Epilupinine

Sodium borohydride reduction of 4-substituted isoquinolinium salts led to vinylogous cyanamides, ureas, and urethanes, as well as the corresponding tetrahydroquinolines (640). Hydrogenation of /8-acylpyridinium salts (641) to vinylogous ureas was exploited in syntheses of alkaloids (642), leading, for instance, to lupinine, epilupinine, and corynantheidine (643, 644). Similarly, syntheses of dasycarpidone and epidasycarpidone were achieved (645) through isomerization of an a,/0-unsaturated 2-acylindole and cyclization of the resultant enamine. 

The synthetic utility of radical cyclization was used as the key step in a four-step synthesis of the natural product (d,0-epilupinine (134b, a quinolizidine alkaloid) (75CB1043) from methyl nicotinate (146). Thus, l-(4-bromobutyl)-3-methoxycarbonyl-l,4,5,6-tetrahydropyridine (140), obtained from methyl nicotinate (146), was cyclized to 141 (43%), which on reduction with LiAlH4 in THF provided 134b in 95% yield (89T5269). 

Quinolizidine synthesis via intramolecular immonium ion based Diels-Alder reactions total synthesis of ( )-lupinine, ( )-epilupinine, ( )-criptopleurine and ( )-julandine [97]... 

The reductive coupling of of dienes containing amine groups in the backbones allows for the production of alkaloid skeletons in relatively few steps [36,46,47]. Epilupinine 80 was formed in 51% yield after oxidation by treatment of the tertiary amine 81 with PhMeSiEh in the presence of catalytic 70 [46]. Notably, none of the trans isomer was observed in the product mixture (Eq. 11). The Cp fuMcTIIF was found to catalyze cyclization of unsubstituted allyl amine 82 to provide 83. This reaction proceeded in shorter time and with increased yield relative to the same reaction with 70 (Eq. 12) [47]. Substitution of either alkene prevented cyclization, possibly due to competitive intramolecular stabilization of the metal by nitrogen preventing coordination of the substituted olefin, and resulted in hydrosilylation of the less substituted olefin. 

The key step in the total synthesis of (—)-epilupinine 253 involved the ring expansion of a proline-derived spirocyclic ammonium ylide to give 252 through a [1,2] Stevens rearrangement, as shown in Scheme 51 <1997T16565>. 

Another useful route to alkaloids involves the electrochemical oxidation of lactams (145) bearing functionality on nitrogen that can be used to intramolec-ularly capture an intermediate acyl im-minium ion (146). The concept is portrayed in Scheme 33 and is highlighted by the synthesis of alkaloids lupinine (150) and epilupinine (151) shown in Scheme 34 [60]. Thus, the electrooxidation of lactam (147) provided a 71% yield of ether (148). Subsequent treatment with titanium tetrachloride affected cyclization and afforded the [4.4.0] bicyclic adduct (149). Krapcho decarbomethoxylation followed by hydride reduction of both the... 

This methodology was applied to a concise synthesis of the alkaloid epilupinine (Scheme 18.10) [27]. N-alkylation of proline benzyl ester with bromo diazoketone 25 gave substrate 26. Treatment with either Rh2(OAc)4 or various copper-based catalysts... 

Lupinus luteus L., Lupinus hispanicus L., Lupinus hirsutus L. They have also been found in Anabasis aphyla. In absolute configuration, lupinine is in its (—)-form, which is non-stable thermally, and is easily epimerized to epilupinine, which is a stable (+)- form of lupinine . The melting point of (—)-lupinine is 70-71 °C, of mixed (+ and —)-lupinine 63-64°C, and of (+)-lupinine (synthetic)... 

C. Lupinine and epilupinine contain esters, which have been found in... 

Lupinine (2) is easily epimerized to epilupinine (33), a compound occurring in nature and also formed by synthesis (82-87). The synthesis of optically active natural lupinine and epilupinine was accomplished in 1967 (S5). Optically active... 

Alkaloids 42-47 were isolated from the leaves and seeds of Lupinus cosentinii Guss. They are considered to be epilupinine esters with various organic acids. The structure of the new alkaloids was established by IR, H NMR, MS, and investigation of hydrolysis products. 

Analogous reactions involving the more reactive iminium ions have also been observed. For example, a lupinine synthesis involved (203) as a reactive intermediate (60JA502). The decarboxylation of. the diacid was relatively nonstereospecific giving, after reduction, a mixture of ( )-lupinine and ( )-epilupinine. 

The cyclic ammonium ylide/[l,2]-shift approach has been successfully applied by West and Naidu to a key step in the total synthesis of (—)-epilupinine, one of the biologically active lupin alkaloids. Cu(acac)2-catalyzed diazo decomposition of enantiomeric pure diazoketone 160 in refluxing toluene generates a spiro ammonium ylide 161 and 162, which then undergoes [l,2]-shift to give rise to a quinolizidine skeleton as a mixture of diastereomers (95 5) (Scheme Major diastereomer 164 has enantiomeric purity of 75% ee. The partial retention of stereo-... 

Yttrium-catalyzed diene cyclization/hydrosilylation was applied to the synthesis of aliphatic nitrogen heterocycles such as the indolizidine alkaloid ( )-epilupinine. l-Allyl-2-vinylpiperidine 30 was synthesized in four steps in 59% overall yield from commercially available ( )-2-piperidinemethanol (Scheme 10). Treatment of 30 with phenylsilane and a catalytic amount of Gp 2YGH3(THF) gave silylated quinolizidine derivative 31 in 84% yield, resulting from selective hydrometallation of the A-allyl G=G bond in preference to the exocyclic vinylic G=G bond. Oxidation of the crude reaction mixture with tert-huVf hydrogen peroxide and potassium hydride gave (i)-epilupinine in 51-62% yield from 30 (Scheme 10). 

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