thebaine and reticuline

Opiates such as morphine and codeine are mainly obtained by extraction from opium poppies. Fermentative opiate production in microbes has also been investigated, and complete biosynthesis of opiates from a simple carbon source has recently been accomplished in yeast. Here we demonstrate that Escherichia coli serves as an efficient, robust and flexible platform for total opiate synthesis. Thebaine, the most important raw material in opioid preparations, is produced by stepwise culture of four engineered strains at yields of 2.1 mg l(-1) from glycerol, corresponding to a 300-fold increase from recently developed yeast systems. This improvement is presumably due to strong activity of enzymes related to thebaine synthesis from (R)-reticuline in E. coli. Furthermore, by adding two genes to the thebaine production system, we demonstrate the biosynthesis of hydrocodone, a clinically important opioid. Improvements in opiate production in this E. coli system represent a major step towards the development of alternative opiate production systems.

Topics: Acetyltransferases; Analgesics, Opioid; Benzylisoquinolines; Codeine; Coptis; Escherichia coli; Fermentation; Glycerol; Hydrocodone; Methyltransferases; Morphine; Organisms, Genetically Modified; Oxidoreductases; Oxycodone; Papaver; Thebaine

Opioids are the primary drugs used in Western medicine for pain management and palliative care. Farming of opium poppies remains the sole source of these essential medicines, despite diverse market demands and uncertainty in crop yields due to weather, climate change, and pests. We engineered yeast to produce the selected opioid compounds thebaine and hydrocodone starting from sugar. All work was conducted in a laboratory that is permitted and secured for work with controlled substances. We combined enzyme discovery, enzyme engineering, and pathway and strain optimization to realize full opiate biosynthesis in yeast. The resulting opioid biosynthesis strains required the expression of 21 (thebaine) and 23 (hydrocodone) enzyme activities from plants, mammals, bacteria, and yeast itself. This is a proof of principle, and major hurdles remain before optimization and scale-up could be achieved. Open discussions of options for governing this technology are also needed in order to responsibly realize alternative supplies for these medically relevant compounds.

Topics: Animals; Benzylisoquinolines; Biosynthetic Pathways; Carbohydrate Metabolism; Codeine; Genetic Engineering; Hydrocodone; Morphinans; Papaver; Saccharomyces cerevisiae; Thebaine

The assumption that CYP2D1 is the corresponding rat cytochrome to human CYP2D6 has been revisited using recombinant proteins in direct enzyme assays. CYP2D1 and 2D2 were incubated with known CYP2D6 substrates, the three morphine precursors thebaine, codeine and (R)-reticuline. Mass spectrometric analysis showed that rat CYP2D2, not 2D1, catalyzed the 3-O-demethylation reaction of thebaine and codeine. In addition, CYP2D2 incubated with (R)-reticuline generated four products corytuberine, pallidine, salutaridine and isoboldine while rat CYP2D1 was completely inactive. This intramolecular phenol-coupling reaction follows the same mechanism as observed for CYP2D6. Michaelis-Menten kinetic parameters revealed high catalytic efficiencies for rat CYP2D2. These findings suggest a critical evaluation of other commonly accepted, however untested, CYP2D1 substrates.

Topics: Alcohol Oxidoreductases; Animals; Aryl Hydrocarbon Hydroxylases; Benzylisoquinolines; Codeine; Cytochrome P-450 CYP2D6; Cytochrome P450 Family 2; Humans; Kinetics; Mass Spectrometry; Microsomes, Liver; Morphinans; Morphine; Phenols; Rats; Rats, Wistar; Substrate Specificity; Thebaine

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.

Topics: Alkaloids; Benzylisoquinolines; Isoquinolines; Molecular Structure; Papaver; Papaverine; Seedlings; Stereoisomerism; Thebaine

Morphine is a plant (opium poppy)-derived alkaloid and one of the strongest known analgesic compounds. Studies from several laboratories have suggested that animal and human tissue or fluids contain trace amounts of morphine. Its origin in mammals has been believed to be of dietary origin. Here, we address the question of whether morphine is of endogenous origin or derived from exogenous sources. Benzylisoquinoline alkaloids present in human neuroblastoma cells (SH-SY5Y) and human pancreas carcinoma cells (DAN-G) were identified by GC/tandem MS (MS/MS) as norlaudanosoline (DAN-G), reticuline (DAN-G and SH-SY5Y), and morphine (10 nM, SH-SY5Y). The stereochemistry of reticuline was determined to be 1-(S). Growth of the SH-SY5Y cell line in the presence of (18)O(2) led to the [(18)O]-labeled morphine that had the molecular weight 4 mass units higher than if grown in (16)O(2), indicating the presence of two atoms of (18)O per molecule of morphine. Growth of DAN-G cells in an (18)O(2) atmosphere yielded norlaudanosoline and (S)-reticuline, both labeled at only two of the four oxygen atoms. This result clearly demonstrates that all three alkaloids are of biosynthetic origin and suggests that norlaudanosoline and (S)-reticuline are endogenous precursors of morphine. Feeding of [ring-(13)C(6)]-tyramine, [1-(13)C, N-(13)CH(3)]-(S)-reticuline and [N-CD(3)]-thebaine to the neuroblastoma cells led each to the position-specific labeling of morphine, as established by GC/MS/MS. Without doubt, human cells can produce the alkaloid morphine. The studies presented here serve as a platform for the exploration of the function of "endogenous morphine" in the neurosciences and immunosciences.

Topics: Alkaloids; Animals; Benzylisoquinolines; Cell Line; Humans; Mass Spectrometry; Morphine; Oxygen Isotopes; Rats; Stereoisomerism; Tetrahydropapaveroline; Thebaine; Tyrosine