Alkoxy chiral

With a-alkyl-substituted chiral carbonyl compounds bearing an alkoxy group in the -position, the diastereoselectivity of nucleophilic addition reactions is influenced not only by steric factors, which can be described by the models of Cram and Felkin (see Section 1.3.1.1.), but also by a possible coordination of the nucleophile counterion with the /J-oxygen atom. Thus, coordination of the metal cation with the carbonyl oxygen and the /J-alkoxy substituent leads to a chelated transition state 1 which implies attack of the nucleophile from the least hindered side, opposite to the pseudoequatorial substituent R1. Therefore, the anb-diastereomer 2 should be formed in excess. With respect to the stereogenic center in the a-position, the predominant formation of the anft-diastereomer means that anti-Cram selectivity has occurred. 

An analogous solvent effect was observed upon treatment of the chiral a-alkoxy aldehyde 11 with 2-lithio-4-methylfuran in the presence of zinc bromide. This highly diastereoselective addition reaction was the key step in a synthesis of the enantiomcrically pure C-10-C-20 fragment of the immunosuppressant KK 506139. 

I-Oialkoxy carbonyl compounds are a special class of chiral alkoxy carbonyl compounds because they combine the structural features, and, therefore, also the stereochemical behavior, of 7-alkoxy and /i-alkoxy carbonyl compounds. Prediction of the stereochemical outcome of nucleophilic additions to these substrates is very difficult and often impossible. As exemplified with isopropylidene glyceraldehyde (Table 15), one of the most widely investigated a,/J-di-alkoxy carbonyl compoundsI0S, the predominant formation of the syn-diastereomer 2 may be attributed to the formation of the a-chelate 1 A. The opposite stereochemistry can be rationalized by assuming the Felkin-Anh-type transition state IB. Formation of the /(-chelate 1C, which stabilizes the Felkin-Anh transition state, also leads to the predominant formation of the atm -diastereomeric reaction product. 

A convenient route to highly enantiomerically enriched a-alkoxy tributylslannanes 17 involves the enanlioselective reduction of acyl stannanes 16 with chiral reducing agents10. Thus reaction of acyl stannanes with lithium aluminum hydride, chirally modified by (S)-l,l -bi-naphthalene-2,2 -diol, followed by protection of the hydroxy group, lead to the desired a-alkoxy stannanes 17 in optical purities as high as 98 % ee. 

Chiral organolead compounds 19 can be obtained, with retention of configuration, from the corresponding a-alkoxy stannanes via tin/lilhium exchange and transmetalation with bro-mo(tributyl)lcad12. 

The data reported in Table 3 for the 2-butenylborations of 2-(dibenzylamino)propanal shed additional light on this transition state model. The ( )-2-butenylboration of 2-(dibenzyl-amino)propanal evidently proceeds preferentially (90%) by way of transition state 9, suggesting that the bulky dibenzylamino substituent destabilizes transition state 8 (X = NBn2 > CH3). On the other hand, the (Z)-2-butenylboration of 2-(dibenzylamino)propanal is relatively non-selective, compared to the excellent selectivity realized in the (Z)-allylborations of a-chloro- or x-alkoxy-substituted chiral aldehydes. This result suggests that an increase in the steric requirement of X destabilizes transition state 11 such that significantly greater amounts of product are obtained from transition state 10. 

Results of the asymmetric 2-propenylborations of several chiral a- and /i-alkoxy aldehydes are presented in Table 11 74a-82 84. These data show that diisopinocampheyl(2-propenyl)borane A and l,3-bis(4-methylphenylsulfonyl)-4,5-diphenyl-2-propenyl-l,3,2-diazaborolidine C exhibit excellent diastereoselectivity in reactions with chiral aldehydes. These results are in complete agreement with the enantioselectivity of these reagents in reactions with achiral aldehydes (Section 1.3.3.3.3.1.4.). In contrast, however, the enantioselectivity of reactions of the tartrate 2-propenylboronate B (and to a lesser extent the tartrate (/i)-2-butenylhoronate)53b is highly... 

Table 11. Double Asymmetric Reactions of Chiral 1- and fl-Alkoxy Aldehydes...

Optically active dihydro-2-methylene-2(3//)-furanones fused to 5- and 6-membered carbocyclic rings were synthesized with 64-92% ee using the intramolecular reaction between chiral 2-alkoxy-carbonylallylsilanes and aldehydes80. 

In the more successful reagents, the ligands have been selected in such a way that the metal center remains nonstereogenic, this has been achieved mainly by application of chiral diols with C2 symmetry or by introduction of two of the same alkoxy residues. 

The diastereofacial selectivity of addition of achiral allylchromium to chiral aldehydes is mainly determined by steric approach control even a- and /5-alkoxy-subsliluents apparently do not give rise to a rate-determining chelation9. 

The diastereomeric a-alkoxy complexes (1 )-15 and (S)-15, separable by chromatography, were each converted to the corresponding aluminum enolates and reacted with 2-methylpropanal (17)49. Enolate (/ )-16 selectively provided a mixture of two diastereomers with the (Fe/ ,2, 3 i )-complex (/ )-18 identified as the major constituent of a 94 6 mixture. The two chiral auxiliaries of complex (S j-lS exerted antagonistic effects and an undefined mixture of all four possible diastereomers was obtained. 

---