Indolizidine products

On the other hand, when we investigated the enantiose-lective aza-[3- -3] annulation of pyrroUdine-based exocyclic vinylogous amides and urethanes 297, the similar chiral amine salts catalysts 299 or 300 still work very well at 40 mol% catalyst loading, afforded the indolizidines products 301 with up to 70% ee. Specially, this asymmetric aza-cycloaddition is an unexpected regiochemical reversal... 

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. 

Among the many recent applications to natural products, syntheses of pyrrolizidine and indolizidine alkaloids that take advantage of the 1,3-dipolar cycloaddition methodology have been reviewed [8]. The regio- and stereochemistry [9] as well as synthetic appHcations [10] of nitrile oxide cycloadditions have also been discussed. 

The product of the reaction in Entry 8 was used in the synthesis of the alkaloid pseudotropine. The proper stereochemical orientation of the hydroxy group is determined by the structure of the oxazoline ring formed in the cycloaddition. Entry 9 portrays the early stages of synthesis of the biologically important molecule biotin. The reaction in Entry 10 was used to establish the carbocyclic skeleton and stereochemistry of a group of toxic indolizidine alkaloids found in dart poisons from frogs. Entry 11 involves generation of a nitrile oxide. Three other stereoisomers are possible. The observed isomer corresponds to approach from the less hindered convex face of the molecule. 

Two protected 3-amino acids, containing indolizidine and quinolizidine skeletons (607a,b), have been synthesized by using 1,3-dipolar cycloaddition of nitrones (551) and (552) to methyl ( )-5-mesyloxy-2-pentenoate. The key steps of this approach is demonstrated by novel syntheses of indolizidinone and quino-lizidinone derivatives (606a,b) and by the ring opening of the tricyclic 1,3-dipolar cycloaddition products (605a,b) (Scheme 2.268) (779). 

Again, rhodium-complexes, although in a completely different process, catalyzed the formation of indolizidine derivatives through the hydroformylation of pyrroles bearing a terminal double bond. The intermediate aldehyde reacted to afford the final product 74 (Scheme 23) <2004TA1821>. 

Due to the widespread presence of the indolizidine skeleton in many natural products, both the procedures aimed at the functionalization and elaboration of the ring are also of interest. A clear example of this is represented by the elaboration of indolizidinone 184 that was transformed into several different polyhydroxy or alkylated products (Scheme 44) <1995JOC398>. 

Often, in the synthesis of natural products containing the indolizidine substructure, it is necessary to modify a preformed indolizidine ring. This is the case in the synthesis of (+)-myrmicarin 217 191 where the key step is the closure of the third ring through an electrophilic substitution on the pyrrole nucleus (Scheme 45) <2000JOC2824>. 

An impressive number of alkaloids and bioactive compounds containing the indolizidine skeleton have been synthesized. These belong principally to three classes which will be separately analyzed. Other natural products not belonging to these classes will be collected in section 11.09.8.3. 

Indolizidine alkaloids. The key step in a new stereocontrolled synthesis of these alkaloids, such as castanospermine (5), depends upon the diastereoselective reaction of an azagluco aldehyde with allylmetal reagents catalyzed by Lewis acids (12, 21-22). Thus reaction of allyltrimethylsilane with the aldehyde 1 and TiCL, (excess) in CH2C12 at - 85° results in the product 2, formed by selective chelation of the ot-amino aldehydo group with TiCl4. The product can be converted into 5... 

The functionalization of proline has been used to synthesize natural products from the indolizidine alkaloid family [71]. To this end, Lhommet and coworkers utilized... 

Once the methoxy group has been installed and nucleophilic capture of the intermediate has occurred, the product (132) can be treated with an enol ether (e.g. 133) and titanium tetrachloride to affect C-C bond formation adjacent to nitrogen. This sequence served nicely in syntheses of both indolizidine alkaloids elaeokanine A (135) and C (136). 

The construction of an indolizidine skeleton has been successfully obtained by radical cyclizations mediated by (TMS)3SiH. Reaction (7.44) represented a key step in the total synthesis of (—)-slaframine. The two pairs of diastereomers were first separated and then hydrolysed to the corresponding alcohols in a 76% overall yield [55]. On the other hand the cyclization of the A-iodopropyl pyridinones in Reaction (7.45) occurs smoothly at room temperature using Et3B/02 as initiator, to give the desired products with a trifluoromethyl group at the bridgehead position in a syn/anti ratio of 7 3 [56]. 

An efficient kinetic resolution was also observed during the (—)-sparteine-mediated deprotonation of the piperidin-2-yhnethyl carbamate rac-112 (equation 25). By treatment of rac-112 with s-BuLi/(—)-sparteine (11), the pro-S proton in (/ )-112 is removed preferentially to form the lithium compound 113, which undergoes intramolecular cyclo-carbolithiation, and the indolizidinyl-benzyllithium intermediate 114 was trapped with several electrophiles. The mismatched combination in the deprotonation of (5 )-112, leading to cp/-113, does not significantly contribute to product formation. Under optimized conditions [0.75 equivalents of s-BuLi, 0.8 equivalents of (—)-sparteine, 22 h at —78°C in diethyl ether] the indolizidine 115 was isolated with 34% yield (based on rac-112), d.r. = 98 2, e.r. = 97 3 optically active (5 )-112 was recovered (46%, 63% ee). 

The reaction of 1-propargyltetrahydroisoquinoline 76 with PhMe2SiH, catalyzed by Rh(acac)(CO)2 at 60°C and 50 atm. CO furnished the silylcyclocarbonylation (SiCCa) product 77 in 65% yield (Eq. 22) [49]. The SiCCa reaction has been applied to the syntheses of enantiopure indolizidine skeletons, where the aminolysis of the acyl-[Rh] bond took place instead of reductive elimination after silylmetallation of the alkyne moiety [49]. 

Iminium ion-vinylsilane cyclizations closely related to the one described here have been used to prepare indolizidine alkaloids of the pumiliotoxin A and elaeokanine families, indole alkaloids, amaryllidaceae alkaloids, and the antibiotic (+)-streptazolin. The ability of the silicon substituent to control the position, and in some cases stereochemistry, of the unsaturation in the product heterocycle was a key feature of each of these syntheses. 

Michael, J. P. 1993. Indolizidine and quinolizidine alkaloids. Natural Product Reports, 10 51-70. 

Mild conditions discovered for the cyclization of propargyl pyridine 145 were applied to other substituted and elaborated heterocydes, giving indolizidine-type products in good-to-excellent yields (Table 9.17). 

The dipolar cycloaddition of nitronates has been applied to the synthesis of several natural products in the context of the tandem [4+2] / [3 + 2] nitroalkene cycloaddition process. All of these syntheses have focused on the construction of pyrrolidine, pyrrolizidine, and indolizidine alkaloids. For example, the synthesis of ( )-hastanecine (316), a necine alkaloid, involves the elaboration of a p-benzoy-loxynitroalkene 311 via [4 + 2] cycloaddition with a chiral vinyl ether (312) in the presence of a titanium based Lewis acid, to provide the nitronate 313 with high diastereo- and facial selectivity (Scheme 2.30) (69). The dipolar cycloaddition of... 

Pandey and Lakshmaiah (10) further extended their methodology to the construction of the indolizidine and pyrrolizidine bicyclic skeleta. The basic precursor 41, which was realized in three straightforward steps, underwent double desilyation and subsequent cycloaddition with ethyl acrylate to furnish the two regioisomers 42 and 43 in essentially quantitative yield and in a 17 3 ratio. The major regioisomer was isolated in a 7 3 endo/exo ratio. Further elaboration of the major products where (n=l) and (n = 2) delivered the natural products... 

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