Diacetates, prochiral desymmetrization

In an asymmetric synthesis, the enantiomeric composition of the product remains constant as the reaction proceeds. In practice, ho vever, many enzymatic desymmetrizations undergo a subsequent kinetic resolution as illustrated in Figure 6.5. For instance, hydrolysis of a prochiral diacetate first gives the chiral monoalcohol monoester, but this product is also a substrate for the hydrolase, resulting in the production of... 

Also, desymmetrization of prochiral hydroxyalkylphosphine P-boranes was successfully performed using similar reagents and conditions. In the case of bis(hydroxymethyl)phenylphosphine P-borane 87, both its acetylation and hydrolysis of the diacetyl derivative 89 gave good results, although in addition to the expected monoacetate 88, the diol 87 and diacetate 89 were always present in the reaction mixture (Equation 42). °°... 

An efficient synthesis of (R)- and (S)-1 -amino-2,2-difluorocycloropanecarboxylic acid (DFACC) 91 via lipase-catalyzed desymmetrization of prochiral diols 89 and prochiral diacetates 92 was recently reported.28 Thus, the lipase-catalyzed transesterification of 89 using vinyl acetate as acyl donor in benzene di-z-propyl ether (20 1) as organic solvent... 

Figure 46 Lipase-catalyzed desymmetrization of prochiral diols 89 and diacetates 92.28...

Enzymatic resolution has been successfully applied to the preparation of optically active gem-difluorocyclopropanes (see Scheme 12.4). We succeeded in the first optical resolution of racemic gm-difluorocyclopropane diacetate, trans-43, through lipase-catalyzed enantiomer-specific hydrolysis to give (R,R)-(-)-44 with >99% ee (see equation 9, Scheme 12.4) [4a], We also applied lipase-catalyzed optical resolution to an efficient preparation of monoacetate cw-46 from prochiral diacetate m-45 (see equation 10, Scheme 12.4) [4a], Kirihara et al. reported the successful desymmetrization of diacetate 47 by lipase-catalyzed enantiomer-selective hydrolysis to afford monoacetate (R)-48, which was further transformed to enantiopure amino acid 15 (see equation 11, Scheme 12.4) [19]. We demonstrated that the lipase-catalyzed enantiomer-specific hydrolysis was useful for bis-gem-difluorocyclopropane 49. Thus, optically pure diacetate (R,S,S,R)-49 and (S,R,R,S)-diol 50, were obtained in good yields, while meso-49 was converted to the single monoacetate enantiomer (R,S,R,S)-51 via efficient desymmetrization (see equation 12, Scheme 12.4) [4b, 4e], Since these mono- and bis-gm-difluorocyclopropanes have two hydroxymethyl groups to modify, a variety of compounds can be prepared using them as building blocks [4, 22],... 

Chiral ligand 651 is obtained from the appropriate natural amino-acid phenylalanine, whereas the corresponding derivatives of valine or leucine proved to be slightly less effective [46], Axially prochiral, enantiotopic, biaryl-2,6-diols have been converted to the respective chiral compounds via enzymatic desymmetrization. Thus Pseudomonas cepacia lipase (PCL) catalysed the atropisomerically-selective hydrolysis of diacetate 654 to give monoacetate 655 in 67% yield and 96% e. e. [47], Scheme 24. 

This chapter illustrates the application of lipases and esterases as user-friendly biocatalysts in (i) desymmetrization of prochiral or meso-diols and diacetates, (ii) kinetic resolution of racemic alcohols, and (iii) preparation of enantiopure intermediate(s) from a mixture of stereoisomers by enzymatic differentiation. All the examples were taken from our own works in natural products synthesis. 

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