Plant cytochrome P450s from moss to poplar

This review represents the first attempt to define the origins of the major P450-containing pathways in plants. Comparative genomics with five complete P450 gene sets from Chlamydomonas reinhardtii with 39 sequences, Physcomitrella patens (moss) with 71 sequences, rice with 356 sequences, Arabidopsis with 246 sequences and Populus with 312 sequences is used to estimate how old each gene family is and to identify the most ancient P450s and their pathways. The pathways included are the phenylpropanoid and lignin pathways, the gibberellin pathway, the oxylipin/jasmonate pathway, the basic flavonoid pathway, the brassinosteroid pathway, the abscisic acid pathway and the cutin synthesis pathway. An effort is made to identify at least some examples of P450s that have emerged at many different levels of the evolutionary bush, from the base to the tips.     

Regulation of the biosynthesis of plant hormones by cytochrome P450s

 Cytochrome P450 monooxygenases are a large group of heme-containing enzymes, most of which catalyze hydroxylation reactions. Since the discovery of cytochrome P450 in plants, more than 500 forms have been found, and they appear to be involved in the biosynthetic pathways of a large variety of primary and secondary metabolites. In particular, cytochrome P450s are involved in the biosynthesis of plant hormones, and play important roles in the regulation of plant growth and development. Recent genetic and functional analyses of cytochrome P450s in plants have significantly improved our understanding of not only the biosynthetic pathways themselves, but also of plant development from the perspective of hormonal control of morphogenesis. This review summarizes the present status of research on cytochrome P450s' roles in regulating the biosynthesis of plant hormones. Received: January 30, 2002 / Accepted: March 4, 2002     

Improved cloning and expression of cytochrome P450s and cytochrome P450 reductase in yeast

Combination of the pYeDP60 yeast expression system with a modified version of the improved uracil-excision (USER) cloning technique provides a new powerful tool for high-throughput expression of eukaryotic cytochrome P450s. The vector presented is designed to obtain an optimal 5' untranslated sequence region for yeast (Kozak consensus sequence), and has been tested to produce active P450s and NADPH-cytochrome P450 oxidoreductase (CPR) after 5' end silent codon optimization of the cDNA sequences. Expression of two plant cytochrome P450s, Sorghum bicolor CYP79A1 and CYP71E1, and S. bicolor CPR2 using the modified pYeDP60 vector in all three cases produced high amounts of active protein. High-throughput functional expression of cytochrome P450s have long been a troublesome task due to the workload involved in cloning of each individual P450 into a suitable expression vector. The redesigned yeast P450 expression vector (pYeDP60u) offers major improvements in cloning efficiency, speed, fidelity, and simplicity. The modified version of the USER cloning system provides great potential for further development of other yeast vectors, transforming these into powerful high-throughput expression vectors.     

The cytochrome P450 genesis locus: the origin and evolution of animal cytochrome P450s

The neighbourhoods of cytochrome P450 (CYP) genes in deuterostome genomes, as well as those of the cnidarians Nematostella vectensis and Acropora digitifera and the placozoan Trichoplax adhaerens were examined to find clues concerning the evolution of CYP genes in animals. CYP genes created by the 2R whole genome duplications in chordates have been identified. Both microsynteny and macrosynteny were used to identify genes that coexisted near CYP genes in the animal ancestor. We show that all 11 CYP clans began in a common gene environment. The evidence implies the existence of a single locus, which we term the ‘cytochrome P450 genesis locus’, where one progenitor CYP gene duplicated to create a tandem set of genes that were precursors of the 11 animal CYP clans: CYP Clans 2, 3, 4, 7, 19, 20, 26, 46, 51, 74 and mitochondrial. These early CYP genes existed side by side before the origin of cnidarians, possibly with a few additional genes interspersed. The Hox gene cluster, WNT genes, an NK gene cluster and at least one ARF gene were close neighbours to this original CYP locus. According to this evolutionary scenario, the CYP74 clan originated from animals and not from land plants nor from a common ancestor of plants and animals. The CYP7 and CYP19 families that are chordate-specific belong to CYP clans that seem to have originated in the CYP genesis locus as well, even though this requires many gene losses to explain their current distribution. The approach to uncovering the CYP genesis locus overcomes confounding effects because of gene conversion, sequence divergence, gene birth and death, and opens the way to understanding the biodiversity of CYP genes, families and subfamilies, which in animals has been obscured by more than 600 Myr of evolution.     

Plant cytochrome P450-mediated herbicide metabolism

In the last two decades it has become apparent that enzymes of the P450 monooxygenase (P450) superfamily are responsible for the Phase I metabolism of numerous herbicides representing several classes of organic compounds. The majority of experimental evidence for P450 involvement in herbicide metabolism has been derived from in vitro studies in which the catalytic activity of plant microsomes towards herbicidal substrates was measured in the presence of various P450 inhibitors and activators. While the studies with microsomes elicited much appreciation for the pivotal roles of plant P450s in herbicide metabolism, detailed characterization of these enzymes only became possible after the isolation of genes encoding specific isoforms responsible for herbicide conversion. Several lines of evidence suggest that the development of herbicide resistance in weeds by enhanced detoxification is frequently associated with elevated levels of P450 activity. Enhanced detoxification-based herbicide resistance is particularly difficult to control, because it can involve resistance to multiple, chemically unrelated classes of herbicides. Continued research efforts are aimed at elucidating the role of P450s in the metabolic fates of herbicides in plants and the development of herbicide resistance in weeds. Recent advances made in the isolation and genetic manipulation of P450 enzymes have created new opportunities for their application in engineering herbicide tolerance and bioremediation.     

A key cytochrome P450 hydroxylase in pradimicin biosynthesis

Pradimicins A-C (1-3) are a group of antifungal and antiviral polyketides from Actinomadura hibisca. The sugar moieties in pradimicins are required for their biological activities. Consequently, the 5-OH that is used for glycosylation plays a critical role in pradimicin biosynthesis. A cytochrome P450 monooxygenase gene, pdmJ, was amplified from the genomic DNA of A. hibisca and expressed in Escherichia coli BL21(DE3). PdmJ introduced a hydroxyl group to G-2A (4), a key pradimicin biosynthetic intermediate, at C-5 to form JX134 (5). A d-Ala-containing pradimicin analog, JX137a (6) was tested as an alternative substrate, but no product was detected by LC-MS, indicating that PdmJ has strict substrate specificity. Kinetic studies revealed a typical substrate inhibition of PdmJ activity. The optimal substrate concentration for the highest velocity is 115μM under the test conditions. Moreover, the conversion rate of 4 to 5 was reduced by the presence of 6, likely due to competitive inhibition. Coexpression of PdmJ and a glucose 1-dehydrogenase in E. coli BL21(DE3) provides an efficient method to produce the important intermediate 5 from 4.     

Metabolons involving plant cytochrome P450s

Arranging biological processes into “compartments” is a key feature of all eukaryotic cells. Through this mechanism, cells can drastically increase metabolic efficiency and manage complex cellular processes more efficiently, saving space and energy. Compartmentation at the molecular level is mediated by metabolons. A metabolon is an ordered protein complex of sequential metabolic enzymes and associated cellular structural elements. The sub-cellular organization of enzymes involved in the synthesis and storage of plant natural products appears to involve the anchoring of metabolons by cytochrome P450 monooxygenases (P450s) to specific domains of the endoplasmic reticulum (ER) membrane. This review focuses on the current evidence supporting the organization of metabolons around P450s on the surface of the ER. We␣outline direct and indirect experimental data that describes P450 enzymes in the phenylpropanoid, flavonoid, cyanogenic glucoside, and other biosynthetic pathways. We also discuss the limitations and future directions of metabolon research and the potential for application to metabolic engineering endeavors.     

A world of cytochrome P450s

The world we live in is a biosphere influenced by all organisms who inhabit it. It is also an ecology of genes, with some having rather startling effects. The premise put forth in this issue is cytochrome P450 is a significant player in the world around us. Life and the Earth itself would be visibly different and diminished without cytochrome P450s. The contributions to this issue range from evolution on the billion year scale to the colour of roses, from Darwin to Rachel Carson; all as seen through the lens of cytochrome P450.     

Involvement of a natural fusion of a cytochrome P450 and a hydrolase in mycophenolic acid biosynthesis

Mycophenolic acid (MPA) is a fungal secondary metabolite and the active component in several immunosuppressive pharmaceuticals. The gene cluster coding for the MPA biosynthetic pathway has recently been discovered in Penicillium brevicompactum, demonstrating that the first step is catalyzed by MpaC, a polyketide synthase producing 5-methylorsellinic acid (5-MOA). However, the biochemical role of the enzymes encoded by the remaining genes in the MPA gene cluster is still unknown. Based on bioinformatic analysis of the MPA gene cluster, we hypothesized that the step following 5-MOA production in the pathway is carried out by a natural fusion enzyme MpaDE, consisting of a cytochrome P450 (MpaD) in the N-terminal region and a hydrolase (MpaE) in the C-terminal region. We verified that the fusion gene is indeed expressed in P. brevicompactum by obtaining full-length sequence of the mpaDE cDNA prepared from the extracted RNA. Heterologous coexpression of mpaC and the fusion gene mpaDE in the MPA-nonproducer Aspergillus nidulans resulted in the production of 5,7-dihydroxy-4-methylphthalide (DHMP), the second intermediate in MPA biosynthesis. Analysis of the strain coexpressing mpaC and the mpaD part of mpaDE shows that the P450 catalyzes hydroxylation of 5-MOA to 4,6-dihydroxy-2-(hydroxymethyl)-3-methylbenzoic acid (DHMB). DHMB is then converted to DHMP, and our results suggest that the hydrolase domain aids this second step by acting as a lactone synthase that catalyzes the ring closure. Overall, the chimeric enzyme MpaDE provides insight into the genetic organization of the MPA biosynthesis pathway.     

The ins and outs of cytochrome P450s

The active site of cytochromes P450 is situated deep inside the protein next to the heme cofactor. Consequently, enzyme specificity and kinetics can be influenced by how substrates pass through the protein to access the active site and how products egress from the active site. We previously analysed the channels between the active site and the protein surface in P450 crystal structures available in October 2003 [R.C. Wade, P.J. Winn, I. Schlichting, Sudarko, A survey of active site access channels in cytochromes P450, J. Inorg. Biochem. 98 (2004) 1175-1182]. Since then, 52 new P450 structures have been made available, including entries for ten isozymes for which structures were not previously available. We present an updated survey covering all P450 crystal structures available in March 2006. This survey shows channels not observed earlier in crystal structures, some of which were identified in previous molecular dynamics simulations. The crystal structures demonstrate how some of the channels can merge when the protein structure opens up resulting in a wide cleft to the active site, caused largely by movements of the F-G helix-loop-helix and the B-C loop. Significant differences were observed between the channels in the crystal structures of the mammalian and bacterial enzymes. The multiplicity of channels suggests possibilities for substrate channelling to and from the P450s.     

Rearrangement reactions catalyzed by cytochrome P450s

Cytochrome P450s promote a variety of rearrangement reactions both as a consequence of the nature of the radical and other intermediates generated during catalysis, and of the neighboring structures in the substrate that can interact either with the initial radical intermediates or with further downstream products of the reactions. This article will review several kinds of previously published cytochrome P450-catalyzed rearrangement reactions, including changes in stereochemistry, radical clock reactions, allylic rearrangements, “NIH” and related shifts, ring contractions and expansions, and cyclizations that result from neighboring group interactions. Although most of these reactions can be carried out by many members of the cytochrome P450 superfamily, some have only been observed with select P450s, including some reactions that are catalyzed by specific endoperoxidases and cytochrome P450s found in plants.     

Homology modeling of plant cytochrome P450s

Plant P450 monooxygenases represent the largest family of plant proteins and the largest collection of P450s available for comparative studies and biotechnological applications. They have been shown to catalyze a diverse array of difficult chemical reactions and have demonstrated potential to be used in pharmacological, agronomic and phytoremediative applications. Central to our use of these catalytically competent enzymes is the need to understand their interactions with substrates. Because most characterized plant P450s are membrane-bound proteins that are resistant to standard X-ray and NMR structure determinations, homology modeling represents a reliable and relatively rapid alternative method for analyzing structure-function relationships and predicting substrates for many P450s that are only now being characterized. These methods, which are being widely used in mammalian P450 structure-function studies, can allow plant biologists to define critical residues interacting with substrates and, in a directed fashion, alter the reactivities of individual monooxygenases. The homology modelings that have been done on a limited number of plant P450s and the site-directed mutations that validate them indicate that current modeling and substrate docking procedures are capable of providing structural explanations for sequence variants as well as for predicting functional characteristics of undefined P450s.     

The first cytochrome P450 in ferns. Evidence for its involvement in phytoecdysteroid biosynthesis in Polypodium vulgare

The fern Polypodium vulgare is a phytoecdysteroid (PE)-producing plant. Cultures of P. vulgare prothalus produce PE, whereas prothalus-derived callus cultures do not. However, this callus line can transform topically applied ecdysone (E) to 20-hydroxyecdysone (20E), which is the last step in the biosynthetic pathway of the main plant PE. This hydroxylation is catalysed by a cytochrome P450 enzyme. E treatment of the callus line results in an increased amount of P450, showing a linear correspondence between the amount of P450 and in vivo E 20-hydroxylation activity, estimated by measuring the bioconversion of E to 20E. This activity can be inhibited by molecules that bind to the P450-heme group. E shows a P450-substrate-binding spectrum with microsomes that overexpress the P450 protein. Finally, a P450 protein was purified from E-treated calli, this being the first P450 to be described in the pterydophyte group.     

Microsomal cytochrome P450 2C5: comparison to microbial P450s and unique features

Although microsomal P450s represent the majority of P450s, only microbial P450s have been amenable to crystal structure solution. We have recently solved the first crystal structure of a microsomal P450, 2C5, a progesterone hydroxylase from rabbit. We discuss the features of the protein in common with existing structures of microbial P450s and limitations of homology modeling mammalian P450s based on the microbial structures. Unique features involving membrane, substrate and cytochrome P450 reductase interactions are also discussed.     

Plant sterol biosynthesis: novel potent and selective inhibitors of cytochrome P450-dependent obtusifoliol 14 alpha-methyl demethylase.

The R-(-) isomer of methyl 1-(2,2-dimethylindan-1-yl)imidazole-5-carboxylate (CGA 214372; 2) strongly inhibited P450-dependent obtusifoliol 14 alpha-demethylase (P450OBT.14DM) (I50 = 8 x 10(-9) M, I50/Km = 5 x 10(-5) in a maize (Zea mays) microsomal preparation. Kinetic studies indicated uncompetitive inhibition with respect to obtusifoliol. The corresponding S-(+) isomer was a 20-fold weaker inhibitor for P450OBT.14DM. The molecular features of a variety of analogues of 2 were related to their potency as inhibitors of P450OBT.14DM in vitro, allowing delineation of the key structural requirements governing inhibition of the demethylase. CGA 214372 proved to have a high degree of selectivity for P450OBT.14DM. This allowed easy distinction of this activity from other P450-dependent activities present in the maize microsomal preparation and gave strong evidence that P450OBT.14DM is a herbicidal target. Microsomal maize P450OBT.14DM and yeast P450LAN.14DM, the only known examples of P450-dependent enzymes carrying out an identical metabolic function in different eukaryotes, showed distinct inhibition patterns with CGA 214372 and ketoconazole, a substituted imidazole anti-mycotic.     

Nanoelectrochemistry of cytochrome P450s: Direct electron transfer and electrocatalysis

Direct electron transfer has been demonstrated between cytochrome P450 2B4 (CYP2B4), P450 1A2 (CYP1A2), sterol 14α-demethylase (CYP51MT) and screen printed graphite electrodes, modified by gold nanoparticles and didodecyldimethyl ammonium bromide (DDAB). The proposed method for preparation of enzymatic nanostructured electrodes may be used for electrodetection of this hemoprotein provided that 2–200 pmol P450 per electrode has been adsorbed. Electron transfer, direct electrochemical reduction and interaction with P450 substrates (oxygen, benzphetamine, lanosterol) and inhibitor ketoconazole were analyzed using cyclic voltammetry (CV), square wave (SWV) or differential pulse (DPV) voltammetry, and amperometry.     

Secondary structure and membrane topology of cytochrome P450s

The secondary structure prediction of 19 microsomal cytochrome P450s from two different families was made on the basis of their amino acid sequences. It was shown that there is structural similarity between the heme-binding sites in these enzymes and those in the bacterial P450cam. An average predicted secondary structure of cytochrome P450 proteins with 70% accuracy contains about 46% alpha-helices, 12% beta-sheets, 9% beta-turns, and 33% random coils. In the region of residues 35-120 in microsomal P450s two adjacent beta alpha beta-units (the Rossmann domain), were recognized and may be available to interact with the NADPH-cytochrome P450 reductase. Using the procedure for identification of hydrophobic and membrane-associated alpha-helical segments, only one N-terminal transmembrane anchor was predicted. Also the heme-binding site may include the surface-bound helix. A model for vertebrate microsomal P450s having an amphipathic membrane protein located on the cytoplasmic side of the endoplasmic reticulum membrane, with their active center lying outside or on the bilayer border, is proposed.     

Interactions of cytochrome P450s with their ligands

Cytochrome P450s (CYPs) are heme-containing monooxygenases that contribute to an enormous range of enzymatic function including biosynthetic and detoxification roles. This review summarizes recent studies concerning interactions of CYPs with ligands including substrates, inhibitors, and diatomic heme-ligating molecules. These studies highlight the complexity in the relationship between the heme spin state and active site occupancy, the roles of water in directing protein–ligand and ligand–heme interactions, and the details of interactions between heme and gaseous diatomic CYP ligands. Both kinetic and thermodynamic aspects of ligand binding are considered.