Lupinine from

Schdpf and Thoma found that lupininic acid yielded a methyl ester (b.p. 120-2°/10 mm.) which had [aj — 19-4° to 5-8° in different batches. The f-ester furnished a gummy picrate, [a]J, ° — 41-8°, and on hydrolysis by hydrochloric acid gave a crystalline lupininic acid hydrochloride, m.p. 275°, — 13T°, identical with that described by Willstatter and Fourneau, whilst the d-ester, or ester of f-rotation below — 19-4°, furnished a crystalline picrate, m.p. 185°, [a]j, -f- 61-8°, from which pure d-epi-ester,-b.p. 126°/11 mm., [aJi, 54-8°, was prepared, this in turn yielding amorphous d-lupininie acid hydrochloride. The f-ester is convertible into ... 

Although lupinine is thus a comparatively simple alkaloid its detailed chemistry has been difficult to unravel owing (a) to the presence in its molecule of two asymmetric carbon atoms as asterisked in (XI), and (6) the possibility of cis-trans isomerism in certain of its proximate (ieriva-tives. Winterfeld and Holschneider have pointed out that a further complexity arises from the presence in natural Z-lupinine of a structural isomeride, aZZolupinine for which formula (XII) is suggested. They also quote Kreig s observation that by the action of sodium on a benzene solution of Z-lupinine (m.p. 68-9° [ajo — 23-52°), the latter is converted... 

The nature of the base, CmHijN, varies. When produced from pure Mupinine, m.p. 68-9°, it furnishes on oxidation only 3-methylpyridine-2-carboxylic acid (XV) and pyridine-2 3-dicarboxylic acid. If, however, lupinine, m.p. 63-3°, is used, the resulting pyridine base on oxidation furnishes in addition 2-n-butylpyridine-6-carboxylic acid (XVI) and 6-methylpyridine-2-carboxylic acid (XVII). The conclusion is drawn that lupinine, m.p. 63-3°, is a mixture of 1-lupinine (XI) with aZlolupinine (XII), each of these components furnishing its own lupinane (XIII and XIV), and that these two lupinanes contribute to the final degradation product, the tertiary pyridine base, CioHuN, the two isomerides 2-w-Ijutyl-3-inethylpyridine (XVIII) and 2-w-butyl-6-raethylpyridine (XIX) respectively. These interrelationships are shown by the following scheme —... 

The intramolecular Pummerer reaction has been applied to the synthesis of simple quinolizidine alkaloids like lupinine <2000JOC2368>, and also to arenoquinolizine alkaloids. Thus, the 2-(2-piperidyl)indole 284 was converted to indolo[2,3- ]quinolizidine 287 following a protocol that has as the key step the regioselective cyclization onto the indole 3-position of a thionium ion generated by Pummerer reaction from the appropriately substituted compound... 

The synthesis pathway of quinolizidine alkaloids is based on lysine conversion by enzymatic activity to cadaverine in exactly the same way as in the case of piperidine alkaloids. Certainly, in the relatively rich literature which attempts to explain quinolizidine alkaloid synthesis °, there are different experimental variants of this conversion. According to new experimental data, the conversion is achieved by coenzyme PLP (pyridoxal phosphate) activity, when the lysine is CO2 reduced. From cadeverine, via the activity of the diamine oxidase, Schiff base formation and four minor reactions (Aldol-type reaction, hydrolysis of imine to aldehyde/amine, oxidative reaction and again Schiff base formation), the pathway is divided into two directions. The subway synthesizes (—)-lupinine by two reductive steps, and the main synthesis stream goes via the Schiff base formation and coupling to the compound substrate, from which again the synthetic pathway divides to form (+)-lupanine synthesis and (—)-sparteine synthesis. From (—)-sparteine, the route by conversion to (+)-cytisine synthesis is open (Figure 51). Cytisine is an alkaloid with the pyridone nucleus. 

Alkaloids 36-41 were isolated from Lupinus luteus L. seedlings. They are considered to be lupinine esters with 4-hydroxycinnamic acids (94-100). The structures of these new alkaloids were elucidated on the basis of H NMR, MS, and chemical and enzymatic transformations. All these alkaloids were obtained from lupinine and hydroxycinnamic acid by two enzymatic systems (96-97) ligase catalyzed formation of the CoA-thioester, and transferase catalyzed lupinine ester formation from the CoA-thioester. 

Sophorine was isolated from Sophora alopecuroides (26). The nature of MS decay showed that sophorine is a quinolizidine alkaloid of the lupinine type. The IR spectrum suggests the presence of a franj-quinolizidine moiety (2675-2945 cm ) and an — NH—CO— group (1605 and 1683 cm ). On the basis of chemical shift analysis and signal multiplicity of H- and C-NMR spectra as well as biosynthetic considerations, structure 59 was proposed for sophorine. 

Nakai 124-126). UV and IR spectra of 78 and 81-83 are characteristic of lupinine alkaloids of the cytisine series containing an a-pyridine ring. MS fragmentation patterns are similar to those of cytisine alkaloids. The structures of these alkaloids were confirmed by synthesis from cytisine by reaction with HCOOH (81), (CHjCO) (78), C2H5Br (82), or CH2=CH—COCH3 (83). 

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... 

Lupinine Group.—Previous investigation of Cadia purpurea (cf. Vol. 7) resulted in the isolation of 13-hydroxylupanine (1) and its derivatives and cadiamine, Ci5H26N203, containing two hydroxy-groups. Structure (4) for the latter alkaloid has now been proposed.5 Esters (5) and (6) have also been obtained from the same... 

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