Jeanette E. Stok

Reactions Catalyzed by Bacterial Cytochromes P450

The cytochromes P450 are a large family of oxidative haemoproteins that are responsible for a wide variety of oxidative transformations in a variety of organisms. This review focuses upon the reactions catalyzed specifically by bacterial enzymes, which includes aliphatic hydroxylation, alkene epoxidation, aromatic hydroxylation, oxidative phenolic coupling, heteroatom oxidation and dealkylation, and multiple oxidations including C-C bond cleavage. The potential for the practical application of the oxidizing power of these enzymes is briefly discussed.

Evaluation of α-cyanoesters as fluorescent substrates for examining interindividual variation in general and pyrethroid-selective esterases in human liver microsomes

Carboxylesterases hydrolyze many pharmaceuticals and agrochemicals and have broad substrate selectivity, requiring a suite of substrates to measure hydrolytic profiles. To develop new esterase substrates, a series of α-cyanoesters that yield fluorescent products upon hydrolysis was evaluated for use in carboxylesterase assays. The use of these substrates as surrogates for Type II pyrethroid hydrolysis was tested. The results suggest that these novel analogs are appropriate for the development of high-throughput assays for pyrethroid hydrolase activity. A set of human liver microsomes was then used to determine the ability of these substrates to report esterase activity across a small population. Results were compared against standard esterase substrates. A number of the esterase substrates showed correlations, demonstrating the broad substrate selectivity of these enzymes. However, for several of the substrates, no correlations in hydrolysis rates were observed, suggesting that multiple carboxylesterase isozymes are responsible for the array of substrate hydrolytic activity. These new substrates were then compared against α-naphthyl acetate and 4-methylumbelliferyl acetate for their ability to detect hydrolytic activity in both one- and two-dimensional native electrophoresis gels. Cyano-2-naphthylmethyl butanoate was found to visualize more activity than either commercial substrate. These applications demonstrate the utility of these new substrates as both general and pyrethroid-selective reporters of esterase activity.

Isopenicillin N Synthase Mediates Thiolate Oxidation to Sulfenate in a Depsipeptide Substrate Analogue: Implications for Oxygen Binding and a Link to Nitrile Hydratase?

Isopenicillin N synthase (IPNS) is a nonheme iron oxidase that catalyzes the central step in the biosynthesis of beta-lactam antibiotics: oxidative cyclization of the linear tripeptide delta-L-alpha-aminoadipoyl-L-cysteinyl-D-valine (ACV) to isopenicillin N (IPN). The ACV analogue delta-L-alpha-aminoadipoyl-L-cysteine (1-(S)-carboxy-2-thiomethyl)ethyl ester (ACOmC) has been synthesized as a mechanistic probe of IPNS catalysis and crystallized with the enzyme. The crystal structure of the anaerobic IPNS/Fe(II)/ACOmC complex was determined to 1.80 A resolution, revealing a highly congested active site region. By exposing these anaerobically grown crystals to high-pressure oxygen gas, an unexpected sulfenate product has been observed, complexed to iron within the IPNS active site. A mechanism is proposed for formation of the sulfenate-iron complex, and it appears that ACOmC follows a different reaction pathway at the earliest stages of its reaction with IPNS. Thus it seems that oxygen (the cosubstrate) binds in a different site to that observed in previous studies with IPNS, displacing a water ligand from iron in the process. The iron-mediated conversion of metal-bound thiolate to sulfenate has not previously been observed in crystallographic studies with IPNS. This mode of reactivity is of particular interest when considered in the context of another family of nonheme iron enzymes, the nitrile hydratases, in which post-translational oxidation of two cysteine thiolates to sulfenic and sulfinic acids is essential for enzyme activity.

Validating Eaton's Hypothesis: Cubane as a Benzene Bioisostere

Pharmaceutical and agrochemical discovery programs are under considerable pressure to meet increasing global demand and thus require constant innovation. Classical hydrocarbon scaffolds have long assisted in bringing new molecules to the market place, but an obvious omission is that of the Platonic solid cubane. Eaton, however, suggested that this molecule has the potential to act as a benzene bioisostere. Herein, we report the validation of Eatons hypothesis with cubane derivatives of five molecules that are used clinically or as agrochemicals. Two cubane analogues showed increased bioactivity compared to their benzene counterparts whereas two further analogues displayed equal bioactivity, and the fifth one demonstrated only partial efficacy. Ramifications from this study are best realized by reflecting on the number of bioactive molecules that contain a benzene ring. Substitution with the cubane scaffold where possible could revitalize these systems, and thus expedite much needed lead candidate identification.

Structural Studies on the Reaction of Isopenicillin N Synthase with a Sterically Demanding Depsipeptide Substrate Analogue

Isopenicillin N synthase (IPNS) is a nonheme iron(II)‐dependent oxidase that catalyses the central step in penicillin biosynthesis, conversion of the tripeptide δ‐L‐α‐aminoadipoyl‐L‐cysteinyl‐D‐valine (ACV) to isopenicillin N (IPN). This report describes mechanistic studies using the analogue δ‐(L‐α‐aminoadipoyl)‐(3S‐methyl)‐L‐cysteine D‐α‐hydroxyisovaleryl ester (ASmCOV), designed to intercept the catalytic cycle at an early stage. ASmCOV incorporates two modifications from the natural substrate: the second and third residues are joined by an ester, so this analogue lacks the key amide of ACV and cannot form a β‐lactam; and the cysteinyl residue is substituted at its β‐carbon, bearing a (3S)‐methyl group. It was anticipated that this methyl group will impinge directly on the site in which the co‐substrate dioxygen binds. The novel depsipeptide ASmCOV was prepared in 13 steps and crystallised with IPNS anaerobically. The 1.65 Å structure of the IPNS–FeII–ASmCOV complex reveals that the additional β‐methyl group is not oriented directly into the oxygen binding site, but does increase steric demand in the active site and increases disorder in the position of the isovaleryl side chain. Crystals of IPNS–FeII–ASmCOV were incubated with high‐pressure oxygen gas, driving substrate turnover to a single product, an ene‐thiol/C‐hydroxylated depsipeptide. A mechanism is proposed for the reaction of ASmCOV with IPNS, linking this result to previous crystallographic studies with related depsipeptides and solution‐phase experiments with cysteine‐methylated tripeptides. This result demonstrates that a (3S)‐methyl group at the substrate cysteinyl β‐carbon is not in itself a block to IPNS activity as previously proposed, and sheds further light on the steric complexities of IPNS catalysis.

Oxygen activation by P450cin: Protein and substrate mutagenesis

A conserved threonine found in the majority of cytochromes P450 (P450s) has been implicated in the activation of dioxygen during the catalytic cycle. P450(cin) (CYP176A) has been found to be an exception to this paradigm, where the conserved threonine has been replaced with an asparagine. Prior studies with a P450(cin) N242A mutant established that the Asn-242 was not a functional replacement for the conserved threonine but was essential for the regio- and stereocontrol of the oxidation of cineole. To explore further how P450(cin) controls the activation of the dioxygen in the absence of the conserved threonine, two concurrent lines of investigation were followed. Modification of P450(cin) indicated that the Thr-243 was not involved in controlling the protonation of the hydroperoxy species. In addition, the N242T mutant did not enhance the rate and/or efficiency of catalytic turnover of cineole by P450(cin). In parallel experiments, the substrate cineole was modified by removing the ethereal oxygen to produce camphane or 2,2-dimethylbicyclo[2.2.2]octane (cinane). An analogous experiment with P450(EryF) showed that a hydroxyl group on the substrate was vital, and in its absence catalytic turnover was effectively abolished. Catalytic turnover of P450(cin) with either of these alternative substrates (camphane or cinane) revealed that in the absence of the ethereal oxygen there was still a significant amount of coupling of the NADPH-reducing equivalents to the formation of oxidised product. Again the substrate itself was not found to be important in controlling oxygen activation, in contrast to P450(EryF), but was shown to be essential for regio- and stereoselective substrate oxidation. Thus, it still remains unclear how dioxygen activation in the catalytic turnover of cineole by P450(cin) is controlled.

Structural and mechanistic insight into alkane hydroxylation by Pseudomonas putida AlkB.

Pseudomonas putida GPo1 alkane hydroxylase (AlkB) is an integral membrane protein that catalyses the hydroxylation of medium-chain alkanes (C3-C12). 1-Octyne irreversibly inhibits this non-haem di-iron mono-oxygenase under turnover conditions, suggesting that it acts as a mechanism-based inactivator. Upon binding to the active site, 1-octyne is postulated to be oxidized to an oxirene that rapidly rearranges to a reactive ketene which covalently acylates nearby residues, resulting in enzyme inactivation. In analysis of inactivated AlkB by LC-MS/MS, several residues exhibited a mass increase of 126.1 Da, corresponding to the octanoyl moiety derived from oxidative activation of 1-octyne. Mutagenesis studies of conserved acylated residues showed that Lys18 plays a critical role in enzyme function, as a single-point mutation of Lys18 to alanine (K18A) completely abolished enzymatic activity. Finally, we present a computational 3D model structure of the transmembrane domain of AlkB, which revealed the overall packing arrangement of the transmembrane helices within the lipid bilayer and the location of the active site mapped by the 1-octyne modifications.

Cytochrome P450cin (CYP176A1) D241N: Investigating the role of the conserved acid in the active site of cytochrome P450s

P450(cin) (CYP176A) is a rare bacterial P450 in that contains an asparagine (Asn242) instead of the conserved threonine that almost all other P450s possess that directs oxygen activation by the heme prosthetic group. However, P450(cin) does have the neighbouring, conserved acid (Asp241) that is thought to be involved indirectly in the protonation of the dioxygen and affect the lifetime of the ferric-peroxo species produced during oxygen activation. In this study, the P450(cin) D241N mutant has been produced and found to be analogous to the P450(cam) D251N mutant. P450(cin) catalyses the hydroxylation of cineole to give only (1R)-6β-hydroxycineole and is well coupled (NADPH consumed: product produced). The P450(cin) D241N mutant also hydroxylated cineole to produce only (1R)-6β-hydroxycineole, was moderately well coupled (31±3%) but a significant reduction in the rate of the reaction (2% as compared to wild type) was observed. Catalytic oxidation of a variety of substrates by D241N P450(cin) were used to examine if typical reactions ascribed to the ferric-peroxo species increased as this intermediate is known to be more persistent in the P450(cam) D251N mutant. However, little change was observed in the product profiles of each of these substrates between wild type and mutant enzymes and no products consistent with chemistry of the ferric-peroxo species were observed to increase.

Cineole biodegradation: Molecular cloning, expression and characterisation of (1R)-6β-hydroxycineole dehydrogenase from Citrobacter braakii

The first steps in the biodegradation of 1,8-cineole involve the introduction of an alcohol and its subsequent oxidation to a ketone. In Citrobacter braakii, cytochrome P450(cin) has previously been demonstrated to perform the first oxidation to produce (1R)-6beta-hydroxycineole. In this study, we have cloned cinD from C. braakii and expressed the gene product, which displays significant homology to a number of short-chain alcohol dehydrogenases. It was demonstrated that the gene product of cinD exhibits (1R)-6beta-hydroxycineole dehydrogenase activity, the second step in the degradation of 1,8-cineole. All four isomers of 6-hydroxycineole were examined but only (1R)-6beta-hydroxycineole was converted to (1R)-6-ketocineole. The (1R)-6beta-hydroxycineole dehydrogenase exhibited a strict requirement for NAD(H), with no reaction observed in the presence of NADP(H). The enzyme also catalyses the reverse reaction, reducing (1R)-6-ketocineole to (1R)-6beta-hydroxycineole. During this study the N-terminal His-tag used to assist protein purification was found to interfere with NAD(H) binding and lower enzyme activity. This could be recovered by the addition of Ni(2+) ions or proteolytic removal of the His-tag.

Cytochrome P450 is present in both Ferrous and Ferric forms in the resting state within intact Escherichia coli and Hepatocytes

Background: P450 catalytic cycles start with Fe(III) in vitro, but the resting form in vivo is unknown. Results: Significant Fe(II) P450 is present in intact cells even after vigorous aeration. Conclusion: The P450 form and cell environment determine the proportion of Fe(II) P450 in vivo. Significance: Fe(II) in the resting state is unexpected due to the potential for futile cycling. Cytochrome P450 enzymes (P450s) are exceptionally versatile monooxygenases, mediating hydroxylations of unactivated C–H bonds, epoxidations, dealkylations, and N- and S-oxidations as well as other less common reactions. In the conventional view of the catalytic cycle, based upon studies of P450s in vitro, substrate binding to the Fe(III) resting state facilitates the first 1-electron reduction of the heme. However, the resting state of P450s in vivo has not been examined. In the present study, whole cell difference spectroscopy of bacterial (CYP101A1 and CYP176A1, i.e. P450cam and P450cin) and mammalian (CYP1A2, CYP2C9, CYP2A6, CYP2C19, and CYP3A4) P450s expressed within intact Escherichia coli revealed that both Fe(III) and Fe(II) forms of the enzyme are present in the absence of substrates. The relevance of this finding was supported by similar observations of Fe(II) P450 heme in intact rat hepatocytes. Electron paramagnetic resonance (EPR) spectroscopy of the bacterial forms in intact cells showed that a proportion of the P450 in cells was in an EPR-silent form in the native state consistent with the presence of Fe(II) P450. Coexpression of suitable cognate electron donors increased the degree of endogenous reduction to over 80%. A significant proportion of intracellular P450 remained in the Fe(II) form after vigorous aeration of cells. The addition of substrates increased the proportion of Fe(II) heme, suggesting a kinetic gate to heme reduction in the absence of substrate. In summary, these observations suggest that the resting state of P450s should be regarded as a mixture of Fe(III) and Fe(II) forms in both aerobic and oxygen-limited conditions.