Substrate, prochiral desymmetrization

CHMO is known to catalyze a number of enantioselective BV reactions, including the kinetic resolution of certain racemic ketones and desymmetrization of prochiral substrates [84—87]. An example is the desymmetrization of 4-methylcyclohexanone, which affords the (S)-configurated seven-membered lactone with 98% ee [84,87]. Of course, many ketones fail to react with acceptable levels of enantioselectivity, or are not even accepted by the enzyme. 

Figure 6.4 Hydrolase-catalyzed desymmetrization of a prochiral (a), a meso (b), or a centrosymmetric (c) substrate.

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... 

Esterases, proteases, and some lipases are used in stereoselective hydrolysis of esters bearing a chiral or a prochiral acyl moiety. The substrates are racemic esters and prochiral or meso-diesters. Pig liver esterase (PLE) is the most useful enzyme for this type of reaction, especially for the desymmetrization of prochiral or meso substrates. 

The biocatalytic differentiation of enantiotopic nitrile groups in prochiral or meso substrates has been studied by several research groups. For instance, the nitrilase-catalyzed desymmetrization of 3-hydroxyglutaronitrile [92,93] followed by an esterification provided ethyl-(Jl)-4-cyano-3-hydroxybutyrate, a useful intermediate in the synthesis of cholesterol-lowering dmg statins (Figure 6.32) [94,95]. The hydrolysis of prochiral a,a-disubstituted malononitriles by a Rhodococcus strain expressing nitrile hydratase/amidase activity resulted in the formation of (R)-a,a-disubstituted malo-namic acids (Figure 6.33) [96]. 

Of the two former processes shown in Scheme 5.2, the kinetic resolution of race-mates has found a much greater number of applications than the desymmetrization of prochiral or meso compounds. This is due to the fact that racemic substrates are much more common than prochiral ones. However, kinetic resolution suffers from a number of drawbacks, the main being the following ... 

To avoid the inherent limitations of a kinetic resolution process, the reaction was extended to desymmetrization of prochiral meso epoxides. A number of cyclic di-methylidene epoxides were synthesized and subjected to treatment with Et2Zn in the presence of Cu(OTf)2 and ligands 42 or 43. As in the case mentioned above, ligand 42 was superior in terms of selectivity. Cydohexane derivative 46 gave the ring-opened product with a 97% ee and in a 90% isolated yield, with a y/a ratio of 98 2 (Scheme 8.28). The other substrates investigated produced sigmficantly lower ees of between 66% and 85%. 

Nitrilases catalyze the synthetically important hydrolysis of nitriles with formation of the corresponding carboxylic acids 7-11). Enantioselectivity is relevant in the kinetic resolution of racemic nitriles or desymmetrization of prochiral dinitriles. Both versions have been applied successfully to a number of different substrates using one of the known currently available nitrilases. Recently, scientists at Diversa expanded the collection of nitrilases by metagenome panning 150). Nevertheless, in numerous cases the usual limitations of enzyme catalysis become visible, including poor or only moderate enantioselectivity and limited activity. 

In the first reported case of the directed evolution of an enantioselective nitrilase, an additional limitation had to be overcome that is sometimes ignored when enzymes are used as catalysts in synthetic organic chemistry product inhibition and/ or decreased enantioselectivity at high substrate concentrations 46). A case in point concerns the desymmetrization of the prochiral dinitrile 35 with preferential formation of the ( /-configurated acid 18, which is known to be a chiral intermediate in the synthesis of the cholesterol-lowering therapeutic drug 36 (Lipitor, ... 

The concept of isotopic labeling for distinguishing pseudo enantiomers in the kinetic resolution of chiral compounds and in the desymmetrization of prochiral substrates bearing reactive enantiotopic groups (Sections 9.2 and 9.3) can also be applied when Fourier transform infrared spectroscopy (FTIR) is used as the detec-... 

Desymmetrization of an achiral, symmetrical molecule through a catalytic process is a potentially powerful but relatively unexplored concept for asymmetric synthesis. Whereas the ability of enzymes to differentiate enantiotopic functional groups is well-known [27], little has been explored on a similar ability of non-enzymatic catalysts, particularly for C-C bond-forming processes. The asymmetric desymmetrization through the catalytic glyoxylate-ene reaction of prochiral ene substrates with planar symmetry provides an efficient access to remote [28] and internal [29] asymmetric induction (Scheme 8C.10) [30]. The (2/ ,5S)-s> i-product is obtained with >99% ee and >99% diastereoselectivity. The diene thus obtained can be transformed to a more functionalized compound in a regioselective and diastereoselective manner. 

Desymmetrization and Kinetic Resolution of Anhydrides Desymmetrization of meso-Epoxides and other Prochiral Substrates... 

Most work on this subject is based on the use of alcohols as reagents in the presence of enantiomerically pure nucleophilic catalysts [1, 2]. This section is subdivided into four parts on the basis of classes of anhydride substrate and types of reaction performed (Scheme 13.1) - desymmetrization of prochiral cyclic anhydrides (Section 13.1.1) kinetic resolution of chiral, racemic anhydrides (Section 13.1.2) parallel kinetic resolution of chiral, racemic anhydrides (Section 13.1.3) and dynamic kinetic resolution of racemic anhydrides (Section 13.1.4). 

Desymmetrization of prochiral cyclic anhydrides In the presence of the chiral nucleophilic catalyst (e.g. A, Scheme 13.1, top) one of the enantiotopic carbonyl groups of the prochiral (usually meso) cyclic anhydride substrate is selectively converted into an ester. Application of catalyst B (usually the enantiomer or a pseudoenantiomer of A) results in generation of the enantiomeric product ester. Ideally, 100% of one enantiomerically pure product can be generated from the starting anhydride. No reports of desymmetrizing alcoholyses of acyclic meso anhydrides appear to exist in the literature. 

More recent applications in target-oriented synthesis took advantage of the BVMO platform for the generation of enanhocomplementary lactones. In this context, butyrolactones represent appealing intermediates due to the facile availability of prochiral ketone substrates for enzyme-mediated desymmetrizations Scheme 21.7 indicates the potenhal in lignan total synthesis based on products obtained in a previous study [46]. The collechon of BVMOs exploited by our groups also allowed efficient access to various indole alkaloids via enanhocomplementary lactones obtained in the desymmetrizahon of fused bicycloketones [35]. 

Carbonyl-Ene Reaction. BINOL-TiX2 reagent exhibits a remarkable level of asymmetric catalysis in the carbonyl-ene reaction of prochiral glyoxylates, thereby providing practical access to a-hydroxy esters. These reactions exhibit a remarkable positive nonlinear effect (asymmetric amplification) that is of practical and mechanistic importance (eq 19). The desymmetrization of prochiral ene substrates with planar symmetry by the enantiofacial selective carbonyl-ene reaction provides an efficient solution to remote internal asymmetric induction (eq 20). The kinetic resolution of a racemic allylic ether by the glyoxylate-ene reaction also provides efficient access to remote but relative asymmetric induction (eq 21). Both the dibromide and dichloride catalysts provide the (2R,5S)-syn product with 97% diastereoselectivity and >95% ee. 

The known desymmetrization of prochiral 3-substituted glutarates via enzymatic hydrolysis [65] has been optimized by chemists at Ciba Speciality Chemicals for the synthesis on a large scale [66]. The a-chymotrypsin-catalyzed process is characterized by a high substrate concentration of 285 g L and an isolated yield of 94% product with an ee of 98.2% (route C). 

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