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Catharanthus

Until separation techniques such as chromatography (28,29) and counter-current extraction had advanced sufficientiy to be of widespread use, the principal alkaloids were isolated from plant extracts and the minor constituents were either discarded or remained uninvestigated. With the advent of, first, column, then preparative thin layer, and now high pressure Hquid chromatography, even very low concentrations of materials of physiological significance can be obtained in commercial quantities. The alkaloid leurocristine (vincristine, 22, R = CHO), one of the more than 90 alkaloids found in Catharanthus roseus G. Don, from which it is isolated and then used in chemotherapy, occurs in concentrations of about 2 mg/100 kg of plant material. [Pg.533]

R = CHO) and vincaleukoblastine (vinblastine (22), R = CH3), along with nearly one hundred other compounds, from Catharanthus roseus (V.) G. Don,... [Pg.551]

W. I. Taylor and N. R. Famswortli, eds., The Catharanthus Alkaloids, Botanj, Chemist, Pharmacology and Clinical Uses, Marcel Dekker, New York, 1973 W. I. Taylor and N. R. Famswortli, eds.. The Uinca Alkaloids, Botanj, Chemistry and Pharmacology, Marcel Dekker, New York, 1973. [Pg.559]

Vinca alkaloids are derived from the Madagascar periwinkle plant, Catharanthus roseus. The main alkaloids are vincristine, vinblastine and vindesine. Vinca alkaloids are cell-cycle-specific agents and block cells in mitosis. This cellular activity is due to their ability to bind specifically to tubulin and to block the ability of the protein to polymerize into microtubules. This prevents spindle formation in mitosing cells and causes arrest at metaphase. Vinca alkaloids also inhibit other cellular activities that involve microtubules, such as leukocyte phagocytosis and chemotaxis as well as axonal transport in neurons. Side effects of the vinca alkaloids such as their neurotoxicity may be due to disruption of these functions. [Pg.1283]

Iridoids and their related alkaloids are widely spread in angiosperms and are found in 13 orders and 70 families including Rutales, Buxales, Hamamelidales, Comales, Loasales, Gentianales, etc. Important iridoids are loganin, found in high amounts in Strychnos nux-vomica and in Catharanthus roseus, and secologanin found especially in Caprifoliaceae. [Pg.117]

Trinitrotoluene (TNT) is reduced by the aquatic plant Myriophyllum spicatum to ami-nodinitrotoluenes (Pavlostathis et al. 1998) and, in axenic root cultures of Catharanthus roseus, the initial metabolites 2-amino-4,6-dinitrotoluene and 4-amino-2,6-dintrotoluene... [Pg.98]

The two alkaloids vinblastine and vincristine found in Catharanthus roseus have been recent targets of total synthesis because of their potency in cancer chemotherapy. The reduced tree diagram for the Fukuyama plan to vincristine is shown in Figure 4.66. There are three points of convergence, four branches leading to the target product and four tiers of reaction yields. [Pg.169]

Catharanthus roseus) [9]. Maytansine (3) is an ansa macrolyde isolated from Maytenus ovatus [10], and rhizoxin (4) is an antitumor macrolide isolated from the fungus Rhizopus chinensis [11]. Another very important tubulin interactive anti-cancer agent is colchicine (6), and this compound binds to a different binding site of tubulin but is also used in anti-cancer therapy. [Pg.17]

Salutaridinol 7-0-acetyltransferase catalyzes the conversion of the phenanthrene alkaloid salutaridinol to salutaridinol-7-Oacetate, the immediate precursor of thebaine along the morphine biosynthetic pathway in P. somniferum (Fig. 10.7).26 Acetyl CoA-dependent acetyltransferases have an important role in plant alkaloid metabolism. They are involved in the synthesis of monoterpenoid indole alkaloids in medicinal plant species such as Rauwolfia serpentina. In this plant, the enzyme vinorine synthase transfers an acetyl group from acetyl CoA to 16-epi-vellosimine to form vinorine. This acetyl transfer is accompanied by a concomitant skeletal rearrangement from the sarpagan- to the ajmalan-type (reviewed in2). An acetyl CoA-dependent acetyltransferase also participates in vindoline biosynthesis in Catharanthus roseus, the source of the chemotherapeutic dimeric indole alkaloid vinblastine (reviewed in2). Acetyl CoA deacetylvindoline 4-O-acetyltransferase catalyzes the last step in vindoline biosynthesis. A cDNA encoding acetyl CoA deacetylvindoline 4-0-acetyltransferase was recently successfully isolated.27... [Pg.173]

PFITZNER, U., ZENK, M.H., Immobilization of strictosidine synthase from Catharanthus cell cultures and preparative synthesis of strictosidine, Planta Med., 1982, 46,10-14. [Pg.176]

Recently, Cordell and collaborators (51) reported the discovery of (—)-16-epi-(Z)-isositsirikine (48) from the leaves of Catharanthus roseus (L.) G.Don and Rhazya stricta Decaisne, the first isositsirikine-type alkaloid with Z geometry in the C-20 ethylidene side chain. Moreover, they gave reliable structure assignments for (-)-( )-isositsirikine (46) and (—)-16-epi-( )-isositsirkine (47). [Pg.153]

Extensive biotransformation studies have been conducted with the As-pidosperma alkaloid vindoline, but much less work has been done with monomeric Iboga and dimeric alkaloids from this plant. The long-standing interest in this group of compounds stems from the clinical importance of the dimeric alkaloids vincristine and vinblastine, both of which have been used for more than 2 decades in the treatment of cancer. Few mammalian metabolites of dimeric Catharanthus alkaloids have been characterized. Thus the potential role of alkaloid metabolism in mechanism of action or dose-limiting toxicities remains unknown. The fact that little information existed about the metabolic fate of representative Aspidosperma and Iboga alkaloids and Vinca dimers prompted detailed microbial, mammalian enzymatic, and chemical studies with such compounds as vindoline, cleavamine, catharanthine, and their derivatives. Patterns of metabolism observed with the monomeric alkaloids would be expected to occur with the dimeric compounds. [Pg.366]

Leurosine (75) (Scheme 20) is the most abundant of the dimeric antitumor alkaloids isolated from Catharanthus roseus G. Don. Several species of Strep-tomyces produced a common metabolite of the alkaloid, and S. griseus (UI1158) was incubated with 400 mg of leurosine sulfate to obtain 28 mg of pure metabolite (180). The metabolite was identified as 76 primarily on the basis of its H-NMR spectrum. The mass spectrum indicated that the metabolite contained one oxygen atom more than 75. The H-NMR spectrum contained all of the aromatic proton signals of the vindoline portion of the molecule, and aromatic proton signals for the Iboga portion of the compound occurred as a doublet of doublets... [Pg.375]

Scheme 20. Structures of dimeric Catharanthus alkaloids and their microbial or enzymatic transformation products. Scheme 20. Structures of dimeric Catharanthus alkaloids and their microbial or enzymatic transformation products.
Another cultured cell line of Catharanthus roseus (EU4A), which does not produce detectable amounts of vinblastine and other bisindole alkaloids, was also examined for its ability to transform 78 (183). Cell-free extracts of the culture line were prepared, and the 35,000 X g supernatant solution was used. Incubations with 2r-tritioanhydiovinblastine yielded a mixture from which radioactive vinblastine (52) was isolated. The labeled vinblastine was reisolated after unlabeled carrier was added and rigorously purified by successive thin-layer chromatography, reversed-phase HPLC, and crystallization to constant specific activity. Boiled extracts could not produce labeled 52, thus supporting the involvement of enzymes in the conversion process. [Pg.377]

G. Sriram, D. B. Fulton, and J. V. Shanks, Flux quantification in central carbon metabolism of Catharanthus roseus hairy roots by 13c labeling and comprehensive bondomer balancing. Phytochemistry 68, 2243 2257 (2007). [Pg.246]

Cell cultures of Catharanthus roseus entrapped in calcium alginate have been employed by Takemoto and Achiwa to deracemize pyridyl alcohols such as 15 and 16 [17] (Scheme 8). [Pg.65]

Peebles CA, Gibson SI, Shanks JV, San KY. (2007) Characterization of an ethanol-inducible promoter system in Catharanthus roseus hairy roots. Biotechnol Prog 23 1258-1260. [Pg.648]

Rniz-May E, Galaz-Avalos RM, Loyola-Vargas VM. (2009) Differential secretion and accumulation of terpene indole alkaloids in hairy roots of Catharanthus roseus treated with methyl jasmonate. Mol Biotechnol 41 278-285. [Pg.649]


See other pages where Catharanthus is mentioned: [Pg.550]    [Pg.551]    [Pg.58]    [Pg.147]    [Pg.224]    [Pg.238]    [Pg.165]    [Pg.66]    [Pg.733]    [Pg.29]    [Pg.169]    [Pg.186]    [Pg.545]    [Pg.20]    [Pg.119]    [Pg.134]    [Pg.141]    [Pg.153]    [Pg.339]    [Pg.366]    [Pg.367]    [Pg.377]    [Pg.379]    [Pg.468]    [Pg.178]    [Pg.634]    [Pg.645]   
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Ajmalicine from Catharanthus roseus

Alkaloid from Vinca rosea (Catharanthus

Alkaloids biosynthesis in Catharanthus

Alkaloids from Catharanthus roseus

Analysis of Catharanthus Alkaloids

Bisindole alkaloids of Catharanthus

Bisindole alkaloids of Catharanthus C-20’ Position as a Functional Hot Spot

Capsaicin Catharanthus roseus

Catharanthus Alkaloids in Cell Culture

Catharanthus alkaloids

Catharanthus alkaloids Leukaemia

Catharanthus alkaloids Subject

Catharanthus alkaloids Vinblastine

Catharanthus alkaloids Vincristine

Catharanthus alkaloids Vindesine

Catharanthus alkaloids processes

Catharanthus bisindole alkaloids

Catharanthus lanceus

Catharanthus longifolius

Catharanthus ovalis

Catharanthus pusillus

Catharanthus rosea

Catharanthus roseus

Catharanthus roseus alkaloid production

Catharanthus roseus alkaloids

Catharanthus roseus biosynthesis

Catharanthus roseus brassinosteroids

Catharanthus roseus catharanthine from

Catharanthus roseus cells

Catharanthus roseus enzyme

Catharanthus roseus geraniol

Catharanthus roseus indole alkaloid biosynthesis

Catharanthus roseus leurosine

Catharanthus roseus leurosine from

Catharanthus roseus linalool

Catharanthus roseus metabolic engineering

Catharanthus roseus nerol

Catharanthus roseus vinblastine from

Catharanthus roseus vincristine from

Catharanthus roseus vindoline from

Catharanthus roseus, terpenoid indole

Catharanthus roseus, terpenoid indole alkaloids

Catharanthus roseus, terpenoid indole biosynthesis

Catharanthus roseus, vinca alkaloids from

Catharanthus trichophyllus

Crown gall cells of Catharanthus roseus

Leurocristine from Catharanthus roseus

Madagascar Periwinkle, Catharanthus

Monoterpenes Catharanthus

Naturally Occurring Bisindole Alkaloids from Catharanthus

Organism Catharanthus roseus

Periwinkle, Catharanthus

Tryptophan Catharanthus roseus

Vinca rosea (Catharanthus roseus

Vincristine from Catharanthus

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