Hydrolysis asymmetric

The Japanese firm Tanabe Inc Ltd has been operating, since 1969, the optical resolution of DL-amino acids using aminoacylase. The prindple is based on the asymmetrical hydrolysis of N-acyl-DL-amino add by amino acylase which gives the L-amino add and the unhydrolysed acyl-D-amino add. 

Table 1.1 Influence ofcosolvents on the asymmetric hydrolysis the prochiral diester (1) catalyzed by pig liver esterase. of...

Scheme 1.4 Asymmetric hydrolysis of dihydropyridine diesters influence of solvent on lipase stereochemical preference.

Chiral epoxides and their corresponding vicinal diols are very important intermediates in asymmetric synthesis [163]. Chiral nonracemic epoxides can be obtained through asymmetric epoxidation using either chemical catalysts [164] or enzymes [165-167]. Biocatalytic epoxidations require sophisticated techniques and have thus far found limited application. An alternative approach is the asymmetric hydrolysis of racemic or meso-epoxides using transition-metal catalysts [168] or biocatalysts [169-174]. Epoxide hydrolases (EHs) (EC 3.3.2.3) catalyze the conversion of epoxides to their corresponding vicinal diols. EHs are cofactor-independent enzymes that are almost ubiquitous in nature. They are usually employed as whole cells or crude... 

Dimethylsulfoxide -1.3 OS-phosphate buffer pH 7.1 (1/3) Pseudomonas cepecia lipase Asymmetrical hydrolysis of( + )1 -chloro-2-acetoxy-3-(l-naphthyloxy)-propane 82.3 8... 

Besides fragmentation or rearrangement, the carboxylic acid anions, formed by an enzymatic hydrolysis, can also act as nucleophiles. Kuhn and Tamm used the asymmetric hydrolysis of meso-epoxy diester 8-28 with PLE to synthesize y-lactone... 

The production process for (S)-phenylalanine as an intermediate in aspartame perpetuates the principle of reracemization of the nondesired enantiomer (Figure 4.5) in a hollow fiber/ liquid membrane reactor. Asymmetric hydrolysis of the racemic phenylalanine isopropylester at pH 7.5 leads to enantiopure phenylalanine applying subtilisin Carlsberg. The unconverted enantiomer is continuously extracted via a supported liquid membrane [31] that is immobilized in a microporous membrane into an aqueous solution of pH 3.5. The desired hydrolysis product is charged at high pH and cannot, therefore, be extracted into the acidic solution [32]. 

An alternative to extraction crystallization is used to obtain a desired enantiomer after asymmetric hydrolysis by Evonik Industries. In such a way, L-amino acids for infusion solutions or as intermediates for pharmaceuticals are prepared [35,36]. For example, non-proteinogenic amino acids like L-norvaline or L-norleucine are possible products. The racemic A-acteyl-amino acid is converted by acylase 1 from Aspergillus oryzae to yield the enantiopure L-amino acid, acetic acid and the unconverted substrate (Figure 4.7). The product recovery is achieved by crystallization, benefiting from the low solubility of the product. The product mixture is filtrated by an ultrafiltration membrane and the unconverted acetyl-amino acid is reracemized in a subsequent step. The product yield is 80% and the enantiomeric excess 99.5%. 

The key-step of Mori s synthesis of 12 was pig pancreatic lipase (PPL)-cat-alyzed asymmetric hydrolysis of raeso-diacetate A to give B (Scheme 22) [32]. Purification of B (90.8% ee) afforded pure C, which was converted to 12. 

With a good route to the key meso diol 128 in hand, the authors turned their attention to desymmetrization, using the known asymmetric hydrolysis of meso diacetates by Lipase AK (Scheme 23). The meso diol 128 was first converted to diacetate 140, and then hydrolyzed with Lipase AK to cleave selectively one of the two acetates, producing chiral hydroxyester 141. Oxidation, cleavage of the acetate, and lactonization yielded the (3S,4.R) lactone 129. The corresponding lactol (3S,4 )-130 was found to be the enantiomer of the compound produced in the HLADH synthesis. 

H. Hemmerle, H. J. Gais, Asymmetric Hydrolysis and Esterification Catalyzed by Esterases from Porcine Pancreas in the Synthesis of Both Enantiomers of Cyclopentanoid Building Blocks , Tetrahedron Lett. 1987, 28, 3471-3474. 

Scheme 2.7 Asymmetric hydrolysis of disubstituted malononitrile 14 using a nitrile hydratase.

One of the first fluorescence-based ee assays uses umbelliferone (14) as the built-in fluorophore and works for several different types of enzymatic reactions 70,86). In an initial investigation, the system was used to monitor the hydrolytic kinetic resolution of chiral acetates (e.g., rac-11) (Fig. 8). It is based on a sequence of two coupled enzymatic steps that converts a pair of enantiomeric alcohols formed by the asymmetric hydrolysis under study (e.g., R - and (5)-12) into a fluorescent product (e.g., 14). In the first step, (R)- and (5)-ll are subjected separately to hydrolysis in reactions catalyzed by a mutant enzyme (lipase or esterase). The goal of the assay is to measure the enantioselectivity of this kinetic resolution. The relative amount of R)- and ( S)-12 produced after a given reaction time is a measure of the enantioselectivity and can be ascertained rapidly, but not directly. 

Asymmetric hydrolysis of ( )-menthyl acetate by Rhodotorula mucilaginosa is reported. ... 

Lipases exhibit high catalytic activity in water, an even higher activity in a two-phase system, such as water/water-immiscible organic solvent, and in water-immiscible organic solvents of low water content86-88,90. This allows for the attainment of favorable equilibria in asymmetric hydrolysis and esterification reactions catalyzed by lipases. They are used to their greatest... 

For example, the acetate prepared from l,l,l-trifluoro-2-octanol was transformed into (.R)-l,l,l-trifluoro-2-octanol in 96% when hydrolyzed with lipase MY at 40% conversion. Other, trifluoromethylated chiral secondary alcohols shown in Table 2 were prepared by the same procedure. The corresponding alcohols were converted to their acetate, followed by asymmetric hydrolysis to attain the higher enantiomeric excess [28]. 

Table 3. Effect of acyl group and enzyme towards asymmetric hydrolysis ...

Table 4. Asymmetric hydrolysis of esters from fluoroalkylated benzyl alcohol...

Table 5. Lipase-catalyzed Asymmetric Hydrolysis of Fluorinated Esters...

Based on the recent impressive progress made on asymmetric hydrolysis, the design and bio-transformation of the optically active ethyl 2,2-difluoro-3-hydroxyoctanoate 78 and synthesis of optically active fluorinated [6]-gingerol derivatives are reported [82]. The following criteria were used in the search for a practical route to chiral ethyl 2,2-difluoro-3-hydroxyoctanoate with a high -value (1) the search of an additive to enhance the enantioselectivity of asymmetric hydrolysis by lipases, and (2) the modification of ethyl 2,2-difluoro-... 

Menthyl acetate (136) (+)-Menthyl acetate (137) (->Menthol (138) (+>Menthyl acetate (137) Fig. (26). Asymmetric hydrolysis of ( )-menthyl acetate to obtain pure (-)-menthol... 

An appropriate precursor molecule 13 is accessible by condensation of the three components quinoline 11, the aldehyde 2, and cyanoa-cetamide (3). The stereogenic center at C-20 is introduced in the form of aldehyde 2 very early in the process by an enzyme-catalyzed asymmetric hydrolysis with pig liver esterase. 

Figure 12.10 Asymmetric hydrolysis of nifedipine diesters influence of solvent on stereochemical preferences (Hirose, 1992 Carrea, 2000).

M. Bhupathy, J. L. Leazer J. M. McNamara, D. R. Sidler P. J. Reider, and E. J. J. Grabowski, lipase-catalyzed asymmetric hydrolysis of esters having remote chiral/prochiral centers,/. Org. Chem. 1990, 55, 6252-6259. 

The overall process for this enzymatic resolution is compared with the conventional chemical process in Fig. 14. The enzymatic process can skip several tedious steps which are necessary in chemical resolution and this is a considerable practical advantage. There have been several reports on the application of enzymatic asymmetric hydrolysis to the optical resolution of pantolactone [141, 142], In these cases, esterified substrates, such as O-acetyl or O-formyl pantolactone, and lipases were used as the starting materials and catalysts, respectively. Since the lactonase of F. oxysporum hydrolyzes the intramolecular ester bond of pantolactone, it is not necessary to modify the substrate, pantolactone. This is one of the practical advantages of this enzyme. 

Enantiomerically pure cyclopropanes are a frequent motif in the structure of natural products. Their synthesis is often demanding and many approaches have been made [50, 51]. Porcine pancreatic lipase (PPL) was used for the stereoselective desymmetrization of a cyclopropane dibutanoate (Fig. 2). The asymmetric hydrolysis of the meso compound yielded the corresponding enantiopure alcohol almost quantitatively. The intermediate obtained was successfully applied in the total synthesis of dictyopterenes A and C, sexual pheromones of brown algae [52], and constanolactones (see below) [53]. 

Diols such as the optically active 1,1 -binaphthyl-2-2 -diol (BINOL) have been used as versatile templates and chiral auxiliaries in catalysts employed successfully in asymmetric synthesis. The application of enzymes in the enantioselective access to axially dissymmetric compounds was first reported by Fujimoto and coworkers.83 In aqueous media, the asymmetric hydrolysis of the racemic binaphthyl dibutyrate (the ester) using whole cells from bacteria species afforded the (A)-diol with 96%ee and the unreacted substrate (A)-ester with 94% ee at 50 % conversion. Recently, in non-aqueous media, lipases from Pseudomonas cepacia and Ps. fluorescens have been employed in the enantioselective resolution and desymmetrization of racemic 6,6 -disubstituted BINOL derivatives using vinyl acetate.84 The monoacetate (K)-73 (product) was obtained in 32-44 % chemical yields and 78-96% ee depending on the derivatives used. The unreacted BINOL (S)-72 was obtained in 30-52 % chemical yield and 55-80% ee. 

Figure 7 Preparation of chiral synthon for (3-3-receptor agonist (A) enzymatic resolution of racemic amino acid amide (8) by amidase from M. neoaurum ATCC 25795 (B) enzymatic resolution of racemic amino acid amide (10) by amidase from M. neoaurum ATCC 25795 (C) enzymatic asymmetric hydrolysis of diester (12) to the corresponding (>S)-monoester (13) by pig liver esterase.

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