrease in high spin fraction (45%) and a correspondingly larger KD (46 microM), suggesting that the carbonyl moiety of camphor plays an important steric role in addition to its interaction as a hydrogen bond acceptor. The absolute regioselectivity of the mutant enzyme, and of the wild type enzyme with thiocamphor, is lost resulting in production of several hydroxylated products in addition to the 5-exo-hydroxy isomer. Based on rates of NADH oxidation, comparison of the substrate specificity for these systems (kcat/KD) indicates a 5- and 7-fold decrease in specificity for the mutant enzyme and thiocamphor-wild type complex, respectively. The replacement of the cytochrome P-450cam active site tyrosine with phenylalanine does not affect the branching ratio of monooxygenase versus oxidase chemistry or peroxygenase activity (Atkins, W.M., and Sligar, S.G. (1987) J. Am. Chem. Soc. 109, 3754-3760).     

Structural evidence for a functionally relevant second camphor binding site in P450cam: model for substrate entry into a P450 active site

P450cam has long served as a prototype for the cytochrome P450 (CYP) gene family. But, little is known about how substrate enters its active site pocket, and how access is achieved in a way that minimizes exposure of the reactive heme. We hypothesize that P450cam may first bind substrate transiently near the mobile F-G helix that covers the active site pocket. Such a two-step binding process is kinetically required if P450cam rarely populates an open conformation-as suggested by previous literature and the inability to obtain a crystal structure of P450cam in an open conformation. Such a mechanism would minimize exposure of the heme by allowing P450cam to stay in a closed conformation as long as possible, since only brief flexing into an open conformation would be required to allow substrate entry. To test this model, we have attempted to dock a second camphor molecule into the crystal structure of camphor-bound P450cam. The docking identified only one potential entry site pocket, a well-defined cavity on the F-helix side of the F-G flap, 16 A from the heme iron. Location of this entry site pocket is consistent with our NMR T1 relaxation-based measurements of distances for a camphor that binds in fast exchange (active site camphor is known to bind in slow exchange). Presence of a second camphor binding site is also confirmed with [(1)H-(13)C] HSQC titrations of (13)CH3-threonine labeled P450cam. To confirm that camphor can bind outside of the active site pocket, (13)CH3-S-pyridine was bound to the heme iron to physically block the active site, and to serve as an NMR chemical shift probe. Titration of this P450cam-pyridine complex confirms that camphor can bind to a site outside the active site pocket, with an estimated Kd of 43 microM. The two-site binding model that is proposed based on these data is analogous to that recently proposed for CYP3A4, and is consistent with recent crystal structures of P450cam bound to tethered-substrates, which force a partially opened conformation.     

Binding sites of pyridine in cytochrome P-450cam

Careful titration of oxidized cytochrome P-450cam from Pseudomonas putida with pyridine revealed deviations of the Eadie plot from linearity in the substrate-bound as well as in the substrate-free protein. A binding model which assumes two binding sites for pyridine--the iron and the camphor binding site--is able to describe completely the nonlinear Eadie plot.     

Protein engineering of cytochrome p450(cam) (CYP101) for the oxidation of polycyclic aromatic hydrocarbons

Mutations of the active site residues F87 and Y96 greatly enhanced the activity of cytochrome P450(cam) (CYP101) from Pseudomonas putida for the oxidation of the polycyclic aromatic hydrocarbons phenanthrene, fluoranthene, pyrene and benzo[a]pyrene. Wild-type P450(cam) had low (<0.01 min(-1)) activity with these substrates. Phenanthrene was oxidized to 1-, 2-, 3- and 4-phenanthrol, while fluoranthene gave mainly 3-fluoranthol. Pyrene was oxidized to 1-pyrenol and then to 1,6- and 1,8-pyrenequinone, with small amounts of 2-pyrenol also formed with the Y96A mutant. Benzo[a]pyrene gave 3-hydroxybenzo[a]pyrene as the major product. The NADH oxidation rate of the mutants with phenanthrene was as high as 374 min(-1), which was 31% of the camphor oxidation rate by wild-type P450(cam), and with fluoranthene the fastest rate was 144 min(-1). The oxidation of phenanthrene and fluoranthene were highly uncoupled, with highest couplings of 1.3 and 3.1%, respectively. The highest coupling efficiency for pyrene oxidation was a reasonable 23%, but the NADH turnover rate was slow. The product distributions varied significantly between mutants, suggesting that substrate binding orientations can be manipulated by protein engineering, and that genetic variants of P450(cam) may be useful for studying the oxidation of polycyclic aromatic hydrocarbons by P450 enzymes.     

Biodehalogenation: reactions of cytochrome P-450 with polyhalomethanes

The products, stoichiometry, and kinetics of the oxidation of the enzyme cytochrome P-450 cam by five polyhalomethanes and chloronitromethane are described. The reactivity of the enzyme is compared with that of deuteroheme and with the enzyme in its native cell, Pseudomonas putida (PpG-786). In all cases, the reaction entails hydrogenolysis of the carbon-halogen bond: 2FeIIP + RCXn----2FeIIIP + RCHXn-1 (P = porphyrin or P-450 cam in vitro and in vivo). Trichloronitromethane was the fastest reacting substrate, and chloroform was the slowest. The results establish that P. putida is a valid whole cell model for the reductase activity of the P-450 complement in these reactions. The reactions of cytochrome P-450 with polyhaloalkanes proceed in a manner quite analogous to other iron(II) proteins in the G conformation. The chemistry observed for the enzyme parallels that of its iron(II) porphyrin active site. Iron-bonded carbenes are not intermediates, and hydrolytically stable iron alkyls are not products of these reactions.     

Occurrence of cytochrome P450 in continuous cultures of Saccharomyces cerevisiae

Summary Cytochrome P450 of Saccharomyces cerevisiae is an inducible enzyme system. Hitherto, its induction was related to semi-anaerobic culture conditions and high glucose concentrations in the growth medium respectively. Since glucose and oxygen are main regulatory effectors in this yeast, the relationship between the occurrence of cytochrome P450 and these two effectors was established in continuous culture. At glucose-derepressed conditions it was not possible to induce the formation of cytochrome P450 by oxygen limitation alone. The oxygen supply had to be decreased to a level where glucose repression also became active. At glucose-repressed conditions cytochrome P450 was obtained in good yield (3 to 5 pmol per mg dry cell weight) below a dissolved oxygen tension of appproximately 15%. There was a correlation between the content of mitochondrial cytochromes and that of cytochrome P450. The presence of mitochondrial cytochromes was reciprocal with cytochrome P450 when its content was increased by lowering the dissolved oxygen tension.     

Benign synthesis of 2-ethylhexanoic acid by cytochrome P450cam: enzymatic, crystallographic, and theoretical studies

This study examines the ability of P450cam to catalyze the formation of 2-ethylhexanoic acid from 2-ethylhexanol relative to its activity on the natural substrate camphor. As is the case for camphor, the P450cam exhibits stereoselectivity for binding (R)- and (S)-2-ethylhexanol. Kinetic studies indicate (R)-2-ethylhexanoic acid is produced 3.5 times as fast as the (S)-enantiomer. In a racemic mixture of 2-ethylhexanol, P450cam produces 50% more (R)-2-ethylhexanoic acid than (S)-2-ethylhexanoic acid. The reason for stereoselective 2-ethylhexanoic acid production is seen in regioselectivity assays, where (R)-2-ethylhexanoic acid comprises 50% of total products while (S)-2-ethylhexanoic acid comprises only 13%. (R)- and (S)-2-ethylhexanol exhibit similar characteristics with respect to the amount of oxygen and reducing equivalents consumed, however, with (S)-2-ethylhexanol turnover producing more water than the (R)-enantiomer. Crystallographic studies of P450cam with (R)- or (S)-2-ethylhexanoic acid suggest that the (R)-enantiomer binds in a more ordered state. These results indicate that wild-type P450cam displays stereoselectivity toward 2-ethylhexanoic acid synthesis, providing a platform for rational active site design.     

Electron-conformational interactions at the active site of reduced bacterial cytochrome P450cam induced by a substrate and analysis of the electron structure of heme]

Magnetic circular dichroism (MCD) spectra in the Soret region (360-480 nm) of camphor-free and camphor-bound reduced bacterial cytochrome P450cam from Pseudomonas putida were recorded and analysed in the temperature range from 2 K to 290 K. The temperature dependences of the MCD intensity are qualitatively changed by binding of substrate to the enzyme. In the absence of camphor the linear increase of the MCD intensity with 1/T at T < 4.2 K gives evidence for degeneracy or near degeneracy of the ground electronic state. In the presence of substrate the degeneracy is removed and temperature profiles show saturation behaviour at T < 4.2 K and wavelength dependence of their high-temperature parts. The temperature profiles for the long-wavelength region of the Soret band have a maximum approximately at 15 K, whereas the MCD intensity increases in a monotonous manner up to saturation in the short-wavelength region. The wavelength dependence of temperature profiles gives evidence for the co-existence of two different forms of substrate-bound reduced P450cam. The following conclusions were obtained from a theoretical analysis of the temperature profiles. In the absence of substrate there are very small if any rhombic distortions at the heme iron, and a parameter D of axial zero-field splitting is negative (D = -8.3 cm-1 and -6.2 cm-1 for P450cam and P450LM2, respectively). In the presence of substrate the two forms of reduced P450cam have positive parameters D but of different values (D1 = 12 cm-1 and D2 = 28 cm-1), and there are large rhombic distortions at the heme iron. More than two-fold difference between the D values made it possible to isolate temperature-dependent contributions of the two enzyme forms from the total MCD spectra and to simulate the alterations of the MCD spectra with temperature for reduced P450cam in the presence of substrate. Taking into account the drastic effect of substrate binding on the ground electronic state of reduced P450cam one can suggest that substrate binding induces the transition of enzyme from an inactive to an active state.     

Replacement of tyrosine residues by phenylalanine in cytochrome P450cam alters the formation of Cpd II-like species in reactions with artificial oxidants

Our previous rapid-scanning stopped-flow studies of the reaction of substrate-free cytochrome P450cam with peracids [Spolitak et al. (2005) J Biol Chem 280:20300-20309; (2006) J Inorg Biochem 100:2034-2044] spectrally characterized compound I [ferryl iron plus a porphyrin pi-cation radical (Fe(IV) = O/Por(+))], as well as Cpd ES (Fe(IV) = O/Tyr.). In the present studies, we report how the substitutions in Y75F, Y96F, and Y96F/Y75F P450cam variants permit the formation of a species we attribute to Cpd II (Fe(IV) = O) in reactions with peracids and cumene hydroperoxide. These variants produce changes in hydrogen bonding patterns and increased hydrophobicity that affect the ratio of heterolytic to homolytic pathways in reactions with cumene hydroperoxide, resulting in a shift of this ratio from 84/16 for WT to 72/28 for the Y96F/Y75F double mutant. Various ways of generating the Cpd II-like species were explored, and it was possible, especially with the more hydrophobic variants, to generate large fractions of the P450cam variants as Cpd II. The Cpd II-like species is ineffective at hydroxylating camphor, but can be readily reduced by ascorbate (as well as other peroxidase substrates) to ferric P450cam, which could then bind camphor to form the high-spin heme. The difference in the spectral properties of Cpd ES and Cpd II was rationalized as possibly being due to different states of protonation.