Alkaloids stereoselective reduction

Preparative-scale fermentation of papaveraldine, the known benzyliso-quinoline alkaloid, with Mucor ramannianus 1839 (sih) has resulted in a stereoselective reduction of the ketone group and the isolation of S-papaverinol and S-papaverinol M-oxide [56]. The structure elucidations of both metabolites were reported to be based primarily on ID and 2D NMR analyses and chemical transformations [56]. The absolute configuration of S-papaverinol has been determined using Horeau s method of asymmetric esterification [56]. The structures of the compounds are shown in Fig. 7. 

To demonstrate the versatility of his S3mthesis strategy Yamada used ketoester 151 as relais substance to S3mthesize two further picrotoxane alkaloids isolated from Dendrobium species, nobilonine (90) and 2-hydroxydendrobine (87) (Scheme 14) (84). Monobromination of 151 with bromine in dioxane and subsequent treatment with water resulted in hydroxy-y-lactam 152, whereas attempts to hydroxylate 151 by Barton oxidation led to rearrangements. Chemo- and stereoselective reduction with zinc borohydride converted 152 into the en fo-alcohol. To counterbalance the unfavorable conformational equilibrium this alcohol had to be converted into the alcoholate to achieve lactonization. Chemoselective reduction of the hydroxylac-tam moiety of lactone 153 again followed Borch s protocol, which led in this case to boron complexed amino compounds necessitating successive acid treatment to obtain racemic 2-hydroxydendrobine (87) in low yield accompanied by dendrobine (82). 2-Hydroxydendrobine (87) was converted into nobilonine (90) by Eschweiler-Clark methylation. 

The alkaloid (+)-pinidine81 (4) is obtained as a single a s-stereoisomer in a one-pot transformation of the chiral methyl sulfide 3 via oxidative amination, rearrangement, intramolecular imine formation and stereoselective reduction. 

The synthesis of a variety of tropane alkaloids has been achieved via 6,7-dehydrotropines (105), derived from (82) by stereoselective reduction with diisobutylaluminum hydride. Suteequent ap[ opriate modification of the double bond leads to several naturally occurring tropane alkaloids, including tropine (106), scopine (107), tropanediol (108) and teloidine (109) (Scheme 25). ... 

Cyclic imines will not be dealt with in this review as the conversion is often simply achieved. Mention will be made to the stereoselective reduction involved in the preparation of Solenopsin A and B (131), two naturally occurring piperidine alkaloids isolated from the venom of the fire ant. The desired trans isomer 131 was obtained with > 95% selectivity, using LAH (7 equiv) and trimethylaluminum (7 equiv) in THF. This selectivity could be reversed by using LAH (7 equiv) and NaOMe (14 equiv). °... 

Scheme 8.94). Reduction of the alkene 8.339 and removal of the two protecting groups enabled stereoselective reductive amination to give the alkaloid 8.340. 

Two unselective approaches to the two alkaloids are illustrated in Scheme 50. A straightforward synthesis by King relied on acid-induced intramolecular Mannich reaction of ammoketone 396, prepared from 5-aminopentanal diethyl acetal and pent-3-en-2-one, to give a mixture of ( )-394 (55%) and ( )-395 (20%) (367). The synthesis by Pilli et at. involved a one-pot trimethylsilyl triflate-catalyzed condensation between pent-3-en-2-one and the acyliminium ion derived fium JV-Boc-2-ethoxypiperidine (397) (368,369). Under the reaction conditions, the intermediate 398 underwent spontaneous V-deprotection and cyclization to give a 5.5 1 mixture of ( )-394 and ( )-395 (67%). In the same Scheme is also shown the much shorter stereoselective synthesis of ( )-394 by Beckwith et al, who used a radical-mediated cyclization on the V-acylated 2,3-dihydropyridin-4-one 399 to give the bicyclic product 400 as the sole diastereomer (91%) (370). Compound 400 was readily converted into the target alkaloid by reduction of both carbonyl groups with lithium aluminum hydride followed by reoxidation of the secondary alcohol at C-2. 

The stereoselective total synthesis of both ( )-corynantheidine (61) (170,171) (alio stereoisomer) and ( )-dihydrocorynantheine (172) (normal stereoisomer) has been elaborated by Szdntay and co-workers. The key intermediate leading to both alkaloids was the alio cyanoacetic ester derivative 315, which was obtained from the previously prepared ketone 312 (173) by the Knoevenagel condensation accompanied by complete epimerization at C-20 and by subsequent stereoselective sodium borohydride reduction. ( )-Corynantheidine was prepared by modification of the cyanoacetate side chain esterification furnished diester 316, which underwent selective lithium aluminum hydride reduction. The resulting sodium enolate of the a-formyl ester was finally methylated to racemic corynantheidine (171). 

Selective ring closure of cyclic secondary alkyl radicals onto the central carbon atom of allenes have been investigated in the course of pyrrolizidine alkaloid syntheses [69]. Thus, reduction of the phenylselenyl-substituted N-(l,2-buten-4-yl)pyrroli-done 42 with Bu3SnH via a radical chain mechanism provides 51% of target compound 44 as a 78 22 mixture of diastereomers (Scheme 11.14). The stereoselectivity... 

Acid treatment of a 3 1 mixture of murrayafoline A (7) and koenoline (8) led to chrestifoline A (192) in 70% yield. Addition of murrayafoline A (7) to a mixture of 1057 and lithium aluminum hydride in ether and dichloromethane afforded bismurrayafoline-A (197) in 19% yield (662) (Scheme 5.166). In addition to the aforementioned methods, the same group also reported a stereoselective synthesis of axially chiral bis-carbazole alkaloids by application of their "lactone concept" (663) and a reductive biaryl coupling leading to 2,2 -bis-carbazoles (664). 

Intramolecular cyclization of ally lie stannanes.1 The pyrrolizidine alkaloid isoretronecanol (3) can be synthesized efficiently by cyclization of the mesylate of the hydroxylactam 1 to give 2 stereoselectively. Oxidative cleavage followed by reduction of the keto group gives 3. 

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