Lipase stereoselectivity

Rogalska, E., Nury, S., Douchet, 1. and Verger, R. (1995) Lipase stereoselectivity and regioselectivity toward three isomers of dicaprin A kinetic study by the monomolecular film technique. Chirality 7, 505-515... 

Kovac A, Scheib H, Pleiss J et al. (2000) Molecular bases of lipase stereoselectivity. Eur J Lipid Sci Technol 102(l) 61-77... 

Misset O, Gerritse G, Jaeger KE et al. (1994) The structure-function relationship of the lipases from Pseudomonas aeruginosa and Bacillus subtilis. Protein Eng 7(4) 523-529 Murahdhar RV, ChirumanuUa RR, Marchant R et al. (2002) Understanding lipase stereoselectivity. World 1 Microbiol Biotechnol 18 81-97... 

Regioselective hydrolysis of diesters is a challenging problem ia synthetic chemistry because the side reactions always reduce the yield of desired product. Some Upases are well suited to perform this task. Lipase OF-360 (Meito Sangyo) hydrolyzes diester (55) ia 74% theoretical yield and 93% ee (70). Lipase from Pseudomonas cepacia suspended ia diisopropyl ether saturated with water hydrolyzes triester (56) with a remarkable efficiency and regio- and stereoselectivity (71). 

The lipase (PAL) used in these studies is a hydrolase having the usual catalytic triad composed of aspartate, histidine, and serine [42] (Figure 2.6). Stereoselectivity is determined in the first step, which involves the formation of the oxyanion. Unfortunately, X-ray structural characterization of the (S)- and (J )-selective mutants are not available. However, consideration of the crystal structure of the WT lipase [42] is in itself illuminating. Surprisingly, it turned out that many of the mutants have amino acid exchanges remote from the active site [8,22,40]. 

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. 

Enzyme-catalyzed stereoselective hydrolysis allows the preparation of enantio-merically enriched lactones. For instance. Pseudomonas sp. lipase (PSL) was found to be a suitable catalyst for the resolution of 5-undecalactone and 5-dodecalactone (Figure 6.20). Relactonization of the hydroxy acid represents an efficient method for the preparation of both enantiomers of a lactone [67]. 

The lipase-catalyzed DKRs provide only (/ )-products to obtain (5 )-products, we needed a complementary (5 )-stereoselective enzyme. A survey of (5 )-selective enzymes compatible to use in DKR at room temperature revealed that subtilisin is a worthy candidate, but its commercial form was not applicable to DKR due to its low enzyme activity and instability. However, we succeeded in enhancing its activity by treating it with a surfactant before use. At room temperature DKR with subtilisin and ruthenium catalyst 5, trifluoroethyl butanoate was employed as an acylating agent and the (5 )-products were obtained in good yields and high optical purities (Table 3)P... 

Searching for a method of synthesis of enantiopure lamivudine 1, the compound having a monothioacetal stereogenic centre, Rayner et al. investigated a lipase-catalysed hydrolysis of various racemic a-acetoxysulfides 2. They found out that the reaction was both chemoselective (only the acetate group was hydrolysed with no detectable hydrolysis of the other ester moieties) and stereoselective. As a result of the kinetic resolution, enantiomerically enriched unreacted starting compounds were obtained. However, the hydrolysis products 3 were lost due to decomposition." In this way, the product yields could not exceed 50% (Equation 1). The product 2 (R = CH2CH(OEt)2) was finally transformed into lamivudine 1 and its 4-epimer. ... 

Another approach to the synthesis of chiral non-racemic hydroxyalkyl sulfones used enzyme-catalysed kinetic resolution of racemic substrates. In the first attempt. Porcine pancreas lipase was applied to acylate racemic (3, y and 8-hydroxyalkyl sulfones using trichloroethyl butyrate. Although both enantiomers of the products could be obtained, their enantiomeric excesses were only low to moderate. Recently, we have found that a stereoselective acetylation of racemic p-hydroxyalkyl sulfones can be successfully carried out using several lipases, among which CAL-B and lipase PS (AMANO) proved most efficient. Moreover, application of a dynamic kinetic resolution procedure, in which lipase-promoted kinetic resolution was combined with a concomitant ruthenium-catalysed racem-ization of the substrates, gave the corresponding p-acetoxyalkyl sulfones 8 in yields... 

Immobilized PLE was applied to promote stereoselective acetylation of prochiral bis(hydroxymethyl)methyl-phenylgermane 106 (R = Me) with vinyl acetate as a solvent and acyl donor. Later on, the same group reported that each enantiomer of hydridogermane monoacetates 107 (R = H) was obtained either via acetylation of the bis-hydroxy derivative 106 (R = H) or hydrolysis of the corresponding diacetate 108 (R = H). In both methods, porcine pancreatic lipase was used and, obviously, each reaction led to a different enantiomer of 107 (Equation 51). ... 

Ring-opening polymerization of racemic a-methyl-/J-propiolactone using lipase PC catalyst proceeded enantioselectively to produce an optically active (S)-enriched polymer [68]. The highest ee value of the polymer was 0.50. NMR analysis of the product showed that the stereoselectivity during the propagation resulted from the catalyst enantiomorphic-site control. 

The authors then used a modification of their Lipase-AK route to produce the natural enantiomer, as described in detail in the chapter by Kenji Mori in this volume. Instead of using the enzyme to execute a stereoselective monohydrolysis of meso diacetate 140, the enzyme was used to esterify selectively one of the hydroxy groups of meso diol 128, resulting in the antipodal hydroxyester. After oxidation of the free hydroxyl to the acid, and recrystallization of its salt with (JR)-l-naphthylethylamine, the purified acid was then carried through the remaining steps to furnish the chiral pheromone compound (see the chapter by Kenji Mori in this volume). 

E. Rogalska, C. Cudrey, F. Ferrato, R. Verger, Stereoselective Hydrolysis of Triglycerides by Animal and Microbial Lipases , Chirality 1993, 5, 24-30. 

E. Rogalska, S. Ransac, R. Verger, Stereoselectivity of Lipases. II. Stereoselective Hydrolysis of Triglycerides by Gastric and Pancreatic Lipases , J. Biol. Chem. 1990, 265, 20271-20276. 

Enzyme and Nonenzyme Catalysts By nature, enzymes themselves are chiral and they catalyze a variety of chemical reactions with stereoselectivity. These reactions include oxidation, reduction, and hydration. Examples of enzymes are oxidases, dehydrogenases, lipases, and proteases. Metoprolol, an adrenoceptor-blocking drug, is produced using an enzyme-catalyzed method. 

Another method for assaying the activity and stereoselectivity of enzymes at in vitro concentrations is based on surface-enhanced resonance Raman scattering (SERRS) using silver nanoparticles (116). Turnover of a substrate leads to the release of a surface targeting dye, which is detected by SERRS. In a model study, lipase-catalyzed kinetic resolution of a dye-labeled chiral ester was investigated. It is currently unclear how precise the method is when identifying mutants which lead to E values higher than 10. The assay appears to be well suited as a pre-test for activity. 

The beneficial effect of the hydrophobicity of [BMIM]PFg was shown to extend to other enzymes a remarkably enhanced enantioselectivity was observed for lipases AK and Pseudomonas fluorescens for the kinetic resolution of racemic P-chiral hydroxymethanephosphinates (Scheme 31) (278). The ee values of the recovered alcohols and the acetates were about 80% when the enzymatic reactions were conducted in the hydrophobic [BMIMJPFg. In contrast, there was little enantioselectivity (<5%) observed with the enzymes in hydrophilic [BMIM]BF4. The lack of stereoselectivity in [BMIM]BF4 was attributed to the high miscibility of [BMIM]BF4 with water. The relatively hydrophilic ionic liquid is capable of stripping off the essential water from the enzyme surface, leading to insufficient hydration of the enzyme and a consequently strong influence on its performance (279). 

Reduction of a S-aminoketone resulting from the addition of an equivalent of a glycinate anion on ethyl difluoro- or trifluoroacetate is stereoselective and leads to ethyl di- or trifluorothreoninate threo (syn). Release of the acid, performed by saponification, is accompanied by a partial epimerization into an alio compound. However, the amino acids are obtained in enantiopure forms by using a lipase. . It s important to note that (25, 35)-difluorothreonine exhibits activity toward the growth of leukemia cell hnes comparable to 5-fluorouracil. ... 

As mentioned in part 2.1.3 hydrolytic enzymes are the most frequently used enzymes in organic chemistry. There are several reasons for this. Firstly, they are easy to ttse because they do not need cofactors like the oxidoreductases. Secondly, there are a large amormt of hydrolytic enzymes available because of their industrial interest. For instance detergent enzymes comprise proteases, celltrlases, amylases and lipases. Even if hydrolytic enzymes catalyse a chemically simple reaction, many important featirres of catalysis are still contained such as chemo-, regio- and stereoselectivity and specificity. 

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