Family portraits: the enzymes behind benzylisoquinoline alkaloid diversity

Benzylisoquinoline alkaloids (BIAs) are a group of specialized metabolites found predominantly in the plant order Ranunculales. Approximately 2500 naturally occurring BIAs have been identified, many of which possess a variety of potent biological and pharmacological properties. The initial BIA skeleton is formed via condensation by a unique enzyme, norcoclaurine synthase, of the l-tyrosine derivatives dopamine and 4-hydroxyphenylacetaldehyde, yielding (S)-norcoclaurine as a central intermediate. The vast diversity of BIA structures is subsequently derived from (1) transformation of the basic BIA backbone by oxidative enzymes, particularly cytochromes P450 and FAD-linked oxidases, and (2) further structural and functional group modification by tailoring enzymes, which also include various reductases, dioxygenases, acetyltransferases, and carboxylesterases. Most of the biosynthetic enzymes responsible for the biosynthesis of major BIAs (i.e. morphine, noscapine, papaverine, and sanguinarine) in opium poppy (Papaver somniferum), and other compounds (e.g. berberine) in related plants, have been isolated and partially characterized. Diversity in BIA metabolism is driven by the modular and repetitive recruitment, and subsequent neo-functionalization, of a limited number of ancestral enzymes. In this review, BIA biosynthetic enzymes are discussed in the context of their respective families, facilitating exploration of common phylogeny and biochemical mechanisms.     

Benzylisoquinoline alkaloid biosynthesis in opium poppy

Opium poppy (Papaver somniferum) is one of the world’s oldest medicinal plants and remains the only commercial source for the narcotic analgesics morphine, codeine and semi-synthetic derivatives such as oxycodone and naltrexone. The plant also produces several other benzylisoquinoline alkaloids with potent pharmacological properties including the vasodilator papaverine, the cough suppressant and potential anticancer drug noscapine and the antimicrobial agent sanguinarine. Opium poppy has served as a model system to investigate the biosynthesis of benzylisoquinoline alkaloids in plants. The application of biochemical and functional genomics has resulted in a recent surge in the discovery of biosynthetic genes involved in the formation of major benzylisoquinoline alkaloids in opium poppy. The availability of extensive biochemical genetic tools and information pertaining to benzylisoquinoline alkaloid metabolism is facilitating the study of a wide range of phenomena including the structural biology of novel catalysts, the genomic organization of biosynthetic genes, the cellular and sub-cellular localization of biosynthetic enzymes and a variety of biotechnological applications. In this review, we highlight recent developments and summarize the frontiers of knowledge regarding the biochemistry, cellular biology and biotechnology of benzylisoquinoline alkaloid biosynthesis in opium poppy.     

Atomic structure of salutaridine reductase from the opium poppy (Papaver somniferum)

The opium poppy (Papaver somniferum L.) is one of the oldest known medicinal plants. In the biosynthetic pathway for morphine and codeine, salutaridine is reduced to salutaridinol by salutaridine reductase (SalR; EC 1.1.1.248) using NADPH as coenzyme. Here, we report the atomic structure of SalR to a resolution of ∼1.9 Å in the presence of NADPH. The core structure is highly homologous to other members of the short chain dehydrogenase/reductase family. The major difference is that the nicotinamide moiety and the substrate-binding pocket are covered by a loop (residues 265–279), on top of which lies a large “flap”-like domain (residues 105–140). This configuration appears to be a combination of the two common structural themes found in other members of the short chain dehydrogenase/reductase family. Previous modeling studies suggested that substrate inhibition is due to mutually exclusive productive and nonproductive modes of substrate binding in the active site. This model was tested via site-directed mutagenesis, and a number of these mutations abrogated substrate inhibition. However, the atomic structure of SalR shows that these mutated residues are instead distributed over a wide area of the enzyme, and many are not in the active site. To explain how residues distal to the active site might affect catalysis, a model is presented whereby SalR may undergo significant conformational changes during catalytic turnover.     

Production of benzylisoquinoline alkaloids in Saccharomyces cerevisiae

The benzylisoquinoline alkaloids (BIAs) are a diverse class of metabolites that exhibit a broad range of pharmacological activities and are synthesized through plant biosynthetic pathways comprised of complex enzyme activities and regulatory strategies. We have engineered yeast to produce the key intermediate reticuline and downstream BIA metabolites from a commercially available substrate. An enzyme tuning strategy was implemented that identified activity differences between variants from different plants and determined optimal expression levels. By synthesizing both stereoisomer forms of reticuline and integrating enzyme activities from three plant sources and humans, we demonstrated the synthesis of metabolites in the sanguinarine/berberine and morphinan branches. We also demonstrated that a human P450 enzyme exhibits a novel activity in the conversion of (R)-reticuline to the morphinan alkaloid salutaridine. Our engineered microbial hosts offer access to a rich group of BIA molecules and associated activities that will be further expanded through synthetic chemistry and biology approaches.     

Synthesis of Morphinan Alkaloids in Saccharomyces cerevisiae

Morphinan alkaloids are the most powerful narcotic analgesics currently used to treat moderate to severe and chronic pain. The feasibility of morphinan synthesis in recombinant Saccharomyces cerevisiae starting from the precursor (R,S)-norlaudanosoline was investigated. Chiral analysis of the reticuline produced by the expression of opium poppy methyltransferases showed strict enantioselectivity for (S)-reticuline starting from (R,S)-norlaudanosoline. In addition, the P. somniferum enzymes salutaridine synthase (PsSAS), salutaridine reductase (PsSAR) and salutaridinol acetyltransferase (PsSAT) were functionally co-expressed in S. cerevisiae and optimization of the pH conditions allowed for productive spontaneous rearrangement of salutaridinol-7-O-acetate and synthesis of thebaine from (R)-reticuline. Finally, we reconstituted a 7-gene pathway for the production of codeine and morphine from (R)-reticuline. Yeast cell feeding assays using (R)-reticuline, salutaridine or codeine as substrates showed that all enzymes were functionally co-expressed in yeast and that activity of salutaridine reductase and codeine-O-demethylase likely limit flux to morphine synthesis. The results of this study describe a significant advance for the synthesis of morphinans in S. cerevisiae and pave the way for their complete synthesis in recombinant microbes.     

Removal of Substrate Inhibition and Increase in Maximal Velocity in the Short Chain Dehydrogenase/Reductase Salutaridine Reductase Involved in Morphine Biosynthesis

Salutaridine reductase (SalR, EC 1.1.1.248) catalyzes the stereospecific reduction of salutaridine to 7(S)-salutaridinol in the biosynthesis of morphine. It belongs to a new, plant-specific class of short-chain dehydrogenases, which are characterized by their monomeric nature and increased length compared with related enzymes. Homology modeling and substrate docking suggested that additional amino acids form a novel α-helical element, which is involved in substrate binding. Site-directed mutagenesis and subsequent studies on enzyme kinetics revealed the importance of three residues in this element for substrate binding. Further replacement of eight additional residues led to the characterization of the entire substrate binding pocket. In addition, a specific role in salutaridine binding by either hydrogen bond formation or hydrophobic interactions was assigned to each amino acid. Substrate docking also revealed an alternative mode for salutaridine binding, which could explain the strong substrate inhibition of SalR. An alternate arrangement of salutaridine in the enzyme was corroborated by the effect of various amino acid substitutions on substrate inhibition. In most cases, the complete removal of substrate inhibition was accompanied by a substantial loss in enzyme activity. However, some mutations greatly reduced substrate inhibition while maintaining or even increasing the maximal velocity. Based on these results, a double mutant of SalR was created that exhibited the complete absence of substrate inhibition and higher activity compared with wild-type SalR.The benzylisoquinoline alkaloids (BIAs)³ comprise a large and diverse group of nitrogen-containing secondary metabolites with about 2500 compounds identified in plants (1). Among them are several important pharmaceuticals, such as the antimicrobials berberine and sanguinarine, and the vasodilator papaverine. The most prominent compounds of this class are the antitussive codeine, the analgesic morphine, and their biosynthetic precursor thebaine. The latter is used as the starting molecule for the production of a variety of semi-synthetic analgesics including oxycontin and buprenorphine. Pentacyclic morphinan alkaloids possess several chiral centers, which preclude chemical synthesis as an option for the efficient production of these widely used pharmaceuticals. Therefore, the worldwide supply of these narcotic compounds is still achieved by their isolation mainly from the opium poppy, Papaver somniferum L. With the availability of an increasing number of isolated genes encoding several pathway enzymes, recent interest has focused on the qualitative and quantitative modulation of the alkaloid profile in transgenic opium poppy plants (2–6), the production of BIAs in microbes (7, 8), and de novo synthesis by a combination of chemical and biochemical conversions. BIA biosynthesis begins with the condensation of the tyrosine-derived precursors dopamine and p-hydroxyphenylacetaldehyde to (S)-norcoclaurine (see Fig. 1) (1). Subsequent regiospecific O- and N-methylations and aromatic ring hydroxylation lead to (S)-reticuline, which is the central intermediate for almost all BIAs. For morphinan alkaloid biosynthesis, (S)-reticuline undergoes an inversion of stereochemistry to (R)-reticuline, followed by C-C phenol coupling catalyzed by a unique cytochrome P450-dependent monooxygenase to yield salutaridine. Subsequent stereospecific reduction to 7(S)-salutaridinol is required for the attachment of an acetyl moiety to produce salutaridinol-7-O-acetate, which spontaneously rearranges to thebaine (9). The O-demethylation of thebaine and the reduction of codeinone to codeine represent the penultimate steps in morphine biosynthesis. Cognate cDNAs have been isolated for all of the enzymes leading to (S)-reticuline, as well as those involved in the conversion of (R)-reticuline to salutaridine-7-O-acetate (1). Salutaridine reductase (SalR, EC 1.1.1.248) catalyzes the stereospecific, NADPH-dependent reduction of salutaridine to 7(S)-salutaridinol and is a member of the classical subgroup of the short chain dehydrogenase/reductase (SDR) protein family (10, 11). The main characteristics of this category of SDRs are the largely conserved TGXXXGhG motif for cofactor binding and the YXXXK motif, which together with an upstream Ser residue represent the catalytic center (12). In this catalytic triad, Lys forms hydrogen bonds with the ribose moiety of the cofactor, which itself is hydrogen bonded to Tyr. This hydrogen bond network is presumed to lower the pK_a of the Tyr hydroxyl group, which functions as the catalytic base. Ser has been suggested to either stabilize the substrate (13, 14) or to interact with Tyr (15). Additionally, an Asn residue has been proposed to stabilize the position of the Lys residue, thereby forming a proton relay system involving water (16). Most other members of the SDR protein family are categorized into three additional subgroups (i.e. divergent, intermediate, or complex) exhibiting different overall sizes and slight amino acid sequence variations in conserved regions (17). Non-classical SDRs predominantly consist of isomerases (EC 5.-.-.-), such as galactose epimerase, and lyases (EC 4.-.-.-), such as glucose dehydratase, whereas classical SDRs encompass oxidoreductases (EC 1.-.-.-), such as SalR. Although classical SDRs are typically multimeric, SalR is a monomer because of an additional stretch of 40 amino acids preceding the YXXXK catalytic motif. In porcine testicular carbonyl reductase, these amino acids form a helix blocking the dimer interface (18) and homology modeling revealed a similar feature in SalR (19). In contrast with porcine testicular carbonyl reductase, SalR exhibits an additional stretch of 40 amino acids that have only been detected in some SDRs from plants (11, 20–22). Although attempts to obtain a crystal structure for SalR have so far been unsuccessful, homology modeling using porcine testicular carbonyl reductase as a template produced a tertiary structure in which the additional amino acids form an additional helix (19). The subsequent docking of salutaridine into the active site of this model suggested the involvement of this structural element in substrate binding, which was supported by preliminary site-directed mutagenesis.Open in a separate windowFIGURE 1.Selected steps in morphine biosynthesis. Double arrows indicate the involvement of more than one enzyme. The SalR reaction is highlighted. HPAA, p-hydroxyphenylacetaldehyde; SalR, salutaridine reductase.SalR from the Persian poppy Papaver bracteatum L. shows strong substrate inhibition with a K_i around 150 μm (19). Substrate inhibition can substantially and negatively impact chemical engineering strategies by limiting the quantity of substrate that can be fed into a system, which reduces overall efficiency. The strong substrate inhibition exhibited by SalR could limit its biotechnological application in plant, microbial, or enzyme-based systems. To investigate the structural basis of substrate inhibition, we substituted all amino acids putatively involved in salutaridine binding and analyzed various kinetic parameters. Over the course of these experiments, substrate docking required modification because some mutations had unexpected consequences that did not fully agree with the original docking. The discrepancy was mainly due to the side chain arrangements of amino acids residing in the new helix. Precise prediction of this domain is difficult because of the lack of an equivalent crystal structure. In this report, we present a revised substrate docking for salutaridine into SalR, supported by comprehensive site-directed mutagenesis, which facilitated the creation of an enzyme variant devoid of substrate inhibition.     

Transformation of opium poppy (<Emphasis Type="Italic">Papaver somniferum</Emphasis>L.) with antisense berberine bridge enzyme gene (<Emphasis Type="Italic">anti-bbe</Emphasis>) via somatic embryogenesis results in an altered ratio of alkaloids in latex but not in roots

The berberine bridge enzyme cDNA bbe from Papaver somniferumL. was transformed in antisense orientation into seedling explants of the industrial elite line C048-6-14-64. In this way, 84 phenotypically normal T₀ plants derived from embryogenic callus cultures were produced. The selfed progeny of these 84 plants yielded several T₁ plants with an altered alkaloid profile. One of these plants T₁-47, and its siblings T₂-1.2 and T₂-1.5 are the subject of the present work. The transformation of these plants was evaluated by PCR, and northern and Southern hybridisation. The transgenic plants contained one additional copy of the transgene. The alkaloid content in latex and roots was determined with HPLC and LC-MS. We observed an increased concentration of several pathway intermediates from all biosynthetic branches, e.g., reticuline, laudanine, laudanosine, dehydroreticuline, salutaridine and (S)-scoulerine. The transformation altered the ratio of morphinan and tetrahydrobenzylisoquinoline alkaloids in latex but not the benzophenanthridine alkaloids in roots. The altered alkaloid profile is heritable at least to the T₂ generation. These results are the first example of metabolic engineering of the alkaloid pathways in opium poppy and, to our knowledge, the first time that an alkaloid biosynthetic gene has been transformed into the native species, followed by regeneration into a mature plant to enable analyses of the effect of the transgene on metabolism over several generations.     

Comparative transcript and alkaloid profiling in Papaver species identifies a short chain dehydrogenase/reductase involved in morphine biosynthesis

Plants of the order Ranunculales, especially members of the species Papaver, accumulate a large variety of benzylisoquinoline alkaloids with about 2500 structures, but only the opium poppy (Papaver somniferum) and Papaver setigerum are able to produce the analgesic and narcotic morphine and the antitussive codeine. In this study, we investigated the molecular basis for this exceptional biosynthetic capability by comparison of alkaloid profiles with gene expression profiles between 16 different Papaver species. Out of 2000 expressed sequence tags obtained from P. somniferum, 69 show increased expression in morphinan alkaloid-containing species. One of these cDNAs, exhibiting an expression pattern very similar to previously isolated cDNAs coding for enzymes in benzylisoquinoline biosynthesis, showed the highest amino acid identity to reductases in menthol biosynthesis. After overexpression, the protein encoded by this cDNA reduced the keto group of salutaridine yielding salutaridinol, an intermediate in morphine biosynthesis. The stereoisomer 7-epi-salutaridinol was not formed. Based on its similarities to a previously purified protein from P. somniferum with respect to the high substrate specificity, molecular mass and kinetic data, the recombinant protein was identified as salutaridine reductase (SalR; EC 1.1.1.248). Unlike codeinone reductase, an enzyme acting later in the pathway that catalyses the reduction of a keto group and which belongs to the family of the aldo-keto reductases, the cDNA identified in this study as SalR belongs to the family of short chain dehydrogenases/reductases and is related to reductases in monoterpene metabolism.     

Evidence for the monophyletic evolution of benzylisoquinoline alkaloid biosynthesis in angiosperms

Benzylisoquinoline alkaloids (BIAs) consist of more than 2500 diverse structures largely restricted to the order Ranunculales and the eumagnoliids. However, BIAs also occur in the Rutaceae, Lauraceae, Cornaceae and Nelumbonaceae, and sporadically throughout the order Piperales. Several of these alkaloids function in the defense of plants against herbivores and pathogens--thus the capacity for BIA biosynthesis is expected to play an important role in the reproductive fitness of certain plants. Biochemical and molecular phylogenetic approaches were used to investigate the evolution of BIA biosynthesis in basal angiosperms. The occurrence of (S)-norcoclaurine synthase (NCS; EC 4.2.1.78) activity in 90 diverse plant species was compared to the distribution of BIAs superimposed onto a molecular phylogeny. These results support the monophyletic origin of BIA biosynthesis prior to the emergence of the eudicots. Phylogenetic analysis of NCS, berberine bridge enzyme and several O-methyltransferases suggest a latent molecular fingerprint for BIA biosynthesis in angiosperms not known to accumulate such alkaloids. The limited occurrence of BIAs outside the Ranunculales and eumagnoliids suggests the requirement for a highly specialized, yet evolutionarily unstable cellular platform to accommodate or reactivate the pathway in divergent taxa. The molecular cloning and functional characterization of NCS from opium poppy (Papaver somniferum L.) is also reported. Pathogenesis--related (PR)10 and Bet v 1 major allergen proteins share homology with NCS, but recombinant polypeptides were devoid of NCS activity.     

Evidence for the monophyletic evolution of benzylisoquinoline alkaloid biosynthesis in angiosperms

Benzylisoquinoline alkaloids (BIAs) consist of more than 2500 diverse structures largely restricted to the order Ranunculales and the eumagnoliids. However, BIAs also occur in the Rutaceae, Lauraceae, Cornaceae and Nelumbonaceae, and sporadically throughout the order Piperales. Several of these alkaloids function in the defense of plants against herbivores and pathogens - thus, the capacity for BIA biosynthesis is expected to play an important role in the reproductive fitness of certain plants. Biochemical and molecular phylogenetic approaches were used to investigate the evolution of BIA biosynthesis in basal angiosperms. The occurrence of (S)-norcoclaurine synthase (NCS; EC 4.2.1.78) activity in 90 diverse plant species was compared to the distribution of BIAs superimposed onto a molecular phylogeny. These results support the monophyletic origin of BIA biosynthesis prior to the emergence of the eudicots. Phylogenetic analyses of NCS, berberine bridge enzyme and several O-methyltransferases suggest a latent molecular fingerprint for BIA biosynthesis in angiosperms not known to accumulate such alkaloids. The limited occurrence of BIAs outside the Ranunculales and eumagnoliids suggests the requirement for a highly specialized, yet evolutionarily unstable cellular platform to accommodate or reactivate the pathway in divergent taxa. The molecular cloning and functional characterization of NCS from opium poppy (Papaver somniferum L.) is also reported. Pathogenesis-related (PR)10 and Bet v 1 major allergen proteins share homology with NCS, but recombinant polypeptides were devoid of NCS activity.     

Structural studies of codeinone reductase reveal novel insights into aldo-keto reductase function in benzylisoquinoline alkaloid biosynthesis

Benzylisoquinoline alkaloids (BIAs) are a class of specialized metabolites with a diverse range of chemical structures and physiological effects. Codeine and morphine are two closely related BIAs with particularly useful analgesic properties. The aldo-keto reductase (AKR) codeinone reductase (COR) catalyzes the final and penultimate steps in the biosynthesis of codeine and morphine, respectively, in opium poppy (Papaver somniferum). However, the structural determinants that mediate substrate recognition and catalysis are not well defined. Here, we describe the crystal structure of apo-COR determined to a resolution of 2.4 Å by molecular replacement using chalcone reductase as a search model. Structural comparisons of COR to closely related plant AKRs and more distantly related homologues reveal a novel conformation in the β1α1 loop adjacent to the BIA-binding pocket. The proximity of this loop to several highly conserved active-site residues and the expected location of the nicotinamide ring of the NADP(H) cofactor suggest a model for BIA recognition that implies roles for several key residues. Using site-directed mutagenesis, we show that substitutions at Met-28 and His-120 of COR lead to changes in AKR activity for the major and minor substrates codeinone and neopinone, respectively. Our findings provide a framework for understanding the molecular basis of substrate recognition in COR and the closely related 1,2-dehydroreticuline reductase responsible for the second half of a stereochemical inversion that initiates the morphine biosynthesis pathway.     

Search for new natural sources of morphinans

Codeine, medically the most widely used opiate, is mostly derived from morphine, isolated from opium and poppy straw (Papaver somniferum, opium poppy). Morphine, however, is greatly misused by illegal conversion into its diacetyl-derivative: heroin. The discovery of an efficient alternative medicine or a source for codeine other than opium poppy may contribute to a curtailment of the heroin market. No major adverse properties should be present in such a new medicine or codeine source. In this paper the search for the latter is discussed with regards to the natural occurrence of morphinan derivatives and the biosynthetic pathways in available plants. Economic and social problems connected with the introduction of a new biological source for opiates are reviewed.     

CYP719B1 Is Salutaridine Synthase, the C-C Phenol-coupling Enzyme of Morphine Biosynthesis in Opium Poppy

Morphine is a powerful analgesic natural product produced by the opium poppy Papaver somniferum. Although formal syntheses of this alkaloid have been reported, the morphine molecule contains five stereocenters and a C-C phenol linkage that to date render a total synthesis of morphine commercially unfeasible. The C-C phenol-coupling reaction along the biosynthetic pathway to morphine in opium poppy is catalyzed by the cytochrome P450-dependent oxygenase salutaridine synthase. We report herein on the identification of salutaridine synthase as a member of the CYP719 family of cytochromes P450 during a screen of recombinant cytochromes P450 of opium poppy functionally expressed in Spodoptera frugiperda Sf9 cells. Recombinant CYP719B1 is a highly stereo- and regioselective enzyme; of forty-one compounds tested as potential substrates, only (R)-reticuline and (R)-norreticuline resulted in formation of a product (salutaridine and norsalutaridine, respectively). To date, CYP719s have been characterized catalyzing only the formation of a methylenedioxy bridge in berberine biosynthesis (canadine synthase, CYP719A1) and in benzo[c]phenanthridine biosynthesis (stylopine synthase, CYP719A14). Previously identified phenol-coupling enzymes of plant alkaloid biosynthesis belong only to the CYP80 family of cytochromes. CYP719B1 therefore is the prototype for a new family of plant cytochromes P450 that catalyze formation of a phenol-couple.The C-O or C-C phenol-couple is widely present in the plant kingdom in natural product biosynthetic processes such as alkaloid (1), lignan (2), lignin (3), and gallotannin (4) formation. Phenol-coupling reactions in nature were thought to be catalyzed by a variety of oxidative enzymes with broad substrate specificity such as peroxidases, polyphenol oxidases, and laccases. More recently, several enzymes discovered to be responsible for the formation of intermolecular C-O phenol and intramolecular C-C phenol-couples were found to be highly regio- and/or stereoselective catalysts. The first intermolecular C-O phenol-coupling enzyme identified was the cytochrome P450-dependent oxidase berbamunine synthase (CYP80A1) of bisbenzylisoquinoline alkaloid biosynthesis in Berberis cell cultures (5, 6) (Fig. 1). This enzyme is regiospecific, but will accept either (R)- and (S)-N-methylcoclaurine to form R-R and R-S phenol-coupled products. Absolute regio- and stereospecificity is demonstrated in the formation of the lignan (+)-pinoresinol from two molecules of coniferyl alcohol, a reaction guided by dirigent proteins that can be catalyzed by a range of oxidases or oxidants (7). The aporphine alkaloid intramolecular C-C phenol-couple is catalyzed in Coptis japonica cell cultures by the cytochrome P450-dependent oxidase CYP80G2; this enzyme accepts six tetrahydrobenzylisoquinoline alkaloids as substrate (8).Open in a separate windowFIGURE 1.Selected phenol-coupling reactions of alkaloid biosynthesis. Berbamunine synthase (CYP80A1) catalyzes the C-O intermolecular phenol-coupling reaction of bisbenzyisoquinoline alkaloid biosynthesis. (S)-Corytuberine synthase (CYP80G2) catalyzes formation of the intramolecular C-C phenol-couple in magnoflorine biosynthesis. Salutaridine synthase forms the C-C intramolecular phenol-couple of salutaridine in morphine biosynthesis.Morphine has often been described as the king of alkaloids. Although formal syntheses of this powerful analgesic have been reported, yields are low (Ref. 9 and references therein); attempts in organic chemistry to mimic the biosynthetic formation of the C-C phenol-couple of salutaridine (Fig. 1) have been either unsuccessful, yielding rather isoboldine or pallidine (10), or have resulted in very low yield of salutaridine (11) or in a mixture of isoboldine and salutaridine, with the reaction favoring formation of isoboldine by a factor of ∼5 (12). Along with the five stereocenters present in this molecule, the C-C phenol-couple renders a chemical synthesis of morphine commercially unfeasible. The enzyme catalyzing this reaction in planta was sought unsuccessfully for many years and was discovered finally in the opium poppy Papaver somniferum to be a cytochrome P450-dependent oxidase that stereo- and regiospecifically produces salutaridine by C-C phenol-coupling of (R)-reticuline (Fig. 1) (1, 13). The native enzyme salutaridine synthase was unstable, which precluded protein purification for further characterization.Herein, we describe the identification and functional expression of opium poppy salutaridine synthase, a member of the cytochrome P450 family, in Spodoptera frugiperda Sf9 cells. The recombinant enzyme was sufficiently stable in insect cell culture to be characterized with respect to substrate specificity and steady state kinetic values. Recombinant salutaridine synthase converted (R)-reticuline exclusively to salutaridine and (R)-norreticuline exclusively to norsalutaridine (N-demethylsalutaridine).