Cytochrome P450 active site plasticity: attenuation of imidazole binding in cytochrome P450(cam) by an L244A mutation

We have identified a P450(cam) mutation, L244A, that mitigates the affinity for imidazole and substituted imidazoles while maintaining a high affinity for the natural substrate camphor. The P450(cam) L244A crystal structure solved in the absence of any ligand reveals that the I-helix is displaced inwards by over 1 A in response to the cavity created by the change from leucine to alanine. Furthermore, the crystal structures of imidazole-bound P450(cam) and the 1-methylimidazole-bound P450(cam) L244A mutant reveal that the ligands have distinct binding modes in the two proteins. Whereas in wild-type P450(cam) the imidazole coordinates to the iron in an orientation roughly perpendicular to the plane of the heme, in the L244A mutant the rearranged I helix, and specifically residue Val247, forces the imidazole into an orientation almost parallel to the heme that impairs its ability to coordinate to the heme iron. As a result, the imidazole is much more weakly bound to the mutant than it is to the wild-type enzyme. Despite the constriction of the active site by the mutation, previous work with the L244A mutant has shown that it oxidizes larger substrates than the wild-type enzyme. This paradoxical situation, in which a mutation that nominally increases the active site cavity appears to decrease it, suggests that the mutation actually increases the active site maleability, allowing it to better expand to oxidize larger substrates.     

Intramolecular electron transfer in a cytochrome P450cam system with a site-specific branched structure

Cytochrome P450 (P450) is an attractive oxygenase due to the diverse catalytic reactions and the broad substrate specificity. Class I P450s require an excess concentration (more than 10 times) of iron-sulfur proteins, which transfer electrons to P450s, to attain the maximum catalytic activity and this requirement is a critical bottleneck for practical applications. Here, we show a site-specific branched fusion protein of P450 with its electron transfer proteins using enzymatic cross-linking with transglutaminase. A branched fusion protein of P450 from Pseudomonas putida (P450cam), which was composed of one molecule each of P450cam, putidaredoxin (Pdx) and Pdx reductase, showed higher catalytic activity (306 min(-1)) and coupling efficiency (99%) than the equimolar reconstitution system due to the intramolecular electron transfer. The unique site-specific branched structure simply increased local concentration of proteins without denaturation of each protein. Therefore, enzymatic post-translational protein manipulation can be a powerful alternative to conventional strategies for the creation of multicomponent enzyme systems with novel proteinaceous architecture.     

Engineering cytochrome P-450cam to increase the stereospecificity and coupling of aliphatic hydroxylation

Site-directed mutants were constructed in cytochrome P-450_camto re-engineer the stereochemistry and coupling of ethylbenzenehydroxyiation. The reaction with wild-type (WT) enzyme producesone regioisomer 1-phenylethanol with 5% reduced nicotinamideadenine deoxyribonucleic acid to product conversion of and aratio of 73:27 for the R and S enantiomers respectively. Ethyibenzenewas modeled into the active site of WT P-450_cam in a rigid modeand oriented to optimize either pro-R or pro-S hydrogen abstraction.Residues T101, T185 and V247 make extensive contacts with thesubstrate in the static complexes and were therefore chosenfor site-directed mutagenesis. Single mutants T101M, V247A andV247M are more stereospedik producing 89,87 and 82% (R)-1-phenylethanolrespectively. The coupling of the reaction is doubled for thesingle mutants T185L, T185F and V247M. In an effort to engineerincreased stereospecificity and coupling into a single catalystthe T101M, T185F and V247M mutants were combined in a multiplemutant of P-450_cam.This protein hydroxylates ethyibenzene resultingin an R:S ratio of 87:13 for the 1-phenylethanols and 13% couplingof reducing equivalents to product. The catalytic stereospecificityand stoichiometry with T101M–T185F–V247M does notrepresent a summation of the changes observed for the singlemutants. A portion of the individual effects on substrate recognitionproduced by the single substitutions is either eliminated ordegenerate within the triple mutant.     

A predicted three-dimensional structure of human cytochrome P450: implications for substrate specificity

A three-dimensional structure for human cytochrome P450IA1 waspredicted based on the crystal coordinates of cytochrome P450camfrom Pseudomonas putida. As there was only 15% residue identitybetween the two enzymes, additional information was used toestablish an accurate sequence alignment that is a prerequisitefor model building. Twelve representative eukaryotic sequenceswere aligned and a net prediction of secondary structure wasmatched against the known -helices and ß-sheets ofP450cam. The cam secondary structure provided a fixed main-chainframework onto which loops of appropriate length from the humanP450IA1 structure were added. The model-built structure of thehuman cytochrome conformed to the requirements for the segregationof polar and nonpolar residues between the core and the surface.The first 44 residues of human cytochrome P450 could not bebuilt into the model and sequence analysis suggested that residues1–26 formed a single membrane-spanning segment. Examinationof the sequences of cytochrome P450s from distinct gene familiessuggested specific residues that could account for the differencesin substrate specificity. A major substrate for P450IA1, 3-methyl-cholanthrene,was fitted into the proposed active site and this planar aromaticmolecule could be accommodated into the available cavity. Residuesthat are likely to interact with the haem were identified. Thesequence similarity between 59 eukaryotic enzymes was representedas a dendrogram that in general clustered according to genefamily. Until a crystallographic structure is available, thismodel-building study identifies potential residues in cytochromeP450s important in the function of these enzymes and these residuesare candidates for site-directed mutagenesis.     

Engineering mammalian cytochrome P450 2B1 by directed evolution for enhanced catalytic tolerance to temperature and dimethyl sulfoxide

The previously laboratory-evolved cytochrome P450 2B1 quadruple mutant V183L/F202L/L209A/S334P (QM), which showed enhanced H(2)O(2)-mediated substrate oxidation, has now been shown to exhibit a >3.0-fold decrease in K(m,HOOH) for 7-ethoxy-4-trifluoromethylcoumarin (7-EFC) O-deethylation compared with the parental enzyme L209A. Subsequently, a streamlined random mutagenesis and a high-throughput screening method were developed using QM to screen and select mutants with enhanced tolerance of catalytic activity to temperature and dimethyl sulfoxide (DMSO). Upon screening >3000 colonies, we identified QM/L295H and QM/K236I/D257N with enhanced catalytic tolerance to temperature and DMSO. QM/L295H exhibited higher activity than QM at a broad range of temperatures (35-55 degrees C) and maintained approximately 1.4-fold higher activity than QM at 45 degrees C for 6 h. In addition, QM/L295H showed a significant increase in T(m,app) compared with L209A. QM/L295H and QM/K236I/D257N exhibited higher activity than QM at a broad range of DMSO concentrations (2.5-15%). Furthermore, QM/K236I/D257N/L295H was constructed by combining QM/K236I/D257N with L295H using site-directed mutagenesis and exhibited a >2-fold higher activity than QM at nearly the entire range of DMSO concentrations. In conclusion, in addition to engineering mammalian cytochromes P450 for enhanced activity, directed evolution can also be used to optimize catalytic tolerance to temperature and organic solvent.     

Enzyme-catalyzed dehalogenation of pentachloroethane: why F87W-cytochrome P450cam is faster than wild type

Under anaerobic conditions, cytochromes P450 can reductivelydehalogenate heavily halogenated hydrocarbons, such as one-and two-carbon organic solvents. This catalytic capacity hasdrawn attention to the potential use of engineered forms ofP450s in the remediation of contaminated deep subsurface ecosystems.Loida (1994, PhD Thesis, University of Illinois at Urbana-Champaign,IL) and S.G.Sligar (personal communication) have observedrecentlythat an active-site variant of cytochrome P450cam (F87W) dechlorinatespentachloroethane approximately three times faster than thewild-type enzyme. Molecular dynamics simulations have revealedthat the mutant enzyme binding pocket remains smaller, and thatpentachloroethane assumes configurations closer to the heme-Fein the F87W mutant twice as often as in the wild-type enzyme.This result is consistent with a collisional model of dehalogenation,which agrees with experimental observations [Li and Wackett(1993) Biochemistry, 32, 9355–9361] that solutions containingwild-type P450cam dehalogenate pentachloroethane 100 times fasterthan those containing free heme. The simulations suggest thatit is unlikely that Trp87 significantly stabilizes the developingnegative charge on the substrate during carbon-halogen bondreduction. The design of improved microbiai enzymes that incorporateboth steric and electronic effects continues for use in remediatinghalogenated contaminants in situ     

Class-dependent sequence alignment strategy improves the structural and functional modeling of P450s

Different procedures for obtaining homology models for P450s are investigated using various sequence alignments sharing various levels of sequence identity with available P450 crystal structures. In this analysis, we have investigated how well homology modeling can reproduce known crystal structures as well as how effectively these homology models can be used to reproduce known ligand-binding modes. Homology models obtained from sequence alignments that discriminate between Class I and Class II P450s are significantly closer to the experimental crystal structures and more closely reproduce known ligand's binding modes, than those obtained using sequence alignments that combine Class I and Class II P450s. The quality of the models is slightly improved by constructing hybrid-structure models that model three of the most variable regions of P450s independently from the rest of the protein: the B region that includes SRS1, the FG region that includes SRS2 and SRS3 and the beta4 region that includes SRS6.     

Ile115Leu mutation in the SRS1 region of an insect cytochrome P450 (CYP6B1) compromises substrate turnover via changes in a predicted product release channel

CYP6B1 represents the principal cytochrome P450 monooxygenase responsible for metabolizing furanocoumarins in Papilio polyxenes, an insect that specializes on host plants containing these toxins. Investigations of the amino acids responsible for the efficient metabolism of these plant toxins has identified Ile115 as one that modulates the rate of furanocoumarin metabolism even though it is predicted to be positioned at the edge of the heme plane and outside substrate contact regions. In contrast to previous expression studies conducted under conditions of limiting P450 reductase showing that the Ile115-to-Leu replacement enhances turnover of xanthotoxin and other furanocoumarins, studies conducted at high P450 reductase indicate that the Ile115-to-Leu replacement reduces turnover of these substrates. Further analysis of substrate binding affinities, heme spin state and NADPH consumption rates indicate that, whereas the I115L replacement mutant displays higher substrate affinity and heme spin state than the wild-type CYP6B1 protein, it utilizes NADPH more slowly than the wild-type CYP6B1 protein at high P450 reductase levels. Molecular models developed for the wild-type CYP6B1 and mutant protein suggest that more constricted channels extending from the catalytic site in the I115L mutant to the P450 surface limit the rate of product release from this mutant catalytic site under conditions not limited by the rate of electron transfer from NADPH.     

Comparison of the construction of a 3-D model for human thromboxane synthase using P450cam and BM-3 as templates: implications for the substrate binding pocket

A 3-D model of human thromboxane A₂ synthase (TXAS) was constructedusing a homology modeling approach based on information fromthe 2.0 crystal structure of the hemoprotein domains of cytochromeP450BM-3 and P450cam. P450BM-3 is a bacterial fatty acid monooxygenaseresembling eukaryotic microsomal cytochrome P450s in primarystructure and function. TXAS shares 26.4% residue identity and48.4% residue similarity with the P450BM-3 hemoprotein domain.The homology score between TXAS and P450BM-3 is much higherthan that between TXAS and P450cam. Alignment between TXAS andthe P450BM-3 hemoprotein domain or P450cam was determined throughsequence searches. The P450BM-3 or P450cam main-chain coordinateswere spplied to the TXAS main chain in those sements where thetwo sequences were well aligned. These segments were linkedto one another using a fragment search method, and the sidechains were added to produce a 3-D model for TXAS. A TXAS substrate,prostaglandin H₂ (PGH₂) was docked into the TXAS cavity correspondingto the arachidonic acid binding pocket in P450BM-3 or camphorbinding site in P450cam. Regions of the heme and putative PGH2binding cavities in the TXAS model were identified and analyzed.The segments and residues involved in the active-site pocketof the TXAS model provide reasonable candidates for TXAS proteinengineering and inhibitor design. Comparison of the TXAS modelbased on P450BM-3 with another TXAS model based on the P450BM-3with another TXAS model based on the P450cam structure indicatedthat P450BM-3 is a more suitable template for homology modelingof TXAS.     

Binding free energy calculations for P450cam-substrate complexes

A recently proposed semi-empirical method for calculating bindingfree energies was used to examine the binding of a variety ofsubstrates to cytochrome P450cam. For a set of 11 differentpotential substrates of cytochrome P450cam, both the absoluteand relative binding free energies were generally well reproduced.The mean error in the calculated absolute binding free energyfor all 11 compounds is 0.55 kcal/mol. Forty-eight out of 55calculated relative binding free energies have the correct signand the mean unsigned error between calculated and experimentalrelative binding free energies is 0.77 kcal/mol. For one substrate,thiocamphor, the effect of substrate orientation on the calculatedbinding free energy was examined. The ability of this methodto predict the effect of active site mutations was also examinedin two cases.     

Sequence requirements for cytochromes P450IIA1 and P450IIA2 catalytic activity: evidence for both specific and non-specific substrate binding interactions through use of chimeric cDNAs and cDNA expression

Cytochrome P450s IIA1 and IIA2, encoded by the CYP2A1 and CYP2A2genes, display 88% amino acid sequence similarities. The dissimilaritiesof sequence between these two enzymes are primarily localizedwithin four discrete regions of the polypeptides that are separatedby regions of absolute sequence identity. IIA1 specificallyhydroxylates the prototype substrate testosterone at the 7 and6 position with a predominance of 7 metabolite. IIA2, on theother hand, hydroxylates this steroid at eight positions onthe molecule, with one of the most abundant metabolites being15hydroxytestosterone. To determine those amino acids responsiblefor the difference in testosterone hydroxylation specificities,chimeras were constructed between IIA1 and IIA2 cDNAs and expressedin cell culture using vaccinia-virus-mediated cDNA expression.Chimeras, in which the first 355 amino acids correspond to asingle enzyme, maintain the specificity associated with thatenzyme. Of six chimeras which have substitutions between aminoacids 161 and 276, two are inactive and the remaining four givesimilar metabolite profiles, in which both 7 and 15 hydroxylationspecificities have been lost. Two of these four chimeras arediametric apposites, suggesting that modification of eitherthe N-terminal or central regions of the enzymes results inconformational changes that prevent the specific binding interactionsresponsible for the narrow regioselectivity associated withIIA1 and 15-hydroxytestosterone formation associated with IIA2.     

Construction and evaluation of a three-dimensional structure of cytochrome P450choP enzyme (CYP105C1)

The purpose of this work was to develop and carefully evaluateimproved strategies for constructing reliable 3-D models ofP450 isozymes. To this end, a unique combination of steps forbuilding and evaluating a model structure was used to builda homology model of the P450choP isozyme, based on knowledgeof the X-ray structures of P450cam, P450terp, P450BM-3 and P450eryF.Specifically, the reliability of this model was examined bysystematic comparisons of its conformational, energetic, environmentaland packing properties and those of the four reference proteinswith corresponding properties from the database of proteinswith known structures. The results showed that the examinedproperties of this model structure are well within the criteriaestablished for reliable structures and are of nearly as goodquality as those of the reference proteins. In addition, theresult from a 120 ps unconstrained MD simulation of the modelwith structural waters provided evidence that the model is stableat room temperature. This 3-D model can now be reliably usedfor explicit characterization of substrate and inhibitor complexes.Most importantly, although it is envisioned that building modelsfor mammalian P450s will be even more challenging, the stepsdescribed here should be very useful in future constructionof 3-D models of mammalian P450 isozymes.     

Substrate mobility in thiocamphor-bound cytochrome P450cam: an explanation of the conflict between the observed product profile and the X-ray structure

Thiocamphor is an unusual substrate for P450_cam in that in theX-ray structure it binds in the active site pocket in two distinctorientations and neither of these orientations are consistentwith the 5-alcohol being the primary product. Other camphoranalogs such as norcamphor or camphane bind in a single orientationconsistent with the 5-alcohol being a major product. We presentan analysis of four 175 ps molecular dynamics trajectories ofthiocamphor-bound cytochrome P450_cam. The first two trajectorieswere calculated for cytochrome P450_cam with thiocamphor boundin both its major and minor crystallographic orientations. Inthe second set of simulations, a single oxygen atom was addedas a distal ligand to the heme group in order to model the putativeferryl oxygen reaction intermediate. Trajectories were againcalculated starting with thiocamphor in its major and minororientations. While the protein dynamics were quite similarin all four trajectories, the substrate showed distinctly differentmotions in each of the trajectories. In particular, the preferredsubstrate orientations were very different in the presence ofthe ferryl oxygen than in the absence of that oxygen. The preferredorientations in the absence of the distal oxygen were consistentwith the 3-akohol being the major product, while the preferredorientations in the presence of the distal oxygen were consistentwith the 5-alcohol being a major product. These simulationsoffer an explanation for the inconsistency between the X-raydata and the product profile.     

Preparation of Compound I in P450cam: The Prototypical P450

Cytochrome P450_cam occupies a central position in the heme monooxygenase landscape. For many years, P450_cam has served as a prototype for understanding structure and function in bacterial, fungal, microsomal, and plant P450s. The enzyme is believed to function through a highly reactive iron(IV)oxo radical species called compound I. While the first glimpses of compound I were observed in P450_cam over thirty years ago, subsequent attempts to prepare the intermediate for further characterizations have proven unsuccessful. Given that the initial reports provided great promise, the nature of the subsequent failures has been extremely puzzling. Here we detail the preparation of compound I in P450_cam. Using insights gained from previous investigations, we have obtained the intermediate in ∼ 45 % yield, allowing characterizations by UV/Visible, Mössbauer, and EPR spectroscopies. This report provides a missing piece of the monooxygenase landscape, verifying the existence of compound I in the most studied P450.     

Structure and redox properties of the haem centre in the C357M mutant of cytochrome P450cam

The effects of site-specific mutation of the axial cysteine (C357M) to a methionine residue in cytochrome P450cam on the enzyme's coordination geometry and redox potential have been investigated. The absorption spectra of the haem centre in the C357M mutant of the enzyme showed close similarity to those of cytochrome c both in the oxidised and reduced forms. A well-defined absorption peak at 695 nm, similar to that seen in the case of cytochrome c and characteristic of methionine ligation to the ferric haem, was observed. The results indicated that the haem of C357M cytochrome P450cam is possibly axially coordinated to a methionine and a histidine, analogously to cytochrome c. The circular dichroism spectra in the visible and the far-UV regions suggested that the tertiary structure of the haem cavity in the C357M mutant cytochrome P450cam was distinctly different from that in the wild-type enzyme or in cytochrome c, although the secondary structure of the mutant remained identical to that of the wild-type cytochrome P450cam. Comparison of the natures of the CD spectra in the 400 nm and 695 nm regions of the C357M mutant of cytochrome P450cam with those of horse cytochrome c suggested (R) chirality at the sulfur atom of the iron-bound methionine residue in the mutant. The redox potential of the haem centre, estimated by redox titration of the C357M mutant, was found to be +260 mV, which is much higher than that in the wild-type enzyme and similar to the redox potential of cytochrome c. This supported the concept that axial ligation of the haem plays the major role in tuning the redox potential of the haem centre in haem proteins.     

新型电荷型纳米盘的可控制备及其与细胞色素P450的结合性能

分别采用氮气吹干法和旋转蒸发法制备由磷脂和膜支架蛋白组成的电荷型纳米盘,用凝胶过滤色谱对其尺寸分级,分析了其性能,考察了其与肝微粒体细胞色素P450的结合能力。结果表明,纳米盘外观澄清透明,微观呈圆盘状,平均直径10 nm,在pH 7.4下Zeta电位为?19.86 mV;肝微粒体破碎液与纳米盘能很好结合,CO差示光谱在450 nm出现明显吸收峰,细胞色素P450含量为0.10 nmol/mg,比活比未经纳米盘处理时提高13.0倍,较传统方法提升1.5倍,且操作时间由数日缩短至数小时。电荷型纳米盘在结合膜蛋白细胞色素P450的同时,活性保持良好,在膜蛋白研究领域极具应用潜力。     

Structural domains of P450-containing monooxygenase systems

All known P450-containing monooxygenase systems share commonstructural and functional domain architecture. Apart from P450itself, these systems can comprise several fundamentally differentprotein components or domains, all of which are shared by othermulticomponent/multidomain enzyme systems with various functions:FAD flavoprotein or domain, FMN domain, Fe₂S₂ ferredoxin, Fe₃S₄ferredoxin, and cytochrome b₅. Either FMN domain, ferredoxinsor cytochrome bs serve as the electron transport intermediatebetween the FAD domain and P450. The molecular evolution ofboth P450-containing systems and of each particular componentdoes not follow phylogeny in general. Gene fusion and horizontalgene transfer events can lead to the appearance of novel redoxchains in the same manner that artificial chimeric proteinscan be constructed by humans. Recent studies using genetic andprotein engineering techniques to investigate the separate domainsand their interaction are described.     

The influence of Glu44 and Glu56 of cytochrome b5 on the protein structure and interaction with cytochrome c

The gene encoding trypsin-solubilized bovine liver microsomalcytochrome b₅ (82 residues in length) has been mutated, in whichthe codons of Glu44 and Glu56 were changed to those of Ala.The mutated genes were expressed in Escherichia coli successfullyand three mutant proteins (E44A, E56A and E44/56A) were obtained.The UV-visible, CD and ¹H NMR spectra of proteins have beenstudied. The results show that the mutagenesis at surface residuesdoes not alter the secondary and tertiary structures of cytochromeb₅ significantly. The interactions between recombinant cytochromeb₅ and its mutants with cytochrome c were studied by using opticaldifference spectra. The results demonstrated that both Glu44and Glu56 of cytochrome b₅ participate in the formation of acomplex between cytochrome b₅ and cytochrome c.     

细胞色素P450 BM-3羟基化吲哚能力的半理性改造

为进一步改造细胞色素P450 BM-3酶对吲哚的羟基化能力,以P450 BM-3结构与功能关系的推测为指导,选择突变酶P450 BM-3 （A74G/F87V/L188Q/E435T）为父本,在可能影响P450 BM-3催化吲哚羟基化区域选择性的D168位点进行定点饱和突变,根据全细胞催化产物颜色及组成进行筛选,得到了产物组成、酶动力学性质与父本不同的两个突变酶。突变酶D168W的吲哚羟基化产物中90%是靛玉红,而另一个突变酶D168R的产物中87%是靛蓝,产物组成均不同于亲本。在催化吲哚羟基化时,D168W的k_cat与父本相当,但K_m却是父本的4.8倍,催化活力只有父本的20%;而D168R的k_cat是父本的1.9倍,K_m是父本的82%,催化活力比父本提高了1.37倍。结果表明,在E435T突变上叠加D168位氨基酸残基突变对酶的催化性质产生了单一位点突变所不具有的协同效应,对酶催化的区域选择性和催化活力都有显著影响,以致改变了催化产物组成。这种基于知识的半理性定向进化方法由于是在关键位点进行突变,因此突变目的性强、突变效果显著。