Claisen asymmetric enolate

As a single example of asymmetric enolate Claisen rearrangement assisted by a chiral ligand, Kazmaier and Krebs reported that the treatment of allyl aminoac-etatesa with LiHMDS in the presence of Al(Oi-Pr)3 and quinine gives the Claisen product with excellent diastereo- and enantioselectivity (Scheme 6.165) [195]. 

The most recent, and probably most elegant, process for the asymmetric synthesis of (+)-estrone appHes a tandem Claisen rearrangement and intramolecular ene-reaction (Eig. 23). StereochemicaHy pure (185) is synthesized from (2R)-l,2-0-isopropyhdene-3-butanone in an overall yield of 86% in four chemical steps. Heating a toluene solution of (185), enol ether (187), and 2,6-dimethylphenol to 180°C in a sealed tube for 60 h produces (190) in 76% yield after purification. Ozonolysis of (190) followed by base-catalyzed epimerization of the C8a-hydrogen to a C8P-hydrogen (again similar to conversion of (175) to (176)) produces (184) in 46% yield from (190). Aldehyde (184) was converted to 9,11-dehydroestrone methyl ether (177) as discussed above. The overall yield of 9,11-dehydroestrone methyl ether (177) was 17% in five steps from 6-methoxy-l-tetralone (186) and (185) (201). 

Discussing the stereochemical outcome of the Claisen rearrangements, two aspects had to be considered. On the one hand, the relative configuration of the new stereogenic centers was found to be exclusively syn in 201 and 202, pointing out the passing of a chair-like transition state c-a and c-jS, respectively, including a Z-acylammonium enolate structure (complete simple diastereo-selectivity/internal asymmetric induction). 

The Claisen rearrangement was used in the asymmetric total synthesis of (+)-9(ll)-dehydroestrone methyl ether (5), a versatile intermediate in the synthesis of estrogens5 (Scheme 1. If). The key feature of the synthesis is the successful development of the asymmetric tandem Claisen-ene sequence. Thus, a solution of the cyclic enol ether 6 in toluene was heated in a sealed tube at 180 C for 60 hours to afford the product 9 in 76% isolated yield after deprotection of the silyl enol ether. The Claisen rearrangement of the allyl vinyl ether 6 occurred stereoselectively to give an intermediate (7), in which the 8,14-configuration was 90% syn. The stereoselectivity in the Claisen rearrangement can be explained... 

A clever application of the ME rearrangement, this time including its stereochemical potential, was developed by Heathcock [133]. The concatenation of an asymmetric aldol reaction [134-136], an ester-enolate Claisen rearrangement [137,138], and a ME reaction allow for the stereoselective generation of a 1,2,5-stereotriad. 

Asymmetric Ireland-Claisen Rearrangements. Chiral enolates derived from the boron complex (5) and allyl esters rearrange with excellent selectivity upon warming to —20 °C for a period of 1-2 weeks (eqs 9 and 10). As discussed above, the geometry of the intermediate enolate can be controlled by appropriate choice of base and solvent, thus allowing access to either syn or anti configuration in the product The reaction can be completed in 2-4 days with little erosion in selectivity when run at 4 °C. 

Table 5) [28], and heteroatom Diels-Alder reactions (Sch. 50) [79,80] but no X-ray structure had ever been reported for it or for the 3,3 -disubstituted derivatives which were first introduced as an asymmetric Claisen catalyst [24-27]. Although compound 435 was found not to induce any reaction between cyclohexenone and phosphonate 425 under the standard conditions for catalyst 428, consistent with the proposed equilibrium of species 394, 431, 432, 433, and 434 is the finding that catalysis of the reactions between cyclohexenone or cyclopentenone and phosphonate 425 with a 2 1 mixture of 434 (M = Li) and 435 gave only the Michael adducts 426 and 427 in 96 % ee and 92 % ee, respectively. Because 394 and 432 are inactive catalysts and 434 results in much lower induction and some 1,2-adduct, it was proposed that the active catalyst in the Michael addition of phosphonate 425 to cyclohexenone was the species 431 resulting from association of ALB catalyst with a metal alkoxide. It was proposed that the stereochemical determining step involved intramolecular transfer of the enolate of 425 to the coordinated cyclohexenone in species 436. 

C.H. Heathcock and co-workers devised a highly convergent asymmetric total synthesis of (-)-secodaphniphylline, where the key step was a mixed Claisen condensation. In the final stage of the total synthesis, the two major fragments were coupled using the mixed Claisen condensation] the lithium enolate of (-)-methyl homosecodaphniphyllate was reacted with the 2,8-dioxabicyclo[3.2.1]octane acid chloride. The resulting crude mixture of (3-keto esters was subjected to the Krapcho decarboxylation procedure to afford the natural product in 43% yield for two steps. 

T. Nakata et al. developed a simple and efficient synthetic approach to prepare (+)-methyl-7-benzoylpederate, a key intermediate toward the synthesis of mycalamides. The key steps were the Evans asymmetric aldol reaction, stereoselective Claisen condensation and the Takai-Nozaki olefination. The diastereoselective Claisen condensation took place between a 5-lactone and the lithium enolate of a glycolate ester. 

The N=C double bond of anils can be a part of 1,5-diene systems that are able to undergo the aza-Claisen rearrangement (see Section III.A.2.b). Such asymmetric isomerization of allylic imidoester enolates 115 was observed upon deprotonation with lithium diethylamide to give the amides 116 in moderate yields but with good stereoselectivity195 (equation 47). 

Scheme4.23 Asymmetric ester enolate Claisen rearrangement of (N)-trifluoroacetyl-glycine allylic esters.

A new stereocenter is established in the Claisen condensation whenever the carbanionic carbon center that is undergoing acylation bears two different groups. Normally, however, the basic conditions of the reaction result in the formation of the enolate of the 3-dicarbonyl system and the loss of stereochemical integrity. Two groups have now reported the asymmetric acylation of optically active imide enolates. 

The synthesis of three fragments 278, 282, and 285 for the C21-C42 bottom segment is summarized in Scheme 41. The Eschenmoser-Claisen rearrangement of amido acetal of 276, which was prepared via 2-bromocyclohexenone by Corey s asymmetric reduction, afforded amide 277. Functional group manipulation including chain elongation provided Evans-type amide 278. The Evans aldol reaction of boron enolate of 279 with aldehyde 280 stereoselectively afforded 281, which was converted into aldehyde 282 through a sequence of seven steps... 

---