Quinolizidines formation

The rare reports of quinolizidine formation by a nitrone cycloaddition strategy include the racemic total synthesis of lasubine II (58), one of a series of related alkaloid isolated from the leaves of Lagerstoemia subcostata Koehne (Scheme 1.14) (104). While these alkaloids were previously accessed by infennolecular nitrone cycloaddition reactions, this more recent report uses an intramolecular approach to form the desired piperidine ring. Thus, cycloaddition of nitrone 59 affords predominantly the desired bridged adduct 60 along with two related... 

Reactions of Enamine Salts with OrganometalUc Compounds Organolithium and organomagnesium compounds react with enamine salts to give amines substituted on the ix-carbon atoms. The treatment of. -dehydroquinolizidinium perchlorate (163) with alkylmagnesium halides gives 9-alkylated quinolizidines (164) (252,256). Formation of... 

The reaction of 2-(a-pyridyl)alkylmalonic acid with J -piperideine leading to formation of 3-((x-pyridyl)quinolizidine-l-carboxylic acid on decarboxylation, has been used by Van Tamelen and Foltz (316) for the syntheis of the alkaloid lupanine (Scheme 20). A very elegant synthesis of matrine has been accomplished by Bohlmann et al. (317). 

The utility of lOOC reactions in the synthesis of fused rings containing a bridgehead N atom such as pyrrolizidines, indolizidines, and quinolizidines which occur widely in a number of alkaloids has been demonstrated [64]. Substrates 242 a-d, that possess properly positioned aldoxime and alkene functions, were prepared from proline or pipecolinic acid 240 (Eq. 27). Esterification of 240 and introduction of unsaturation on N by AT-alkylation produced 241 which was followed by conversion of the carbethoxy function to an aldoxime 242. lOOC reaction of 242 led to stereoselective formation of various tricyclic systems 243. This versatile method thus allows attachment of various unsaturated side chains that can serve for generation of functionalized five- or six-membered (possibly even larger) rings. 

The Hg(ll) cation was used to activate the double bond in lactam 178, which was obtained by detosylation of 177 using the Parsons method. This strategy allowed the synthesis of quinolizidine derivative 179, which was obtained as a single /raar-diastereoisomer (Scheme 31). Besides its higher thermodynamic stability with respect to that of the m-isomer, formation of the trans-isomer must involve a lower activation energy since its intermediate precursor, in which the lone pair of electrons of nitrogen must attack from the back side of the mercuronium ion, is sterically less hindered than the precursor of the m-isomer <2003TL4653>. 

The antibacterial agent flumequine 280 was synthetized in optically active form by starting with resolution of the two enantiomers of a suitably substituted racemic tetrahydroquinoline through formation of the (lf )-3-bromocamphor-8-sulfonates. After N-alkylation of the (2K)-tetrahydroisoquinoline enantiomer 277 with diethyl ethoxymethylene-malonate to give 278, the quinolizidine system 279 was formed by acylation onto the peri-position. This compound was finally hydrolyzed to afford 280 (Scheme 60) <1999TA1079>. 

The application of the RCM reaction to the construction of nitrogen-containing ring systems, including quinolizidine derivatives, has been reviewed <1999EJ0959>. From that date, this strategy has become more and more common in quinolizidine synthesis, especially in cases where the cyclization takes place by formation of a bond 7 to the heteroatom. Some examples are given below. 

The nonsymmetrical quinolizidine 373 was obtained from the acyclic symmetrical precursor 372 by means of a reaction sequence comprising azide formation, intramolecular 1,3-dipolar cycloaddition, thermal triazoline fragmentation to a diazoalkane, and Michael addition individual steps, as shown in Scheme 85 <2005CC4661>. 

Lasubines I and II are alkaloids containing a 4-arylquinolizidine substructure that have been isolated from plants of the Lythraceae family and have attracted the attention of synthetic chemists for some time. While numerous racemic syntheses of these and related compounds have been reported, only a few enantioselective syntheses are known. Some examples of these syntheses are given below, and the strategies involved in these examples are summarized in Scheme 92. Three of these syntheses involve the creation of the quinolizidine system by formation of one bond at the a- or 7-positions, while the fourth approach is based on a ring transformation associated with a photochemical Beckmann rearrangement. 

Three syntheses of homopumiliotoxin alkaloids are compared below, and one more reaction leading to homo-pumiliotoxin-related compounds was mentioned in Section 12.01.9.3.7. The strategies involved for the ring-closure procedures leading to the quinolizidine system involved the formation of a- or 7-bonds from piperidine precursors and are summarized in Scheme 97. 

Quinolizidine alkaloids (QA) are thought to be typical natural products of many Leguminosae (1-3) but a few isolated occurrences have been reported also in unrelated families, e.g. Chenopodiaceae ( 1 ), Berberidaceae ( ), Papaveraceae ( ), Scrophulariaceae ( ), Santalaceae ( ), Solanaceae ( ), and Ranunculaceae (J ). These observations could indicate that the genes for QA biosynthesis are probably not restricted to the Leguminosae but are widely distributed in the plant kingdom however, they are only rarely expressed in the other families. We could support this belief by recent experiments using plant cell suspension cultures. A short-term and transientQA formation could be detected after induction even in "QA-free" species, such as Daucus, Spinacia, Conium, and Symphytum (6). 

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. 

The preparation of fused nitrogen heterocycles such as pyrrolizidines, indolizidines, quinolizidines, pyrrolidinoazocines and piperidinoazocines by the RCM of appropriate dienes (equation 38), is another case where presence of a ring assists the RCM reaction. However, when n = 7 (with x = 1), the C=C bonds, separated by 11 single bonds, are too far apart for RCM to occur. Applications of this general strategy are in prospect for the formation of fused nitrogen heterocyclic systems in problems of alkaloid synthesis240. 

Irradiation of the l,2,3>4-tetrahydropyridine 222 results in formation of quinolizidine 223 in high yield, as a single diastereoisomer (Equation 20) <20020L1611>. Photoirradiation of N-tethered allenes has also been shown to result in a good yield of the corresponding [2+2] cycloadduct <1997T16253>. 

The quinolizidine system in monomeric C15 alkaloids in some cases is susceptible to inversion of the ring junction, which is accompanied by inversion of the relative configuration of C-7. Protonation of the nitrogen atom, quaternization, or V-oxide formation are the conditions which cause such transformations. 

The continuing interest in the synthesis of macrocylic alkaloids has been directed this year to the preparation of the cw-quinolizidine group. It is apparent from the work of Hanaoka et al.29 that alkaline conditions for the Mannich condensation of isopelletierine (41) with aryl aldehydes, cf. (39), favour the formation of cis-quinolizidinones. The synthesis of the biphenyl ether alkaloid vertaline (48) was carried out in this way (Vol. 5), and has now been described in full.30... 

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