Synthesis quinolizidine

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

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. 

A base-catalyzed intramolecular nucleophilic substitution reaction on isoquinoline Reissert compounds (222) is the basis of a benzo[a]quinolizidine synthesis developed by Popp et al. (Scheme 42) <72JHC541>. 

Figure 1 Types of precursors for quinolizidine synthesis through formation of two new bonds.

Intramolecular tandem Michael addition-amide formation in the intermediate (291) afforded an epilupinine precursor (Scheme 60) <89H(29)1209>. Another quinolizidine synthesis forming two a bonds in its key step is the reductive double alkylation of azido epoxides with an (o leaving group (292). This strategy has been applied to the synthesis of ring-expanded analogues of indolizidine alkaloids (e.g. (293)) from D-arabinose (Scheme 61) <93TL822l>. 

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). 

An interesting synthesis of quinolizidines was achieved using a vinylogous variation of the Bischler-Napieralski reaction. Angelastro and coworkers reported that treatment of amide 26 with PPSE (polyphosphoric acid trimethylsilyl ester) followed by reductive... 

The intramolecular cyclization of l-(4-bromobutyl)-3-methoxycarbonyl-l,4,5, 6-tetrahydropyridine (140) and l-(3-bromopropyl)-3-methoxycarbonyl-l,4,5,6-tetrahydropyridine (143) (89T5269) resulted in the synthesis of quinolizidine ring system 141 and indolizidine ring system 144 in 43% and 72% yields along with the reduced tetrahydropyridines 142 and 145 in 21% and 8% yields, respectively. All the cyclized products appeared to be (ran.s-fused indolizidines or quinolizidines. The (ran.s -fused simple indolizidines are known to be some 2.4 kcal mol more stable than the d.s-fused isomers (68TL6191). In the and-isomer the methoxycarbonyl substituent occupies an equatorial position. 

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). 

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 final stages of the synthesis of (—)-A-58365B, a Streptomyces metabolite that inhibits the angiotensin-converting enzyme, involve several reactions at substituents attached to ring carbon atoms of a quinolizidine system. Thus, ozonolysis of the exocyclic methylene side chain of compound 107, followed by base-induced elimination and carboxyl deprotection, gave 108 (Scheme 12) <1999JOC1447>. 

Activation of a primary alcohol 174 by in situ mesylation and nucleophilic attack of a pyridine nitrogen atom was used in the last steps of a synthesis of cyclohexa[tf]quinolizidines 176. These compounds were obtained by direct NaBH4 reduction of intermediate pyridinium salts 175, and were proposed as tricyclic models containing the ABC-part of 8-azasteroids (Scheme 30) <1999T9269>. 

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>. 

A similar procedure was applied to the synthesis of quinazolidine 189 from precursor 188 in the total synthesis of the natural product known as ( )-quinolizidine 2071 190, an alkaloid isolated from the skin of the Madagascar mantelline frog Mantella baroni, that shows an exceptional axial stereochemistry for the ethyl group at C-l. Quinolizidine 189 was transformed into 190 by oxidation and two consecutive Wittig methylenations (Scheme 34) <1999CC2281>. 

The Bischler-Napieralski reaction is one of the traditional methods for isoquinoline synthesis, and has been applied to the preparation of fused quinolizidine systems. One simple example is the transformation of compound 246 into a 9 1 mixture of diastereomers 247 and 248 by treatment with phosphorus oxychloride followed by sodium borohydride reduction of a nonisolated iminium salt resulting from the cyclization (Scheme 49) <2000BMC2113>. 

The strategy employed in studies aiming at the synthesis of the spiro segment of halichlorine (see also Section 12.01.11.4) involved a ring expansion in indolizidine 264. The double bond of this compound was cleaved by ozonolysis yielding compound 265, which was cyclized to quinolizidine derivative 266 in the presence of base (Scheme 56) <2004TL2879>. 

A route for the asymmetric synthesis of benzo[3]quinolizidine derivative 273 was planned, having as the key step a Dieckman cyclization of a tetrahydroisoquinoline bis-methyl ester derivative 272, prepared from (.S )-phcnylalaninc in a multistep sequence. This cyclization was achieved by treatment of 272 with lithium diisopropylamide (LDA) as a base, and was followed by hydrolysis and decarboxylation to 273 (Scheme 58). Racemization could not be completely suppressed, even though many different reaction conditions were explored <1999JPI3623>. 

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... 

In a formal synthesis of quinolizidine 233A 296, the 2,6-m-disubstituted piperidine 292, as a mixture of dia-stereomers, was transformed into 293 by N-acylation with but-3-enoyl chloride. An RCM afforded 294, which was transformed into 295 by hydrogenation of the double bonds and hydride reduction of the lactam, thereby completing a formal synthesis <2000JOC8908> of quinolizidine 233A 296 (Scheme 65) <2004JA4100>. 

The stereoselective total synthesis of (+)-epiquinamide 301 has been achieved starting from the amino acid L-allysine ethylene acetal, which was converted into piperidine 298 by standard protocols. Allylation of 297 via an. V-acyliminium ion gave 298, which underwent RCM to provide 299 and the quinolizidine 300, with the wrong stereochemistry at the C-l stereocenter. This was corrected by mesylation of the alcohol, followed by Sn2 reaction with sodium azide to give 301, which, upon saponification of the methyl ester and decarboxylation through the Barton procedure followed by reduction and N-acylation, gave the desired natural product (Scheme 66) <20050L4005>. 

Hetero-Diels-Alder reactions have been succesfully employed for the synthesis of arenoquinolizine systems. For example, as shown in Equation 10, treatment of tetrahydroquinoline 319 with Danishefsky s diene 320 in the presence of a Lewis acid gave the benzo[c]quinolizidine derivative 321 <2000JME3718>. 

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