Subject Lipase

Resolution of Racemic Amines and Amino Acids. Acylases (EC3.5.1.14) are the most commonly used enzymes for the resolution of amino acids. Porcine kidney acylase (PKA) and the fungaly3.spet i//us acylase (AA) are commercially available, inexpensive, and stable. They have broad substrate specificity and hydrolyze a wide spectmm of natural and unnatural A/-acyl amino acids, with exceptionally high enantioselectivity in almost all cases. Moreover, theU enantioselectivity is exceptionally good with most substrates. A general paper on this subject has been pubUshed (106) in which the resolution of over 50 A/-acyl amino acids and analogues is described. Also reported are the stabiUties of the enzymes and the effect of different acyl groups on the rate and selectivity of enzymatic hydrolysis. Some of the substrates that are easily resolved on 10—100 g scale are presented in Figure 4 (106). Lipases are also used for the resolution of A/-acylated amino acids but the rates and optical purities are usually low (107). 

Singapore) was obtained for estimates Vmax and Km of free lipase reaction and and K p and for immobilised lipase reaction. Hanes-Woolf and Simplex methods were used for the evaluation of kinetic parameters owing to their strength in error handling when experimental data are subject to random errors.5... 

The Bacillus subtilis lipase A (BSLA) was the subject of two short directed evolution studies [19,47]. In one case systematic saturation mutagenesis at all of the ISlpositions of BSLA was performed [19]. Using meso-l,4-diacetoxy-2-cyclopentene as the substrate, reversed enantioselectivity of up to 83% ee was observed. In another study synthetic shuffling (Assembly of Designed Oligonucleotides) was tested using BSLA [47]. 

As described above, the temperature effect is useful for enhancing the enantioselectivity however, one problem is the decrease in the reaction rate. For example, although in a lipase AK-catalyzed resolution of solketal, the E value (9 at 30°C, Table 1, entry 1) is increased up to 55 by lowering the temperature to —40°C, 10 times the amount of lipase and 8-fold the reaction time are required as compared with those at 30°C. Thus, the rate of acceleration is an important subject especially to make the low-temperature reaction practical. 

Various cyclic esters have been subjected to hpase-catalyzed ring-opening polymerization. Lipase catalyzed the ring-opening polymerization of 4- to 17-membered non-substituted lactones.In 1993, it was first demonstrated that medium-size lactones, 8-valerolactone (8-VL, six-membered) and e-caprolactone (e-CL, seven-membered), were polymerized by lipases derived from Candida cylindracea, Burkholderia cepacia (lipase BC), Pseudomonas fluorescens (lipase PF), and porcine pancreas (PPL). °... 

The role of reversed micelles in the manufacture of fine chemicals with enzymes also needs to be assessed and analysed. An outstanding example is lipase catalysed interesterification to produce cocoa butter substitute from readily available cheap materials (Luisi, 1985). This example of reversed micelles is sometimes referred to as a colloidal solution of water in organic systems. A number of water insoluble alkaloids, prostanoids, and steroids have been subjected to useful transformations (Martinek et al., 1987). Peptide synthesis has also been conducted. The advantages of two liquid phases are retained to a very great extent the amount of water can be manipulated to gain advantages from an equilibrium viewpoint. 

Four macrolides, 11-undecanolide (12-membered,UDL) [85,86], 12-dodeca-nolide (13-membered,DDL) [86,87], 15-pentadecanolide (16-membered, PDL) [85,86,88,89], and 16-hexadecanolide (17-membered, HDL) [90], were subjected to the lipase-catalyzed polymerization. For the polymerization of DDL, lipases CC, PC, PF, and PPL showed the high catalytic activity and the activity order in the bulk polymerization was as follows lipase PC > lipase PF > lipase CC> PPL. These enzymes were also active for the polymerization of other macrolides. NMR analysis showed that the terminal structure of the polymer was of carboxylic acid at one end and of alcohol at the other terminal. 

The unsaturated amides (RCH=CHCONH2, where R = aryl or heteroaryl) in the presence of sodium acetate and NBS gave 3-bromoazetidin-2-ones 67 in moderate yield, probably by cyclization of 68 <99JCS(P1)2435>. The mesylate 69 cyclized in the presence of base to 70 and, after deprotection, the racemic P-lactam was subjected to lipase-mediated resolution to yield 71 (R = Et, ee 99%) and the amino acid 72 (R = Et, ee 98%) . 

CYCLOHEXEN-l-ONE. Importantly, only 1.6 equivalents of Ag20 are required for efficient coupling. The final preparation in this series illustrates the hydrosilation of racemic 3-butyn-2-ol catalyzed by a phosphine based platinum(O) catalyst. The resultant racemic (E)-vinylsilane is then resolved with a commercially available lipase and subjected to a Johnson ortho ester Claisen rearrangement to afford [3R- AND 3S-]-(4E)-METHYL... 

Hydroperoxides play an important role as oxidants in organic synthesis [56-58]. Although several methods are available for the preparation of racemic hydroperoxides, no convenient method of a broad scope was until recently [59] known for the synthesis of optically active hydroperoxides. Such peroxides have potential as oxidants in the asymmetric oxidation of organic substrates, currently a subject of intensive investigations in synthetic organic chemistry [60, 61]. The application of lipoxygenase [62-65] and lipases [66,67] facilitated the preparation of optically active hydroperoxides by enzymes for the first time. 

There are basically two approaches to the synthesis of enantiomerically pure alcohols (i) kinetic resolution of the racemic alcohol using a hydrolase (lipase, esterase or protease) or (ii) reduction mediated by a ketoreductase (KRED). Both of these processes can be performed as a cascade process. The first approach can be performed as a dynamic kinetic resolution (DKR) by conducting an enzymatic transesterification in the presence of a redox metal [e.g. a Ru(ll) complex] to catalyze in situ racemization of the unreacted alcohol isomer [11] (Scheme 6.1). We shall not discuss this type of process in any detail here since it forms the subject of Chapter 1. 

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. 

Imbalance in the stoichiometry of polycondensation reactions of AA-BB-type monomers can be overcome by changing to heterofunctional AB-type monomers. Indeed, IIMU has been subjected to bulk polycondensation using lipases as catalyst in the presence of 4 A molecular sieves. At 70 °C, CALB showed 84% monomer conversion and a low molecular weight polymer (Mn 1.1 kDa, PDI 1.9). No significant polymerization was observed with other lipases (except R cepacia lipase, 47% conversion, oligomers only) and in reference reactions with thermally deactivated CALB or in the absence of enzyme. Further optimization of the reaction conditions (60wt% CALB, II0°C, 3 days, 4 A molecular sieves) gave a polymer with Mn of 14.8 kDa (PDI 2.3) in 86% yield after precipitation [42]. 

The chemical stability of the amide bond is high. When the surfactant containing an amide bond was subjected to 1 M sodium hydroxide during five days at room temperature, only 5% of the amide surfactant was cleaved. The corresponding experiment performed in 1 M HCl resulted in no hydrolysis. The amide bond was, however, found to be slowly hydrolyzed when lipase from Candida antarctica or peptidase was used as catalyst. Amidase and lipase from Mucor miehei was found to be ineffective. Despite the very high chemical stability, the amide surfactant biodegrades by a similar path in the... 

Classic resolntion has been performed by formation of diastereomeiic salts which could be separated. In a series of synthetic steps and when resolution is one step, it is of utmost importance that the correct chirality is introduced at an early stage. When a racemate is subject to enzyme catalysis, one enantiomer reacts faster than the other and this leads to kinetic resolution (Figure 2.2c). Results of hydrolysis using lipase B from Candida antarctica (CALB) and a range of C-3 secondary butanoates are shown in Table 2.1. 

Other microbial lipases have also been successfully used in anhydrous ionic liquids, e.g., from Alcaligenes sp. (AsL) [54, 58], CaLA, Rhizomucor miehei lipase (RmL), and Thermomyces lanuginosus lipase (TIL) [54]. The lipase from pig pancreas (porcine pancreas lipase, PPL), the only mammalian lipase that has been subjected to ionic liquids, catalyzed transesterificationin[BMIm][NTf2]butnotin[BMIm][PF6]... 

Optically active aziridines have been prepared in high enantiomeric excess by the enzymatic resolution of meso diesters (94AG(E)599). For example, when the me o-bis(acetoxymethyl)aziridine (56) was subjected to enzymatic hydrolysis with lipase Amano P, the aziridine (57) was obtained in 98% ee (90TL6663). 

The literature on the subject is quite large. The present review has been limited to milk lipases, but good reviews on this, other dairy products, milk esterases, and microorganisms are available (International Dairy Federation 1974, 1975, 1980 Shipe et al 1978 Deeth and FitzGerald 1976 Downey 1980A Jensen and Pitas 1976 Shahani et al 1980 Lawrence 1967 Kitchen 1971). 

The incubation of raw skim milk at pH 6.0 and at pH 8.9 for 1 hr at 37 °C in the absence of substrate was subsequently shown to cause a 47% and 40% decrease, respectively, in lipase activity when the milk was later incubated with milk fat. When tributyrin was the substrate the inhibition was even more marked. Although some of the inactivation was due to temperature, the majority of it was attributable to pH exposure. Stadhouders and Mulder (1964) have also demonstrated that milk lipase subjected to incubation at pH 5.0 is almost completely destroyed. 

A number of methods are available for following lipase activity. Although numerous modifications and variations have been introduced, the basic methods are (1) titration of the liberated fatty acids, (2) changes in surface tension, (3) colorimetric determination of the fatty acids, (4) use of gas-liquid chromatography, and (5) use of radioactive substrates. Kuzdzal-Savoie (1980) has reviewed the subject. 

The greatest advantage of the spectrophotometric method is that it is direct and rapid, requires no sample workup, and allows for continuous assays of lipase activity compared to the multiple fixed-time-point analyses incumbent within Basic Protocols 1 and 2. The spectrophotometric method can also be done using very small volumes (as small as 1 ml) and is suitable for following the course of purification (such as in chromatographic fractions) or adaptable to 96-well plates (and subject to automation, if available). Thus, it is the method of choice for screening several samples or preparations for lipase (esterase) activity. 

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