Nitrones pyrrolizidines

Enantioenriched (-)-rosmarinecine, which belongs to the group of pyrrolizidine alkaloids [413], has been synthesized by Goti, Brandi and coworkers applying an intramolecular 1,3-dipolar cycloaddition as the key step [414]. The required nitrone was obtained in situ from L-malic acid. Moreover, 1,3-dienes as precursors for a cy-... 

The strategy based on tandem cycloaddition leads to a short and efficient asymmetric synthesis of the pyrrolizidine necine base (-)-hastanecine, as shown in Scheme 8.32.163 Pyrrolizidine alkaloids have a long history for attracting the interest of synthetic chemists because of their physiological properties. The method of Denmark shown in this scheme is very simple and applied to synthesis of various alkaloids. The Lewis acid-promoted [4+2] cycloaddition between 2-acyloxy nitroalkene and chiral vinyl ether gives a nitronate that... 

The simplest nitroalkene, nitroethene, undergoes Lewis acid-promoted [4+2] cycloaddition with chiral vinyl ethers to give cyclic nitronates with high diastereoselectivity. The resulting cyclic nitronates react with deficient alkenes to effect a face-selective [3+2] cycloaddition. A remote acetal center controls the stereochemistry of [3+2] cycloaddition. This strategy is applied to synthesis of the pyrrolizidine alkaloids (+)-macronecine and (+)-petasinecine (Scheme 8.33).165... 

An interesting strategy for the synthesis of pyrrolizidines and indolizidines has been developed by Brandi and co-workers. Cycloaddition between nitrones or nitrile oxides with methylenecyclopropanes generates strained tricyclic spiro compounds, which are prone toward further transformations, such as rearrangement, ring opening, and new ring closure (Scheme 10.17).116... 

Reductive coupling of the corresponding nitrones with alkyl acrylate is the key step in the short synthetic route of the selective and irreversible GABA inhibitor of amino transferase (S)-vigabatine (534) and of polyhydroxy pyrrolizidine alkaloid (+ )-hyacinthacine A2 (535). 

Highly selective 1,3-dipolar cycloaddition reactions of nitrone (154) with acrylates have been used in the total syntheses of pyrrolizidine alkaloids, 7-deoxy-casuarine (572) and hyacinthacine A2 (573) (Scheme 2.263) (772). 

Dipolarophiles D14. The 1,3-dipolar cycloaddition of nitrones to dimethyl maleate and dimethyl fumarate is widely used in the synthesis of polyhydroxy alkaloid derivatives of dihydroindolizidinone (81), pyrrolizidine (119), (—)-codonopsinine, and (+ )-hyacinthacines Ai and A2 (312). In cases of unstable nitrones, syntheses of cycloadducts are performed in situ (81). 

Cycloaddition reaction of nitrone (—)-(394) with dimethyl maleate D14 has been used for the synthesis of two new polyhydroxyl pyrrolizidines (687) and (688) (Schemes 2.293, 2.294). These compounds are analogs of alkaloids ros-marinecine and crotanecine, which were assayed for their inhibitory activities toward 22 commercially available glycosidase enzymes. One of them ((-)- a-epi-crotanecine) (—)-(688) is a potent and selective inhibitor of a-mannosidases (310). The reaction of (—)-(394) with dimethyl maleate gave a 9.6 6 1 mixture of cycloadducts (—)-(680), (+ )-(680), and (—)-(681), which arise from anti-exo,... 

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... 

Silver ion catalysis has also been used with allenic oximes to generate cyclic nitrones, which are trapped by 1,2-dipolarophiles (equation 142).270 This reaction was used in a synthesis of pyrrolizidine alkaloids.270 5... 

Unsaturated oximes can be cyclized simply by heating.24b It has been suggested that nitrone intermediates are involved in this process. Thus, oxime (53) on heating at 180 °C cyclized to a pyrrolizidine in 60% yield presumably tautomerization to nitrone (54) first occurred followed by [3 + 2] cycloaddition (Scheme 14). Likewise, quinolizidine (55) was obtained in 69% yield from the corresponding oxime. 

Thermal intramolecular cycloaddition reactions of unsaturated nitrones 1341 derived from a series of N- 2-alkenyl)-2-pyrrolecarbaldehydes 1340 and benzylhydroxylamine lead to competitive formation of two kinds of intramolecular cycloadducts, namely the fused- and the bridged-ring regioisomers 1342 and 1343, respectively (Scheme 255) <2001T8323>. Further elaboration of compounds 1342 and 1343 has given pyrrolizidine and indolizidine derivatives, respectively. A similar regiochemical trend was observed when aldehydes 1340 were reacted with (/ )-a-methylbenzylhydroxylamine in order to synthesize optically active compounds. 

DCP-hased Chiral Auxiliaries in Total Synthesis. DCP-based chiral auxiliaries have proven amenable to asymmetric total synthesis, including Denmark s syntheses of of the pyrrolizidine alkaloid (-)-rosmarinecine and the pentahydroxy pyrrolizidine alkaloid (+ )-casuarine. Denmark s synthesis of (+)-casuarine involves [4 + 2] cycloaddition of dienophile 15 with nitrobenzoate followed by [3 + 2] cycloaddition of the resulting nitronate 17 with a vinyl silane 18 (eq 10). During formation of the [4 + 2] cycloadduct, the relative configuration between C4 and C5 is a direct consequence of the vinyl ether geometry, while the stereochemistry at C6 is determined by the ability of the chiral auxiliary to differentiate the diastereotopic n faces (Re of Si) of the vinyl ether (termed internal diastereoselection). Thus, this tandem sequence... 

The tandem inter-[4+2]/intra-[3+2] cycloaddition process involving dienylsilyloxy nitroalkene 540 and chiral vinyl ether 541 in the presence of methylaluminium bis(2,6-diphenylphenoxide) (MAPh) as Lewis acid afforded the single cycloadduct 542 in 66% yield. On a preparative scale, a lower yield (49%) of the purified product was obtained (Scheme 126) <2001JOC4276>. The two-atom linker between the nitronate and the dipolarophile moieties in 540 and the configuration of the chiral auxiliary phenylcyclohexanol could be chosen to obtain the adduct 542 with the relative and absolute configuration at the newly formed stereocenters, as required in the pyrrolizidine alkaloid (-l-)-l-epiaustraline. 

Dipolar cycloadditions of pyrroHne N-oxides, which could be regarded as cycHc nitrones , on electron-poor aUcenes, represent a viable method to obtain highly substituted pyrrolizidines. Enantiopure (S)-3-alkoxypyrroline N-oxide (170), on the other hand, has been exploited in stereoselective cycloaddition reactions with solid-supported unsaturated esters (169) [266]. A both regio- and stereoselective cycloaddition took place in this case, affording the desired compound (171) as a single isomer (Scheme 36). 

Abstract This review is devoted to the stereoselectivity of intermolecular (intramolecular cycloadditions are not included) 1,3-dipolar cycloadditions of sugar-derived nitrones. Stereoselective cycloaddition (transformation of isoxazolidine followed by reduction of the N O bond to produce both an amino and a hydroxy function) allows the synthesis of tailor-made products of possible biological interest such as pol>4iydroxylated pyrrolidines, pyrrolizidines, indolizidines, fi-aminocarbonyl compounds, and disaccharides. Attention is focused on the preparation of isoxazolidinyl nucleosides and to the catalysis of the cycloaddition by Lewis acids. This review has concentrated on the new developments achieved from 1999 to February 2007. 

An account of a lecture by Jager incorporates some new work in this area, including the synthesis of the cycloadduct 178 by cycloaddition of a glucose-derived nitrone with ethyl acrylate (sugar numbers indicated), and its subsequent conversion to the pyrrolizidine 179. ... 

There has been no report so far of a synthesis of (+)-hyacinthacines Ci, C4, and C5 bearing substituents at each carlxMi of the pyrrolizidine skeleton. Therefore, their absolute configurations have yet to be determined. Yu and colleagues described recently the total synthesis of the proposed structure of ( )-hyacinthacine C5 [21] based on an original nucleophilic addition of a dithiane onto the xylose-derived nitrone 62 followed by a Cope-House cycli-zation (Scheme 13). 

The racemic dilithio species 69 was prepared from l-(l,3-dithian-2-yl)pro-pan-l-ol and added to nitrone 62 to provide hydroxylamine 70, which was then subjected to Cope-House pericychc cyclization, installing the methyl substituent at the C-5 position (Scheme 14). The resulting pyrrolizidine AT-oxides 71-72, obtained as a 1 1 mixture in a moderate 55% yield, were submitted to subsequent N—O bond reductive cleavage, providing the desired pyrrolizidines 73-74. A two-step sequence involving hydrolysis of the dithio-ketal and then reduction of the ketone provided the partially protected hya-cinthacine core as a single isomer in 33% yield. Subsequent removal of the... 

Bicyclic isoxazolidine 63 was obtained in good yield by 1,3-DC of D-arabinose-derived nitrone 61 and D-mannitol-derived alkene 62 and then used as common intermediate for a divergent synthesis of polyhydroxy-indolizidines and -pyrrolizidines. Iminosugars 64 and 65 proved to be good inhibitors of some commercially available glycosidases (14JOC10786). 

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