Morphine Biosynthesis in Opium Poppy Involves Two Cell Types: Sieve Elements and Laticifers

Immunofluorescence labeling and shotgun proteomics were used to establish the cell type–specific localization of morphine biosynthesis in opium poppy (Papaver somniferum). Polyclonal antibodies for each of six enzymes involved in converting (R)-reticuline to morphine detected corresponding antigens in sieve elements of the phloem, as described previously for all upstream enzymes transforming (S)-norcoclaurine to (S)-reticuline. Validated shotgun proteomics performed on whole-stem and latex total protein extracts generated 2031 and 830 distinct protein families, respectively. Proteins corresponding to nine morphine biosynthetic enzymes were represented in the whole stem, whereas only four of the final five pathway enzymes were detected in the latex. Salutaridine synthase was detected in the whole stem, but not in the latex subproteome. The final three enzymes converting thebaine to morphine were among the most abundant active latex proteins despite a limited occurrence in laticifers suggested by immunofluorescence labeling. Multiple charge isoforms of two key O-demethylases in the latex were revealed by two-dimensional immunoblot analysis. Salutaridine biosynthesis appears to occur only in sieve elements, whereas conversion of thebaine to morphine is predominant in adjacent laticifers, which contain morphine-rich latex. Complementary use of immunofluorescence labeling and shotgun proteomics has substantially resolved the cellular localization of morphine biosynthesis in opium poppy.     

Morphine metabolism and normorphine in Papaver somniferum

Normorphine has been established as an active metabolite of morphine in P. somniferum. This was done by, (a) demonstrating the presence of normorphine throughout the life cycle of the plant, (b) finding normorphine-¹⁴C after feeding morphine-¹⁴C via the roots, and (c) exposing opium poppies to ¹⁴CO₂ under steady state conditions which led to morphine and normorphine of the same specific activity. Feeding normorphine-¹⁴C showed that the N-demethylation step is irreversible. A sensitive procedure was developed for the detection of normorphine in the presence of large amounts of morphine; using this procedure, normorphine was found in raw opium. These results indicate that the major, if not the sole, morphine degradative pathway involves an initial demethylation to normorphine, which is subsequently degraded to non-alkaloidal metabolites. The high rates of turnover observed led to the conclusion that the morphine alkaloids do play an active metabolic role, perhaps as specific methylating agents.     

Morphinan alkaloids in Papaver bracteatum: Biosynthesis and fate

The known metabolic pathway for hydrophenanthrene alkaloids in Papaver somniferum has been examined for occurrence in P. bracteatum, a species reported to contain thebaine but no codeine or morphine. 1,2-Dehydro-reticulinium-[3-¹⁴C] chloride and (±)-reticuline-[3-¹⁴C] were fed to P. bracteatum plants and both were incorporated, the former into reticuline and thebaine and the latter into thebaine, suggesting that thebaine biosynthesis is the same in the two species. Studies of the natural abundance of morphinan alkaloids in P. bracteatum and the results from feeding codeinone-[16-³H] and codeine-[16-³H] indicate that this species can reduce codeinone to codeine but can not perform either of the demethylations to produce codeinone or morphine. Fed thebaine-[16-³H] was substantially metabolized but not by pathways that involved demethylations to either oripavine or northebaine.     

Codeinone reductase isoforms with differential stability,efficiency and product selectivity in opium poppy

Codeinone reductase (COR) catalyzes the reversible NADPH‐dependent reduction of codeinone to codeine as the penultimate step of morphine biosynthesis in opium poppy (Papaver somniferum). It also irreversibly reduces neopinone, which forms by spontaneous isomerization in aqueous solution from codeinone, to neopine. In a parallel pathway involving 3‐O‐demethylated analogs, COR converts morphinone to morphine, and neomorphinone to neomorphine. Similar to neopine, the formation of neomorphine by COR is irreversible. Neopine is a minor substrate for codeine O‐demethylase (CODM), yielding morphine. In the plant, neopine levels are low and neomorphine has not been detected. Silencing of CODM leads to accumulation of upstream metabolites, such as codeine and thebaine, but does not result in a shift towards higher relative concentrations of neopine, suggesting a mechanism in the plant for limiting neopine production. In yeast (Saccharomyces cerevisiae) engineered to produce opiate alkaloids, the catalytic properties of COR lead to accumulation of neopine and neomorphine as major products. An isoform (COR‐B) was isolated from opium poppy chemotype Bea's Choice that showed higher catalytic activity than previously characterized CORs, and it yielded mostly neopine in vitro and in engineered yeast. Five catalytically distinct COR isoforms (COR1.1–1.4 and COR‐B) were used to determine sequence–function relationships that influence product selectivity. Biochemical characterization and site‐directed mutagenesis of native COR isoforms identified four residues (V25, K41, F129 and W279) that affected protein stability, reaction velocity, and product selectivity and output. Improvement of COR performance coupled with an ability to guide pathway flux is necessary to facilitate commercial production of opiate alkaloids in engineered microorganisms.     

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.     

The biosynthesis of papaverine proceeds via (S)-reticuline

Papaverine is one of the earliest opium alkaloids for which a biosynthetic hypothesis was developed on theoretical grounds. Norlaudanosoline (=tetrahydropapaveroline) was claimed as the immediate precursor alkaloid for a multitude of nitrogen containing plant metabolites. This tetrahydroxylated compound was proposed to be fully O-methylated. The resulting tetrahydropapaverine should then aromatize to papaverine. In view of experimental data, this pathway has to be revised. Precursor administration to 8-day-old seedlings of Papaver followed by direct examination of the metabolic fate of the stable-isotope-labeled precursors in the total plant extract, without further purification of the metabolites, led to elucidation of the papaverine pathway in vivo. The central and earliest benzylisoquinoline alkaloid is not the tetraoxygenated norlaudanosoline, but instead the trihydroxylated norcoclaurine that is further converted into (S)-reticuline, the established precursor for poppy alkaloids. The papaverine pathway is opened by the methylation of (S)-reticuline to generate (S)-laudanine. A second methylation at the 3′ position of laudanine leads to laudanosine, both known alkaloids from the opium poppy. Subsequent N-demethylation of laudanosine yields the known precursor of papaverine: tetrahydropapaverine. Inspection of the subsequent aromatization reaction established the presence of an intermediate, 1,2-dihydropapaverine, which has been characterized. The final step to papaverine is dehydrogenation of the 1,2-bond, yielding the target compound papaverine. We conclusively show herein that the previously claimed norreticuline does not play a role in the biosynthesis of papaverine.     

Subcellular localization of sanguinarine biosynthetic enzymes in cultured opium poppy cells

Benzylisoquinoline alkaloids are a large and structurally diverse group of natural plant products that includes many compounds with potent biological activities, including the antimicrobial agent sanguinarine. The putative subcellular localization of the sanguinarine pathway was determined using in-frame N-terminal fusions between cDNAs encoding nine consecutive biosynthetic enzymes and the gene encoding the green fluorescent protein (GFP). Expression constructs were introduced into cultured opium poppy cells by particle bombardment, and the localization of fusion proteins was visualized using epifluorescence microscopy. GFP fusions with two O-methyltransferases and two N-methyltransferases in the sanguinarine pathway all produced non-targeted fluorescence in the cytosol and nucleus. Interspersed between these soluble proteins are five membrane-bound cytochromes P450. Corresponding cDNAs are available for three P450s, all of which produced fluorescence when fused to GFP in association with the endoplasmic reticulum (ER). Two enzymes with suggested or known N-terminal signal peptides were initially associated with the ER, but were subsequently transported to the central vacuole suggesting their occurrence in the ER lumen. The alternating localization of these biosynthetic enzymes to three subcellular compartments indicates extensive trafficking of pathway intermediates across the endomembranes and suggests a key role for compartmentalization in the regulation of sanguinarine metabolism.     

Molecular genetic diversity and association mapping of morphine content and agronomic traits in Turkish opium poppy (<Emphasis Type="Italic">Papaver somniferum</Emphasis>) germplasm

As the sole plant source of many potent alkaloids, opium poppy (Papaver somniferum L.) is an important medicinal crop. Nevertheless, few studies have characterized opium poppy germplasm with crop-specific molecular markers. Because Turkey is a diversity center for opium poppy, Turkish germplasm is a valuable genetic resource for association mapping studies aimed at identifying QTLs controlling morphine content and agronomic traits. In this study, the morphological diversity and molecular diversity of 103 Turkish opium poppy landraces and 15 cultivars were analyzed. Potentially useful morphological variation was observed for morphine content, plant height, and capsule index. However, the landraces exhibited limited breeding potential for stigma number, and seed and straw yields. Both morphological and molecular analyses showed distinct clustering of cultivars and landraces. In addition, a total of 164 SSR and 367 AFLP polymorphic loci were applied to an opium poppy association mapping panel composed of 95 opium poppy landraces which were grown for two seasons. One SSR and three AFLP loci were found to be significantly associated with morphine content (P < 0.01 and LD value (r ²) = 0.10–0.32), and six SSR and 14 AFLP loci were significantly associated with five agronomic traits (plant height, stigma number, capsule index, and seed and straw yields) (P < 0.01 and LD value (r ²) = 0.08–0.35). This is the first report of association mapping in this crop. The identified markers provide initial information for marker-assisted selection of important traits in opium poppy breeding.     

Cloning and characterization of canadine synthase involved in noscapine biosynthesis in opium poppy

Noscapine biosynthesis in opium poppy is thought to occur via N-methylcanadine, which would be produced through 9-O-methylation of (S)-scoulerine, methylenedioxy bridge formation on (S)-tetrahydrocolumbamine, and N-methylation of (S)-canadine. Only scoulerine 9-O-methyltransferase has been functionally characterized. We report the isolation and characterization of a cytochrome P450 (CYP719A21) from opium poppy that converts (S)-tetrahydrocolumbamine to (S)-canadine. Recombinant CYP719A21 displayed strict substrate specificity and high affinity (K_m = 4.63 ± 0.71 μM) for (S)-tetrahydrocolumbamine. Virus-induced gene silencing of CYP719A21 caused a significant increase in (S)-tetrahydrocolumbamine accumulation and a corresponding decrease in the levels of putative downstream intermediates and noscapine in opium poppy plants.     

Gene actions for yield and its attributes and their implications in the inheritance pattern over three generations in opium poppy (<Emphasis Type="Italic">Papaver somniferum</Emphasis> L.)

The gene actions for yield and its attributes and their inheritance pattern based on five parameter model have been explored in four single crosses (NBIHT-5 × NBIHT-6, NBIHT-5 × NBMHT-1, NBMHT-1 × NBIHT-6 and NBMHT-2 × NBMHT-1) obtained using thebaine rich pure lines of opium poppy (Papaver somniferum L.) for three consecutive generations. All the traits showed nonallelic mode of interaction, however, dominance effect (h) was more pronounced for all the traits except thebaine and papaverine. The dominance × dominance (l) effects were predominant over additive × additive (i) for all traits in all the four crosses except for papaverine. The seed and opium yield, and its contributing traits inherited quantitatively. The fixable gene effects (d) and (i) were lower in magnitude than nonfixable (h) and (l) gene effects. The estimates of heterosis were also higher in comparison to the respective parents which suggested preponderance of dominance gene action for controlling most of the traits. The phenotypic coefficient of variation was marginally higher than those of genotypic coefficient of variation for all the traits. The traits thebaine, narcotine, morphine and opium yield had high heritability coupled with high genetic advance. The leaf number, branches per plant and stem diameter showed positive correlation with opium and seed yields. The selection of plants having large number of leaves, branches and capsules with bigger size would be advantageous to enhance the yield potential.     

Cytochromes P450 from Papilio polyxenes: Adaptations to host plant allelochemicals

1. Papilio polyxenes, a caterpillar which feeds on xanthotoxin-containing plants, has cytochromes P450 that are six- to 100-fold less sensitive to the suicide substrate inhibitor, xanthotoxin, than cytochromes P450 from Manduca sexta, which does not survive on xanthotoxin-containing plants.2. Xanthotoxin is a suicide substrate inhibitor of O-demethylation of p-nitroanisole by M. sexta microsomes but a reversible inhibitor of O-demethylation by P. polyxenes microsomes.3. Aldrin epoxidation is irreversibly inhibited by xanthotoxin in both species.4. Patterns of cross inhibition demonstrate that O-demethylase and aldrin epoxidase from both species and the P. polyxenes xanthotoxin-metabolizing cytochrome P450 are distinct enzymes.     

Papaver bracteatum,potential commercial source of codeine

Papaver bracteatum, native to Iran and southern Russia, has been grown successfully in many countries. Research in the northwest United States has confirmed the potential for its commercial production as a source of the alkaloid thebaine. Potential for the chemical conversion of thebaine into codeine, one of man’s most widely used alkaloidal medicinal agents, is reviewed. Economic and social advantages of growing this species over opium poppy (Papaver somniferum) are discussed. The value of the seed oil for cooking and industrial use is considered.     

Mammalian Cytochrome P450 Enzymes Catalyze the Phenol-coupling Step in Endogenous Morphine Biosynthesis

A cytochrome P450 (P450) enzyme in porcine liver that catalyzed the phenol-coupling reaction of the substrate (R)-reticuline to salutaridine was previously purified to homogeneity (Amann, T., Roos, P. H., Huh, H., and Zenk, M. H. (1995) Heterocycles 40, 425–440). This reaction was found to be catalyzed by human P450s 2D6 and 3A4 in the presence of (R)-reticuline and NADPH to yield not a single product, but rather (−)-isoboldine, (−)-corytuberine, (+)-pallidine, and salutaridine, the para-ortho coupled established precursor of morphine in the poppy plant and most likely also in mammals. (S)-Reticuline, a substrate of both P450 enzymes, yielded the phenol-coupled alkaloids (+)-isoboldine, (+)-corytuberine, (−)-pallidine, and sinoacutine; none of these serve as a morphine precursor. Catalytic efficiencies were similar for P450 2D6 and P450 3A4 in the presence of cytochrome b₅ with (R)-reticuline as substrate. The mechanism of phenol coupling is not yet established; however, we favor a single cycle of iron oxidation to yield salutaridine and the three other alkaloids from (R)-reticuline. The total yield of salutaridine formed can supply the 10 nm concentration of morphine found in human neuroblastoma cell cultures and in brain tissues of mice.Cytochrome P450 (P450)² enzymes catalyze the most versatile chemical reactions in nature (1). There is, however, a discrepancy between the plant and the animal kingdoms with regard to the sheer number of these biocatalysts. Whereas in a single model plant, Arabidopsis thaliana, there are to date 273 P450 proteins, in the human genome, only 57 of these proteins are present. Whereas plants and animals share a multitude of highly regio- and stereospecific O-demethylation reactions, more complex reactions such as phenol coupling are much more abundant in plants than in animals, especially in the alkaloid field (2–11). The proposal of Barton and Cohen (12) correlated the structure of specific plant alkaloids in terms of this reaction mechanism and gave mechanistic proposals of how these phenol-coupled products may possibly be biosynthesized in nature. The oxidation of phenols by one-electron transfer affords radicals, which, by radical pairing, form new C-C or C-O bonds either by intra- or intermolecular coupling. The first two examples that unequivocally demonstrated the formation of C-C and C-O bonds in a stereo- and regioselective manner in plant metabolism are catalyzed by specific P450-linked microsomal-bound plant enzymes (13). One of these enzymes was salutaridine synthase from Papaver somniferum (opium poppy) (14). This synthase catalyzes the intramolecular formation of the critical C12-C13 carbon bridge and is a key enzyme in morphine biosynthesis.The groups of Goldstein (15) and Spector (16) have published a number of reports over the past 25 years claiming that mammals are capable of synthesizing de novo traces of endogenous morphine. However, no convincing experimental data have been presented regarding the enzymes. Phenol-coupling reactions in mammals are extremely rare, and the only example described thus far is the formation of thyroxine, by radical pairing, in humans. If the key step of morphine synthesis, the formation of phenol-coupled salutaridine from (R)-reticuline, occurs in mammals then in analogy to plants, a P450 enzyme must be present (in mammals) to catalyze this reaction. In 1987, the first experiments were conducted in an attempt to discover the reaction by supplying uniformly labeled racemic [³H]reticuline in the presence of rat microsomes and NADPH to examine whether [³H]salutaridine can be formed under these conditions (15). A radioactive compound was formed in 1% yield and assumed to be the phenol-coupled product salutaridine. We later repeated this experiment using (R)-[N-¹⁴CH₃]reticuline and NADPH-fortified microsomes from pig, rat, cow, and sheep. We observed the formation of [N-¹⁴CH₃]salutaridine with the correct stereochemistry at carbon 9 (17). The enzyme from porcine liver was subsequently purified to homogeneity and the reaction product was characterized by mass spectrometry and physical parameters to be a product of a P450 enzyme, which we provisionally named “salutaridine synthase” (18). The aim of this report is the identification of the homogenous porcine P450 enzyme, its equivalent in humans, and the mechanism of the phenol-coupling reaction in the formation of precursors of morphine.