Kinetic resolution dynamic

Dynamic kinetic resolution of racemates to obtain 100% yield of products with 100% ee is theoretically possible when the substrate racemizes but the product does not. Some examples are shown in this section. Deracemization reactions where racemic compounds are converted to enantiomerically pure form without changing the chemical structure will also be discussed. 

Potent inhibitor toward W-acetylneuraminic acid synthetase 

A completely different enzyme-catalyzed synthesis of cyanohydrins is the lipase-catalyzed dynamic kinetic resolution (see also Chapter 6). The normally undesired, racemic base-catalyzed cyanohydrin formation is used to establish a dynamic equilibrium. This is combined with an irreversible enantioselective kinetic resolution via acylation. For the acylation, lipases are the catalysts of choice. The overall combination of a dynamic carbon-carbon bond forming equilibrium and a kinetic resolution in one pot gives the desired cyanohydrins protected as esters with 100% yield [19-22]. 

The enzyme-catalyzed regio- and enantioselective reduction of a- and/or y-alkyl-substituted p,5-diketo ester derivatives would enable the simultaneous introduction of up to four stereogenic centers into the molecule by two consecutive reduction steps through dynamic kinetic resolution with a theoretical maximum yield of 100%. Although the dynamic kinetic resolution of a-substituted P-keto esters by chemical [14] or biocatalytic [15] reduction has proven broad applicability in stereoselective synthesis, the corresponding dynamic kinetic resolution of 2-substituted 1,3-diketones is rarely found in the literature [16]. 

7 Flexible As jmmetric Redox Reactions and C-C Bond Formation 389 

This indeed verifies the dynamic kinetic resolution of roc-3 through enzymatic reduction, representing the first example for the dynamic kinetic resolution of an open-chain 2-alkyl-substituted 1,3-diketone through reduction under neutral conditions. 

In this chapter, DKRs are categorized, according to the racemization method employed, as being base-, acid-, aldehyde-, enzyme-, or metal-catalyzed. Also, radical-induced racemizations, and racemizations that take place through continuous cleavage/formation of the substrate or through SN2 displacement, are among other methods that are also discussed. In most cases, the racemization method of choice depends on the structure of the substrate. In all cases, the KR is catalyzed by an enzyme. 

Entry Substrate Hydrogen donor Product Initial TOP  

NH3 is generated above pH 4.7. In these reactions, the hydride complexes [(Cp Ir)2(p-H)(p-OH)(g-HCOO)] (25) and [Cp Ir(bpy)(H)] (31), which would be generated from the reactions of 24 and 28 with HCOO, would be key catalytic intermediates. The dehalogenation of the alkyl halides using 24 did not occur, most likely due to the bulkiness of the active catalyst 25 compared to 31 in SN2-type reactions (entry 5). 

The highly efficient catalytic system for the chemoselective transfer hydrogenation of aldehydes was reported by Xiao et al. [52]. This system consisted of [Cp IrCl2]2 (1), a diamine and HCOONa, and worked on water and in air. A wide range of aromatic aldehydes were reduced to the corresponding primary alcohols in a highly chemoselective manner some representative examples are summarized in Table 5.9. 

There are three basic requirements for an efficient DKR an efficient KR (i.e. fejj kg), an efficient racemization method (i.e. 10 kg), and a compatibiHty 

Thus the catalyst needed for racemization should be effective under mild conditions of temperature and pressure and ideally have a broad substrate scope. 

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Scheme 9.20 Dynamic kinetic resolution of racemic epoxide...

Hydantoinases belong to the E.C.3.5.2 group of cyclic amidases, which catalyze the hydrolysis of hydantoins [4,54]. As synthetic hydantoins are readily accessible by a variety of chemical syntheses, including Strecker reactions, enantioselective hydantoinase-catalyzed hydrolysis offers an attractive and general route to chiral amino acid derivatives. Moreover, hydantoins are easily racemized chemically or enzymatically by appropriate racemases, so that dynamic kinetic resolution with potential 100% conversion and complete enantioselectivity is theoretically possible. Indeed, a number of such cases using WT hydantoinases have been reported [54]. However, if asymmetric induction is poor or ifinversion ofenantioselectivity is desired, directed evolution can come to the rescue. Such a case has been reported, specifically in the production of i-methionine in a whole-cell system ( . coli) (Figure 2.13) [55]. 

Figure 5.1 Schematic illustration of (a) dynamic kinetic resolution, (b) deracemization, and (c) enantioconvergent processes.

Kinetic Resolution, Dynamic Kinetic Resolution, and Desymmetrization... 

Figure 6.1 Kinetic resolution k ac — ) dynamic kinetic resolution (krac ks)-...

Figure 6.30 Nitrilase-catalyzed dynamic kinetic resolution of cyanohydrins.

Figure 6.38 Dynamic kinetic resolution of amino acid amides.

Figure 6.43 Dynamic kinetic resolution of (rac)-hydantoins by a D-hydantoinase.

The resolution of racemic ethyl 2-chloropropionate with aliphatic and aromatic amines using Candida cylindracea lipase (CCL) [28] was one of the first examples that showed the possibilities of this kind of processes for the resolution of racemic esters or the preparation of chiral amides in benign conditions. Normally, in these enzymatic aminolysis reactions the enzyme is selective toward the (S)-isomer of the ester. Recently, the resolution ofthis ester has been carried out through a dynamic kinetic resolution (DKR) via aminolysis catalyzed by encapsulated CCL in the presence of triphenylphosphonium chloride immobilized on Merrifield resin (Scheme 7.13). This process has allowed the preparation of (S)-amides with high isolated yields and good enantiomeric excesses [29]. 

Ue 7.13 Dynamic kinetic resolution of 2-Chloropropionate by enzymatic aminolysis. 

Scheme 7.19 Dynamic kinetic resolution of primary amines.

Dynamic kinetic resolution of racemic ketones proceeds through asymmetric reduction when the substrate does racemize and the product does not under the applied experimental conditions. Dynamic kinetic resolution of a-alkyl P-keto ester has been performed through enzymatic reduction. One isomer, out of the four possible products for the unselective reduction (Figure 8.38), can be selectively synthesized using biocatalyst, and by changing the biocatalyst or conditions, all of the isomers can be selectively synthesized [29]. 

Dynamic kinetic resolution of a-alkyl-P-keto ester was conducted successfully using biocatalysts. For example, baker s yeast gave selectively syn(2R, 3S)-product [29a] and the selectivity was enhanced by using selective inhibitor [29b] or heat treatment of the yeast [29c]. Organic solvent was used for stereochemical control of G. candidum [29d]. Plant cell cultures were used for reduction of 2-methyl-3-oxobu-tanoate and afforded antialcohol with Marchantia [29e,f] and syn-isomer with Glycine max [29f]. 

Another example of dynamic kinetic resolution is the reduction of a sulfur-substituted ketone. Thus, yeast reduction of (R/S)-2-(4-methoxyphenyl)-l, 5-benzothiazepin-3,4(2H, 5H)-dione gave only (2S, 3S)-alcohol as a product out of four possible isomers as shown in Figure 8.39c [29kj. Only (S)-ketone was recognized by the enzyme as a substrate and reduction of the ketone proceeded... 

Other biocatalysts were also used to perform the dynamic kinetic resolution through reduction. For example, Thermoanaerobium brockii reduced the aldehyde with a moderate enantioselectivity [30b,c], and Candida humicola was found, as a result of screening from 107 microorganisms, to give the (Jl)-alcohol with 98.2% ee when ester group was methyl [30dj. 

Biooxidative deracemization of racemic sec-alcohols to single enantiomers [47,48] is complementary to combined metal-assisted lipase-mediated strategies [49,50]. In general, deracemization can be realized by either an enantioconvergent, a dynamic kinetic resolution, or a stereoinversion process. The latter concept is particularly appealing, as only half of the substrate needs to be converted, as the remaining half already represents the product with correct stereochemistry. 

Owing to the fully reversible equilibrium nature of the aldol addition process, enzymes with low diastereoselectivity will typically lead to a thermodynamically controlled mixture of erythro/threo-isomers that are difficult to separate. The thermodynamic origin of poor threo/erythro selectivity has most recently been turned to an asset by the design of a diastereoselective dynamic kinetic resolution process by coupling of L-ThrA and a diastereoselective L-tyrosine decarboxylase (Figure 10.47)... 

Figure 10.47 Dynamic kinetic resolution ofThrA generated diastereomers by enantioselective decarboxylation (a).

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