The numerous effector functions of Nef.

P450BM-3, a catalytically self-sufficient, soluble bacterial P450, contains on the same polypeptide a heme domain and a reductase domain. P450BM-3 catalyzes the oxidation of short- and long-chain, saturated and unsaturated fatty acids. The three-dimensional structure of the heme domain both in the absence and in the presence of fatty acid substrates has been determined; however, the fatty acid in the substrate-bound form is not adequately close to the heme iron to permit a prediction regarding the stereoselectivity of oxidation. In the case of long-chain fatty acids, the products can also serve as substrate and be metabolized several times. In the current study, we have determined the absolute configuration of the three primary products of palmitic acid hydroxylation (15-, 14-, and 13-OH palmitic acid). While the 15- and 14-hydroxy compounds are produced in a highly stereoselective manner (98% R, 2% S), the 13-hydroxy is a mixture of 72% R and 28% S. We have also examined the binding of these three hydroxy acids to P450BM-3 and shown that only two of them (14-OH and 13-OH palmitic acid) can bind to and be further metabolized by P450BM-3. The results indicate that in contrast to the flexibility of palmitoleic acid bound to the oxidized enzyme, palmitic acid is rigidly bound in the active site during catalytic turnover.     

The structural basis for specificity in lipoxygenase catalysis

Many intriguing facets of lipoxygenase (LOX) catalysis are open to a detailed structural analysis. Polyunsaturated fatty acids with two to six double bonds are oxygenated precisely on a particular carbon, typically forming a single chiral fatty acid hydroperoxide product. Molecular oxygen is not bound or liganded during catalysis, yet it is directed precisely to one position and one stereo configuration on the reacting fatty acid. The transformations proceed upon exposure of substrate to enzyme in the presence of O₂ (RH + O₂ → ROOH), so it has proved challenging to capture the precise mode of substrate binding in the LOX active site. Beginning with crystal structures with bound inhibitors or surrogate substrates, and most recently arachidonic acid bound under anaerobic conditions, a picture is consolidating of catalysis in a U‐shaped fatty acid binding channel in which individual LOX enzymes use distinct amino acids to control the head‐to‐tail orientation of the fatty acid and register of the selected pentadiene opposite the non‐heme iron, suitably positioned for the initial stereoselective hydrogen abstraction and subsequent reaction with O₂. Drawing on the crystal structures available currently, this review features the roles of the N‐terminal β‐barrel (C2‐like, or PLAT domain) in substrate acquisition and sensitivity to cellular calcium, and the α‐helical catalytic domain in fatty acid binding and reactions with O₂ that produce hydroperoxide products with regio and stereospecificity. LOX structures combine to explain how similar enzymes with conserved catalytic machinery differ in product, but not substrate, specificities.     

Interactions of substrates at the surface of P450s can greatly enhance substrate potency

Cytochrome P450s are a superfamily of heme containing enzymes that use molecular oxygen and electrons from reduced nicotinamide cofactors to monooxygenate organic substrates. The fatty acid hydroxylase P450BM-3 has been particularly widely studied due to its stability, high activity, similarity to mammalian P450s, and presence of a cytochrome P450 reductase domain that allows the enzyme to directly receive electrons from NADPH without a requirement for additional redox proteins. We previously characterized the substrate N-palmitoylglycine, which found extensive use in studies of P450BM-3 due to its high affinity, high turnover number, and increased solubility as compared to fatty acid substrates. Here, we report that even higher affinity substrates can be designed by acylation of other amino acids, resulting in P450BM-3 substrates with dissociation constants below 100 nM. N-Palmitoyl-l-leucine and N-palmitoyl-l-methionine were found to have the highest affinity, with dissociation constants of less than 8 nM and turnover numbers similar to palmitic acid and N-palmitoylglycine. The interactions of the amino acid side chains with a hydrophobic pocket near R47, as revealed by our crystal structure determination of N-palmitoyl-l-methionine bound to the heme domain of P450BM-3, appears to be responsible for increasing the affinity of substrates. The side chain of R47, previously shown to be important in interactions with negatively charged substrates, does not interact strongly with N-palmitoyl-l-methionine and is found positioned at the enzyme-solvent interface. These are the tightest binding substrates for P450BM-3 reported to date, and the affinity likely approaches the maximum attainable affinity for the binding of substrates of this size to P450BM-3.     

Key substrate recognition residues in the active site of a plant cytochrome P450, CYP73A1. Homology guided site-directed mutagenesis.

CYP73 enzymes are highly conserved cytochromes P450 in plant species that catalyse the regiospecific 4-hydroxylation of cinnamic acid to form precursors of lignin and many other phenolic compounds. A CYP73A1 homology model based on P450 experimentally solved structures was used to identify active site residues likely to govern substrate binding and regio-specific catalysis. The functional significance of these residues was assessed using site-directed mutagenesis. Active site modelling predicted that N302 and I371 form a hydrogen bond and hydrophobic contacts with the anionic site or aromatic ring of the substrate. Modification of these residues led to a drastic decrease in substrate binding and metabolism without major perturbation of protein structure. Changes to residue K484, which is located too far in the active site model to form a direct contact with cinnamic acid in the oxidized enzyme, did not influence initial substrate binding. However, the K484M substitution led to a 50% loss in catalytic activity. K484 may affect positioning of the substrate in the reduced enzyme during the catalytic cycle, or product release. Catalytic analysis of the mutants with structural analogues of cinnamic acid, in particular indole-2-carboxylic acid that can be hydroxylated with different regioselectivities, supports the involvement of N302, I371 and K484 in substrate docking and orientation.     

Molecular definitions of fatty acid hydroxylases in Arabidopsis thaliana

Towards defining the function of Arabidopsis thaliana fatty acid hydroxylases, five members of the CYP86A subfamily have been heterologously expressed in baculovirus-infected Sf9 cells and tested for their ability to bind a range of fatty acids including unsubstituted (lauric acid (C12:0) and oleic acid (C18:1)) and oxygenated (9,10-epoxystearic acid and 9,10-dihydroxystearic acid). Comparison between these five P450s at constant P450 content over a range of concentrations for individual fatty acids indicates that binding of different fatty acids to CYP86A2 always results in a higher proportion of high spin state heme than binding titrations conducted with CYP86A1 or CYP86A4. In comparison to these three, CYP86A7 and CYP86A8 produce extremely low proportions of high spin state heme even with the most effectively bound fatty acids. In addition to their previously demonstrated lauric acid hydroxylase activities, all CYP86A proteins are capable of hydroxylating oleic acid but not oxygenated 9,10-epoxystearic acid. Homology models have been built for these five enzymes that metabolize unsubstituted fatty acids and sometimes bind oxygenated fatty acids. Comparison of the substrate binding modes and predicted substrate access channels indicate that all use channel pw2a consistent with the crystal structures and models of other fatty acid-metabolizing P450s in bacteria and mammals. Among these P450s, those that bind internally oxygenated fatty acids contain polar residues in their substrate binding cavity that help stabilize these charged/polar groups within their largely hydrophobic catalytic site.     

A structural model of PpoA derived from SAXS-analysis—Implications for substrate conversion

In plants and mammals, oxylipins may be synthesized via multi step processes that consist of dioxygenation and isomerization of the intermediately formed hydroperoxy fatty acid. These processes are typically catalyzed by two distinct enzyme classes: dioxygenases and cytochrome P450 enzymes. In ascomycetes biosynthesis of oxylipins may proceed by a similar two-step pathway. An important difference, however, is that both enzymatic activities may be combined in a single bifunctional enzyme. These types of enzymes are named Psi-factor producing oxygenases (Ppo). Here, the spatial organization of the two domains of PpoA from Aspergillus nidulans was analyzed by small-angle X-ray scattering and the obtained data show that the enzyme exhibits a relatively flat trimeric shape. Atomic structures of the single domains were obtained by template-based structure prediction and docked into the enzyme envelope of the low resolution structure obtained by SAXS. EPR-based distance measurements between the tyrosyl radicals formed in the activated dioxygenase domain of the enzyme supported the trimeric structure obtained from SAXS and the previous assignment of Tyr374 as radical-site in PpoA. Furthermore, two phenylalanine residues in the cytochrome P450 domain were shown to modulate the specificity of hydroperoxy fatty acid rearrangement.     

Fatty acid monooxygenation by cytochrome P-450BM-3

Cytochrome P-450BM-3 is a catalytically self-sufficient enzyme which monooxygenates saturated and unsaturated fatty acids, alcohols, and amides. The protein has two domains: one which contains heme and is P-450-like and the other which contains FAD and FMN and is P-450 reductase-like. Both domains are on a single polypeptide chain. Utilizing a plasmid containing the gene encoding P-450BM-3, we have transformed the Escherichia coli strain DH5 alpha. This clone overexpresses P-450BM-3 to make approximately 20% of the soluble protein of this organism under optimal conditions. P-450BM-3 can be purified to homogeneity from the soluble fraction of the protein of these cells with a recovery of 50% making this cell line an excellent source of this important enzyme. Purified preparations of P-450BM-3 hydroxylate palmitic acid at a rate of 1600 mol/min/mol of heme at 25 degrees C. The stoichiometry of NADPH to oxygen utilized was 1 for all conditions; however, the ratio of oxygen or NADPH utilized per molecule of fatty acid substrate metabolized was different for different homologs of saturated fatty acids, when low concentrations (less than 100 microM) of substrate were used. Lauric and myristic acids were metabolized to two hydroxylated products, irrespective of the initial concentration of fatty acid in the reaction mixture, and the ratio of oxygen consumed to fatty acid hydroxylated was 1. High concentrations of palmitic acid (greater than 200 microM) led to the formation of three polar metabolites and a stoichiometry of 1:1 was observed for oxygen and palmitic acid utilization. These results indicate that a single hydroxyl group was inserted into each of these molecules. Lower concentrations (less than 50 microM) of palmitic acid were metabolized to additional polar metabolites, and the ratio of oxygen consumed to fatty acid substrate consumed approximated 3:1. These results can be explained best by a hypothesis that the initial hydroxylated compounds, which accumulate during the oxidation of palmitic acid by P-450BM-3, can be further oxidized by this enzyme to polyhydroxy- or hydroxy-ketone products.     

Crystal structure of inhibitor-bound P450BM-3 reveals open conformation of substrate access channel

P450BM-3 is an extensively studied P450 cytochrome that is naturally fused to a cytochrome P450 reductase domain. Crystal structures of the heme domain of this enzyme have previously generated many insights into features of P450 structure, substrate binding specificity, and conformational changes that occur on substrate binding. Although many P450s are inhibited by imidazole, this compound does not effectively inhibit P450BM-3. Omega-imidazolyl fatty acids have previously been found to be weak inhibitors of the enzyme and show some unusual cooperativity with the substrate lauric acid. We set out to improve the properties of these inhibitors by attaching the omega-imidazolyl fatty acid to the nitrogen of an amino acid group, a tactic that we used previously to increase the potency of substrates. The resulting inhibitors were significantly more potent than their parent compounds lacking the amino acid group. A crystal structure of one of the new inhibitors bound to the heme domain of P450BM-3 reveals that the mode of interaction of the amino acid group with the enzyme is different from that previously observed for acyl amino acid substrates. Further, required movements of residues in the active site to accommodate the imidazole group provide an explanation for the low affinity of imidazole itself. Finally, the previously observed cooperativity with lauric acid is explained by a surprisingly open substrate-access channel lined with hydrophobic residues that could potentially accommodate lauric acid in addition to the inhibitor itself.     

Substrate Binding Specifically Modulates Domain Arrangements in Adenylate Kinase

The enzyme adenylate kinase (ADK) features two substrate binding domains that undergo large-scale motions during catalysis. In the apo state, the enzyme preferentially adopts a globally open state with accessible binding sites. Binding of two substrate molecules (AMP + ATP or ADP + ADP) results in a closed domain conformation, allowing efficient phosphoryl-transfer catalysis. We employed molecular dynamics simulations to systematically investigate how the individual domain motions are modulated by the binding of substrates. Two-dimensional free-energy landscapes were calculated along the opening of the two flexible lid domains for apo and holo ADK as well as for all single natural substrates bound to one of the two binding sites of ADK. The simulations reveal a strong dependence of the conformational ensembles on type and binding position of the bound substrates and a nonsymmetric behavior of the lid domains. Altogether, the ensembles suggest that, upon initial substrate binding to the corresponding lid site, the opposing lid is maintained open and accessible for subsequent substrate binding. In contrast, ATP binding to the AMP-lid induces global domain closing, preventing further substrate binding to the ATP-lid site. This might constitute a mechanism by which the enzyme avoids the formation of a stable but enzymatically unproductive state.     

Structure and reactivity of human mitochondrial 2,4-dienoyl-CoA reductase: enzyme-ligand interactions in a distinctive short-chain reductase active site

Fatty acid catabolism by beta-oxidation mainly occurs in mitochondria and to a lesser degree in peroxisomes. Poly-unsaturated fatty acids are problematic for beta-oxidation, because the enzymes directly involved are unable to process all the different double bond conformations and combinations that occur naturally. In mammals, three accessory proteins circumvent this problem by catalyzing specific isomerization and reduction reactions. Central to this process is the NADPH-dependent 2,4-dienoyl-CoA reductase. We present high resolution crystal structures of human mitochondrial 2,4-dienoyl-CoA reductase in binary complex with cofactor, and the ternary complex with NADP(+) and substrate trans-2,trans-4-dienoyl-CoA at 2.1 and 1.75 A resolution, respectively. The enzyme, a homotetramer, is a short-chain dehydrogenase/reductase with a distinctive catalytic center. Close structural similarity between the binary and ternary complexes suggests an absence of large conformational changes during binding and processing of substrate. The site of catalysis is relatively open and placed beside a flexible loop thereby allowing the enzyme to accommodate and process a wide range of fatty acids. Seven single mutants were constructed, by site-directed mutagenesis, to investigate the function of selected residues in the active site thought likely to either contribute to the architecture of the active site or to catalysis. The mutant proteins were overexpressed, purified to homogeneity, and then characterized. The structural and kinetic data are consistent and support a mechanism that derives one reducing equivalent from the cofactor, and one from solvent. Key to the acquisition of a solvent-derived proton is the orientation of substrate and stabilization of a dienolate intermediate by Tyr-199, Asn-148, and the oxidized nicotinamide.     

Expression, purification, and characterization of Bacillus subtilis cytochromes P450 CYP102A2 and CYP102A3: flavocytochrome homologues of P450 BM3 from Bacillus megaterium

The cyp102A2 and cyp102A3 genes encoding the two Bacillus subtilis homologues (CYP102A2 and CYP102A3) of flavocytochrome P450 BM3 (CYP102A1) from Bacillus megaterium have been cloned, expressed in Escherichia coli, purified, and characterized spectroscopically and enzymologically. Both enzymes contain heme, flavin adenine dinucleotide (FAD) and flavin mononucleotide (FMN) cofactors and bind a variety of fatty acid molecules, as demonstrated by conversion of the low-spin resting form of the heme iron to the high-spin form induced by substrate-binding. CYP102A2 and CYP102A3 catalyze the fatty acid-dependent oxidation of reduced nicotinamide adenine dinucleotide phosphate (NADPH) and reduction of artificial electron acceptors at high rates. Binding of carbon monoxide to the reduced forms of both enzymes results in the shift of the heme Soret band to 450 nm, confirming the P450 nature of the enzymes. Reverse-phase high-performance liquid chromatography (HPLC) of products from the reaction of the enzymes with myristic acid demonstrates that both catalyze the subterminal hydroxylation of this substrate, though with different regioselectivity and catalytic rate. Both P450s 102A2 and 102A3 show kinetic and binding preferences for long-chain unsaturated and branched-chain fatty acids over saturated fatty acids, indicating that the former two molecule types may be the true substrates. P450s 102A2 and 102A3 exhibit differing substrate selectivity profiles from each other and from P450 BM3, indicating that they may fulfill subtly different cellular roles. Titration curves for binding and turnover kinetics of several fatty acid substrates with P450s 102A2 and 102A3 are better described by sigmoidal (rather than hyperbolic) functions, suggesting binding of more than one molecule of substrate to the P450s, or possibly cooperativity in substrate binding. Comparison of the amino acid sequences of the three flavocytochromes shows that several important amino acids in P450 BM3 are not conserved in the B. subtilis homologues, pointing to differences in the binding modes for the substrates that may explain the unusual sigmoidal kinetic and titration properties.     

Global incorporation of norleucine in place of methionine in cytochrome P450 BM-3 heme domain increases peroxygenase activity

In this study we have replaced all 13 methionine residues in the cytochrome P450 BM-3 heme domain (463 amino acids) with the isosteric methionine analog norleucine. This experiment has provided a means of testing the functional limits of globally incorporating into an enzyme an unnatural amino acid in place of its natural analog, and also an efficient way to test whether inactivation during peroxide-driven P450 catalysis involves methionine oxidation. Although there was no increase in the stability of the P450 under standard reaction conditions (in 10 mM hydrogen peroxide), complete substitution with norleucine resulted in nearly two-fold-increased peroxygenase activity. Thermostability was significantly reduced. The fact that the enzyme can tolerate such extensive amino acid replacement suggests that we can engineer enzymes with unique chemical properties via incorporation of unnatural amino acids while retaining or improving catalytic properties. This system also provides a platform for directing enzyme evolution using an extended set of protein building blocks.     

Novel haem co-ordination variants of flavocytochrome P450BM3

Bacillus megaterium flavocytochrome P450 BM3 is a catalytically self-sufficient fatty acid hydroxylase formed by fusion of soluble NADPH-cytochrome P450 reductase and P450 domains. Selected mutations at residue 264 in the haem (P450) domain of the enzyme lead to novel amino acid sixth (distal) co-ordination ligands to the haem iron. The catalytic, spectroscopic and thermodynamic properties of the A264M, A264Q and A264C variants were determined in both the intact flavocytochromes and haem domains of P450 BM3. Crystal structures of the mutant haem domains demonstrate axial ligation of P450 haem iron by methionine and glutamine ligands trans to the cysteine thiolate, creating novel haem iron ligand sets in the A264M/Q variants. In contrast, the crystal structure of the A264C variant reveals no direct interaction between the introduced cysteine side chain and the haem, although EPR data indicate Cys(264) interactions with haem iron in solution. The A264M haem potential is elevated by comparison with wild-type haem domain, and substrate binding to the A264Q haem domain results in a approximately 360 mV increase in potential. All mutant haem domains occupy the conformation adopted by the substrate-bound form of wild-type BM3, despite the absence of added substrate. The A264M mutant (which has higher dodecanoate affinity than wild-type BM3) co-purifies with a structurally resolved lipid. These data demonstrate that a single mutation at Ala(264) is enough to perturb the conformational equilibrium between substrate-free and substrate-bound P450 BM3, and provide firm structural and spectroscopic data for novel haem iron ligand sets unprecedented in nature.     

Functional and structural roles of critical amino acids within the"N", "P", and "A" domains of the Ca2+ ATPase (SERCA) headpiece

Twenty five amino acids within the "N", "P", and "A" domains of the Ca(2+) ATPase (SERCA1) headpiece were subjected to site directed mutagenesis, taking advantage of a high yield expression system. Functional and conformational effects of mutations were interpreted systematically in the light of the high resolution WT structure, defining direct involvement in catalysis as well as in stabilization of various positions acquired by each domain upon substrate binding and utilization. Amino acids involved in binding of ATP (such as Phe487 and Arg560 in the N domain) or phosphate (such as Asp351, Thr625, Lys684, and Thr353 in the P domain) were characterized with respect to their binding mechanism. Further identified were "positional" roles of several amino acids that stabilize neighboring residues for optimal binding of substrate or Mg(2+), or interface between headpiece domains as they change their relative positions in the course of the catalytic cycle. These include cross-linking of the "N" and "P" domains (e.g., Arg560/Asp627 salt bridge to stabilize domain approximation by ATP binding), and stabilization of the "A", "N", and activated "P" domains in arrangements differing from the ground E2 state and driven by catalytic events. This stabilization is produced through hydrogen bonds at domain interfaces, which vary depending on the intermediate state (e.g., Glu486/T171 in E1P and E2P, as opposed to Glu486/H190 in E2). We demonstrate that specific arrangements of the headpiece domains shown in crystal structures are, in fact, required to trigger displacement of transmembrane segments during the enzyme cycle in solution, allowing long range linkage of catalytic and Ca(2+) binding functions.     

Engineering the substrate specificity of cytochrome P450 CYP102A2 by directed evolution: production of an efficient enzyme for bioconversion of fine chemicals

The P450 cytochromes constitute a large family of hemoproteins that catalyze the monooxygenation of a diversity of hydrophobic substrates. CYP102A2 is a catalytically self-sufficient cytoplasmic enzyme from Bacillus subtilis, containing both a monooxygenase domain and a reductase domain on a single polypeptide chain. CYP102A2 was subjected to error-prone PCR to generate mutants with enhanced activity with fatty acids and other aromatic substrates. The library of CYP102A2 mutants was expressed in BL21(DE3) Escherichia coli cells and screened for their ability to oxidize different substrates by means of an activity assay. After a single round of error-prone PCR, the variant Pro15Ser exhibiting modified substrate specificity was generated. This variant showed approximately 6- to 9-fold increased activity with SDS, lauric acid and 1,4-naphthoquinone, and enhanced activity for other substrates such as ethacrynic acid and epsilon-amino-n-caproic acid. Molecular modeling of the CYP102A2 monooxygenase domain suggested that Pro15 is located in a short helical segment and is involved in extensive interactions between the N-terminal domain and the beta2 sheet, which contribute to the formation of the substrate binding site. Thus, Pro15 appears to affect substrate binding and catalysis indirectly. These results clearly demonstrate the importance of remote residues, not readily predicted by rational design, for the determination of substrate specificity. In addition, we report here that the Pro15Ser variant of CYP102A2 can be efficiently immobilized on epoxy-activated Sepharose at pH 8.5 and 4 degrees C. The immobilized variant of CYP102A2 retains most of its activity (81%) and shows improved stability at 37 degrees C. The approach offers the possibility of designing a P450 bioreactor that can be operated over a long period of time with high efficiency and which can be used in fine chemical synthesis.     

Identification of critical residues of the mycobacterial dephosphocoenzyme a kinase by site-directed mutagenesis

Dephosphocoenzyme A kinase performs the transfer of the γ-phosphate of ATP to dephosphocoenzyme A, catalyzing the last step of coenzyme A biosynthesis. This enzyme belongs to the P-loop-containing NTP hydrolase superfamily, all members of which posses a three domain topology consisting of a CoA domain that binds the acceptor substrate, the nucleotide binding domain and the lid domain. Differences in the enzymatic organization and regulation between the human and mycobacterial counterparts, have pointed out the tubercular CoaE as a high confidence drug target (HAMAP database). Unfortunately the absence of a three-dimensional crystal structure of the enzyme, either alone or complexed with either of its substrates/regulators, leaves both the reaction mechanism unidentified and the chief players involved in substrate binding, stabilization and catalysis unknown. Based on homology modeling and sequence analysis, we chose residues in the three functional domains of the enzyme to assess their contributions to ligand binding and catalysis using site-directed mutagenesis. Systematically mutating the residues from the P-loop and the nucleotide-binding site identified Lys14 and Arg140 in ATP binding and the stabilization of the phosphoryl intermediate during the phosphotransfer reaction. Mutagenesis of Asp32 and Arg140 showed catalytic efficiencies less than 5-10% of the wild type, indicating the pivotal roles played by these residues in catalysis. Non-conservative substitution of the Leu114 residue identifies this leucine as the critical residue from the hydrophobic cleft involved in leading substrate, DCoA binding. We show that the mycobacterial enzyme requires the Mg(2+) for its catalytic activity. The binding energetics of the interactions of the mutant enzymes with the substrates were characterized in terms of their enthalpic and entropic contributions by ITC, providing a complete picture of the effects of the mutations on activity. The properties of mutants defective in substrate recognition were consistent with the ordered sequential mechanism of substrate addition for CoaE.     

A P450 BM-3 mutant hydroxylates alkanes, cycloalkanes, arenes and heteroarenes

P450 monooxygenases from microorganisms, similar to those of eukaryotic mitochondria, display a rather narrow substrate specificity. For native P450 BM-3, no other substrates than fatty acids or an indolyl-fatty acid derivative have been reported (Li, Q.S., Schwaneberg, U., Fischer, P., Schmid, R.D., 2000. Directed evolution of the fatty-acid hydroxylase P450BM-3 into an indole-hydroxylating catalyst. Chem. Eur. J. 6 (9), 1531-1536). Engineering the substrate specificity of Bacillus megaterium cytochrome P-450 BM3: hydroxylation of alkyl trimethylammonium compounds. Biochem. J. 327, 537-544). We thus were quite surprised to observe, in the course of our investigations on the rational evolution of this enzyme towards mutants, capable of hydroxylating shorter-chain fatty acids, that a triple mutant P450 BM-3 (Phe87Val, Leu188-Gln, Ala74Gly, BM-3 mutant) could efficiently hydroxylate indole, leading to the formation of indigo and indirubin (Li, Q.S., Schwaneberg, U., Fischer, P., Schmid, R.D., 2000. Directed evolution of the fatty-acid hydroxylase P450BM-3 into an indole-hydroxylating catalyst. Chem. Eur. J. 6 (9), 1531-1536). Indole is not oxidized by the wild-type enzyme; it lacks the carboxylate group by which the proper fatty acid substrates are supposed to be bound at the active site of the native enzyme, via hydrogen bonds to the charged amino acid residues Arg47 and Tyr51. Our attempts to predict the putative binding mode of indole to P450 BM-3 or the triple mutant by molecular dynamics simulations did not provide any useful clue. Encouraged by the unexpected activity of the triple mutant towards indole, we investigated in a preliminary, but systematic manner several alkanes, alicyclic, aromatic, and heterocyclic compounds, all of which are unaffected by the native enzyme, for their potential as substrates. We here report that this triple mutant indeed is capable to hydroxylate a respectable range of other substrates, all of which bear little or no resemblance to the fatty acid substrates of the native enzyme.     

A single active-site mutation of P450BM-3 dramatically enhances substrate binding and rate of product formation

Identifying key structural features of cytochromes P450 is critical in understanding the catalytic mechanism of these important drug-metabolizing enzymes. Cytochrome P450BM-3 (BM-3), a structural and mechanistic P450 model, catalyzes the regio- and stereoselective hydroxylation of fatty acids. Recent work has demonstrated the importance of water in the mechanism of BM-3, and site-specific mutagenesis has helped to elucidate mechanisms of substrate recognition, binding, and product formation. One of the amino acids identified as playing a key role in the active site of BM-3 is alanine 328, which is located in the loop between the K helix and β 1-4. In the A328V BM-3 mutant, substrate affinity increases 5-10-fold and the turnover number increases 2-8-fold compared to wild-type enzyme. Unlike wild-type enzyme, this mutant is purified from E. coli with endogenous substrate bound due to the higher binding affinity. Close examination of the crystal structures of the substrate-bound native and A328V mutant BMPs indicates that the positioning of the substrate is essentially identical in the two forms of the enzyme, with the two valine methyl groups occupying voids present in the active site of the wild-type substrate-bound structure.     

Substrate specificity of native and mutated cytochrome P450 (CYP102A3) from Bacillus subtilis

Within the Bacillus subtilis genome sequencing project, two monooxygenases (CYP102A2 and CYP102A3) were discovered which revealed a similarity of 76% to the well-known cytochrome P450 BM-3 (CYP102A1) of Bacillus megaterium. All enzymes are natural fusion proteins consisting of a heme domain and a reductase domain. We here report the cloning, expression and characterization of B. subtilis enzyme CYP102A3. The substrate specificity of this enzyme is similar to that of B. megaterium CYP102A1, which hydroxylates medium-chain fatty acids in subterminal positions. A double mutant was prepared that hydroxylates a number of other substrates, which do not bear any resemblance to the natural substrate of this enzyme family.     

A single mutation in cytochrome P450 BM3 induces the conformational rearrangement seen upon substrate binding in the wild-type enzyme

The multidomain fatty-acid hydroxylase flavocytochrome P450 BM3 has been studied as a paradigm model for eukaryotic microsomal P450 enzymes because of its homology to eukaryotic family 4 P450 enzymes and its use of a eukaryotic-like diflavin reductase redox partner. High-resolution crystal structures have led to the proposal that substrate-induced conformational changes lead to removal of water as the sixth ligand to the heme iron. Concomitant changes in the heme iron spin state and heme iron reduction potential help to trigger electron transfer from the reductase and to initiate catalysis. Surprisingly, the crystal structure of the substrate-free A264E heme domain mutant reveals the enzyme to be in the conformation observed for substrate-bound wild-type P450, but with the iron in the low-spin state. This provides strong evidence that the spin-state shift observed upon substrate binding in wild-type P450 BM3 not only is caused indirectly by structural changes in the protein, but is a direct consequence of the presence of the substrate itself, similar to what has been observed for P450cam. The crystal structure of the palmitoleate-bound A264E mutant reveals that substrate binding promotes heme ligation by Glu(264), with little other difference from the palmitoleate-bound wild-type structure observable. Despite having a protein-derived sixth heme ligand in the substrate-bound form, the A264E mutant is catalytically active, providing further indication for structural rearrangement of the active site upon reduction of the heme iron, including displacement of the glutamate ligand to allow binding of dioxygen.