Morphinan isoquinoline alkaloids

Strychnos usambarensis (Loganiaceae) [root] S. Am. Indian poison curare component Derived synthetically from morphine, a morphinan isoquinoline alkaloid from Papaver somniferum (opium poppy) (Papaveraceae) [aerial]... 

Somewhat more effective catalysts are obtained by replacing BINAP with TolBINAP, which is 2,2 -bis(di-p-tolylphosphino)-l,l -binaphthyl.4 The presently preferred catalysts are complexes of Ru(OCOCF3)2 with (R)- or (S)-TolBINAP, obtained by treatment of Ru(OAc)2TolBINAP with 2 equiv. of trifluoroacetic acid. Such catalysts promote hydrogenation of typical enamides in 98% ee and 98% yield. This reaction can be used to provide asymmetric synthesis of isoquinoline alkaloids as well as of morphinans used as substitutes for morphine. 

The role of reticuline as an intermediate in the biosynthesis of the mor-phinan alkaloids (Fig. 2.8) was demonstrated by the isolation both of (S)-and (f )-reticuline from the opium poppy. An excess of the (S)-reticuline over the (f )-isomer was found in opium (poppy latex) obtained from the mature plant, in contrast to the roughly equal amounts of these two isomers that occur in poppy seedlings. Both isomers were found to be incorporated into morphine, the major alkaloid isolated from opium, although incorporation of the (f )-isomer was slightly more efficient. (f )-Reticuline is firmly established in P. somniferum as the precursor of the morphinan-type alkaloids (Loefer and Zenk, 1990). (S)-Reticuline, however, is the central intermediate in isoquinoline alkaloid biosynthesis. It has been postulated that (R)-reticuline is formed from (S)-reticuline by isomerization. This inversion of configuration can be explained by the intermediate formation of the 1,2-dehydroreticulinium ion originating from (S)-reticuline, followed by stereospecific reduction to yield the (R) counterpart. The 1,2-dehydroreticulinium ion is efficiently incorporated into opium alkaloids and its role as a precursor of the morphinan-t)q)e alkaloids has been unequivocally established (De-Eknamkul and Zenk, 1990, 1992). 

Because benzylisoquinolines have been available synthetically (in racemic form) for decades, there is quite a bit of chemistry known regarding their use as key intermediates in the synthesis of a number of more complex isoquinoline alkaloids. The asymmetric synthesis of benzylisoquinolines has been used to complete total synthesis of representative members of several of these alkaloid classes. As shown in Figure 6, the protoberberine alkaloid norcoralydine, the aporphine alkaloid ocoteine, the isopavine alkaloid reframoline and the morphinan 0-methylflavinantine have been made available in optically active form for the first time (except by isolation or resolution) using this approach. 

The reaction of Ru-binap complexes applied to tetrahydroisoquinoline compounds that have an exocyclic enamide double bond produces 1-substituted tetrahydroisoqui-nolines nearly quantitatively and with optical yield close to 100%. This procedure served in industrial production of benzomorphans, morphinans, and various isoquinoline alkaloids ... 

Opitim contains 10-25% alkaloids, and the main constituent is morphine. Other than morphine, more than 25 alkaloids are known, and among them are other morphinan-type alkaloids (codeine and thebaine), benzyl-isoquinoline-type alkaloids (papaverine and noscapine), and protopine-type alkaloids (protopine). The biosynthetic precursor of all of these alkaloids is phenylalanine. 

Morphinan alkaloids are the pharmaceutically most important class of isoquinoline alkaloids. Codeine and morphine are found only in Papaver somniferwn and closely related species. Both alkaloids are derived from (R)-reticuline, the absolute stereochemistry of which corresponds with the configuration of morphinan alkaloids. Re-ticuline is therefore an important branch point in isoquinoline bio nthesis. However, either enantiomer of reticulme, when fed separately, is incorporated into morphinan alkaloids essentially to the same extent. The question therefore arises by which mechanism (R)-reticuline is formed within the plant. 

The biosynthesis of the various isoquinolines is reviewed in two chapters, one devoted solely to the morphinans and the other to the other skeletal types. Attempts to produce morphinan alkaloids by plant cell culture techniques has produced a flurry of activity in several laboratories throu out the world. Four chapters are concerned with plant cell culture techniques for the production of isoquinolines. A series of enzymes which catalyse specific steps in isoquinoline alkaloid biosynthesis have been isolated in recent years and the stage is now set for the isolation and characterization of the enzymes responsible for morphinan alkaloid biosynthesis. The utilization of these enzymes for biotechnological conversions is now envisaged. 

MAO was used in vivo and in vitro as a catalyst for the production of norlaudano-sine from dopamine (Fig. 16.7-14)[35]. Norlaudanosine is an important synthon for benzylisoquinoline alkaloids, providing the upper isoquinoline portion of the morphinan skeleton. In vitro and in vivo yields were in the range of 20 %. 

S)-(+)-reticuline (20) and orientaline (25). The alkaloids of the Papaveraceae and Fumariaceae can be subdivided into several constitutional types (Fig. 3), viz., simple isoquinolines, benzylisoquinolines, pavines, isopavines, cularines, proaporphines, aporphines, promorphinanes, morphinanes, protoberberines, retroprotoberberines, secoberbines, benzophenanthridines, protopines, phthali-deisoquinolines, secophthalideisoquinolines, indenobenzazepines, spirobenzyl-isoquinolines, and rhoeadines. 

Coutts IGC, Hamblin MR, Tinley EJ (1979) The enzymatic oxidation of phenolic tetrahydroiso-quinoline-1-carboxylic acids. J Chem Soc Perkin Trans 1 2744-2750 Davis VE, Cashaw JL, McMurtrey KD, Ruchirawat S, Nimit Y (1982) Metabolism of tetrahydro-isoquinolines and related alkaloids. In Bloom F, Barchas J, Sandler M, Usdin E (eds) Beta-carbolines and tetrahydroisoquinolines. Liss, New York, p 99 Furuya T, Nakano M, Yoshikawa T (1978) Biotransformation of (RS)-reticuline and morphinan alkaloids by cell cultures of Papaver somniferum. Phytochemistry 17 891-893 Gates M (1953) Conversion of codeinone to codeine. J Am Chem Soc 75 4340-4341 Graves JMH, Smith WK (1967) Transformation of pregnenolone and progesterone by cultured plant cells. Nature (London) 214 124 8-1249... 

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