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Lupinine biosynthesis

A -Piperideine (17) has been shown to be a precursor of quinolizidine alkaloids in whole plants (cf. Vol. 8, p. 3). However, neither it nor its self-condensation products could be detected as products in the enzymic reaction. [This conclusion is not completely unambiguous, albeit reasonably safe, because the products of the reaction of diamine oxidase, the first of which is (17), were simply compared with those of the alkaloid synthase reaction by g.l.c., and the products of the two reactions were found to be different].11 It seems likely at this stage that (17) is not normally implicated in quinolizidine biosynthesis but can be substituted for an enzyme-generated intermediate via its open form (32) (see Scheme 5). Since no intermediates earlier than (27) could be detected, it is suggested that biosynthesis in vitro and in vivo proceeds by a series of enzyme-linked intermediates (see Scheme 5), none of which is desorbed from the enzyme or enzyme-complex until (27) is liberated. However, in some plants, biosynthesis must stop with the liberation of a compound (31), having the lupinine skeleton... [Pg.6]

Alkaloid metabolism in lupine was proved by Wink and Hartmann to be associated with chloroplasts (34). A series of enzymes involved in the biosynthesis of lupine alkaloids were localized in chloroplasts isolated from leaves of Lupinus polyphylls and seedlings of L. albus by differential centrifugation. They proposed a pathway for the biosynthesis of lupanine via conversion of exogenous 17-oxosparteine to lupanine with intact chloroplasts. The biosynthetic pathway of lupinine was also studied by Wink and Hartmann (35). Two enzymes involved in the biosynthesis of alkaloids, namely, lysine decarboxylase and 17-oxosparteine synthetase, were found in the chloroplast stoma. The activities of the two enzymes were as low as one-thousandth that of diaminopimelate decarboxylase, an enzyme involved in the biosynthetic pathway from lysine to diaminopimelate. It was suggested that these differences are not caused by substrate availability (e,g., lysine concentration) as a critical factor in the synthesis of alkaloids. Feedback inhibition would play a major role in the regulation of amino acid biosynthesis but not in the control of alkaloid formation. [Pg.176]

The most common group of alkaloids possessing a quinolizidine nucleus is that of the lupine alkaloids which can simply be classified as bicyclic (lupinine/epilupinine type), tricyclic (cytisine type) or tetracyclic, (sparteine/lupanine or matrine type). Fig. (23). This grouping is made according to structure complexity and without considering biosynthesis, as the detailed biosynthetic pathways are still not completely understood. [Pg.258]

In vitro tissue and cell cultures of lupin plants are not appropriate systems for the study of biosynthesis of lupin alkaloids, because the production ability by in vitro culture is rather low, i.e., 10 2 to lO times compared with that of differentiated plants. The production of the alkaloids of lupinine- and sparteine-groups by cell culture have been reported by us [59] and by Wink s group [60]. We have also successfully produced matrine in green callus culture and in multiple shoots of Sophora flavescens [61]. The producibility of matrine was positively correlated with the chloroplast formation. This indicates that the formation of carbon skeleton of matrine-type alkaloids also likely takes place in chloroplasts in plant cells as postulated in that of sparteine-type alkaloids [62]. [Pg.534]

Quinolizidine alkaloid biosynthesis Cadaverine, (+)-P- coumaioylepilupinine/lupinine, (—)-13a-tigloyloxymuttflOTme/lupanine... [Pg.417]


See other pages where Lupinine biosynthesis is mentioned: [Pg.92]    [Pg.72]    [Pg.882]    [Pg.141]    [Pg.369]    [Pg.133]    [Pg.369]    [Pg.292]    [Pg.34]    [Pg.9]    [Pg.147]    [Pg.388]   


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Lupinine

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