Identification of pig liver esterase variants by tandem mass spectroscopy analysis and their characterization

Pig liver esterase (PLE) is probably the most important carboxyl esterase in organic synthesis and is commercially obtained by extraction of the animal tissue. However, problems occur in its application due to the presence of several isoenzymes (α-, β- and γ-PLE). The functional expression of the γ-isoenzyme was already shown and differences in the enantioselectivity compared to the commercial preparations were confirmed. The amino acid and nucleotide sequences of the α- and β-PLE are still unknown. In this work, putative sequences of the α-isoenzyme were identified from a commercial PLE preparation by 2D gel electrophoresis, digestion with proteases and analysis using Matrix-assisted laser desorption/ionization–time of flight (TOF) and electrospray ionisation quadrupole–TOF mass spectrometry. Based on these results, three amino acid exchanges were introduced into the gene encoding γ-rPLE by site-directed mutagenesis, and the proteins were expressed in E. coli Origami (DE3). The produced PLE mutants were characterised with respect to their substrate specificity and enantioselectivity. No significant differences in the activity towards methyl butyrate were found, but several variants showed substantially enhanced enantioselectivity in the resolution of (R,S)-1-phenyl-2-butyl acetate with E = 100 for the best mutant V236P/A237G.     

Highly selective synthesis of 1,3-oleoyl-2-palmitoylglycerol by lipase catalysis.

1,3-Oleoyl-2-palmitoylglycerol (OPO), an important structured triglyceride in infant nutrition, was synthesized by a two-step process in high yields and purity using sn1,3-regiospecific lipases. In the first step, tripalmitin (TP) was subjected to an alcoholysis reaction in an organic solvent catalyzed by sn1,3-regiospecific lipases yielding the corresponding 2-monopalmitin (2-MP). The 2-MP was isolated in up to 85% yield and >95% purity by crystallization and esterified in the second step with oleic acid using the same lipases to form the structured triglyceride OPO in up to 78% yield containing 96% palmitic acid in the sn2-position. Water activity, solvent, as well as carrier for lipase immobilization strongly influenced the yield and purity of products in both steps. The best results were achieved with lipases from Rhizomucor miehei and Rhizopus delemar immobilized on EP 100 and equilibrated to a water activity of 0.43. Special emphasis was given to develop this process in solvents that are allowed to be used in foodstuffs and to perform the second step in a solvent-free system.     

Studies on the enantioselectivity in the lipase-catalyzed synthesis of monoacylglycerols from isopropylidene glycerol

Summary The regioselective lipase-catalyzed acylation of isopropylidene glycerol using different vinyl esters as acyl donors in toluene was studied. Reaction progress and enantioselectivity were monitored by gas chromatography using a permethylated -cyclodextrin phase. All vinyl esters were completely converted after 20 to 24 h and it was found that the S-enantiomer reacted faster. Lower enantiomeric excess were found using e. g. vinyl palmitate (18 %ee) compared to e. g. vinyl butyrate (42 %ee) with crude lipase from Pseudomonas cepacia. Immobilization using the sol-gel method resulted in higher remaining activities (up to 69%) and increased enantioselectivity E (up to 8.5).     

High-throughput assays for lipases and esterases

In the past few years a considerable number of high-throughput screening (HTS) systems have been developed, especially for lipases and esterases. In this review, a range of HTS methods for the directed evolution of these hydrolases are covered. This includes spectrophotometric and fluorimetric formats as well as other approaches to allow for fast, efficient and reliable identification of desired enzyme variants within large mutant libraries. In addition, methods for library creation and application of lipases and esterases are briefly covered.     

Efficient water removal in lipase-catalyzed esterifications using a low-boiling-point azeotrope

High conversions in lipase-catalyzed syntheses of esters from free acyl donors and an alcohol requires efficient removal of water preferentially at temperatures compatible to enzyme activity. Using a lipase B from Candida antarctica (CAL-B)-mediated synthesis of sugar fatty-acid esters, we show that a mixture of ethyl methylketone (EMK) and hexane (best ratio: 4:1, vo/vo) allows efficient removal of water generated during esterification. Azeotropic distillation of the solvent mixture (composition: 26% EMK, 55% hexane, 19% water) takes place at 59 degrees C, which closely matches the optimum temperature reported for CAL-B. Water is then removed from the azeotrope by membrane vapor permeation. In case of glucose stearate, 93% yield was achieved after 48 h using an equimolar ratio of glucose and stearic acid. CAL-B could be reused for seven reaction cycles, with 86% residual activity after 14 d total reaction time at 59 degrees C. A decrease in fatty-acid chain length as well as increasing temperatures (75 degrees C) resulted in lower conversions. In addition, immobilization of CAL-B on a magnetic polypropylene carrier (EP 100) facilitated separation of the biocatalyst.     

Methods to increase enantioselectivity of lipases and esterases

Lipases and esterases are frequently used in the synthesis of optically pure compounds; however, natural enzymes do not always show sufficiently high enantioselectivity. Variation of the structure of the substrates, modification of the reaction system or protein engineering (e.g. the expression of pure enzymes, rational design or directed evolution) are strategies that can be employed to improve the distinction between two enantiomers or enantiotopic groups.     

Protein engineering of a thermostable polyol dehydrogenase

The polyol dehydrogenase PDH-11300 from Deinococcus geothermalis was cloned, functionally expressed in Escherichia coli and biochemically characterized. The enzyme showed the highest activity in the oxidation of xylitol and 1,2-hexanediol and had an optimum temperature of 45°C. The enzyme exhibited a T(50)(60)-value of 48.3°C. The T(50)(60) is the temperature where 50% of the initial activity remains after incubation for 1h. In order to elucidate the structural reasons contributing to thermostability, the substrate-binding loop of PDH-11300 was substituted by the loop-region of a homolog enzyme, the galactitol dehydrogenase from Rhodobacter sphaeroides (PDH-158), resulting in a chimeric enzyme (PDH-loop). The substrate scope of this chimera basically represented the average of both wild-type enzymes, but surprisingly the T(50)(60) was noticeably increased by 7°C up to 55.3°C. Further mutations in the active site led to identification of residues crucial for enzyme activity. The cofactor specificity was successfully altered from NADH to NADPH by an Asp55Asn mutation, which is located at the NAD(+) binding cleft, without influencing the catalytic properties of the dehydrogenase.     

Improved thermostability of a Bacillus subtilis esterase by domain exchange

A moderately thermostable esterase from Geobacillus stearothermophilus (BsteE) and its homolog from Bacillus subtilis (BsubE) show a high structural similarity with more than 95 % homology and 74 % amino acid identity. Interestingly, their thermal stability differs significantly by 30 °C in their melting temperature. In order to identify the positions that are responsible for this difference, most of the flexible amino acids assumed to confer instability were found to be in the cap region. For this reason, a 30 amino acid long cap domain fragment containing ten differing positions derived from BsteE was incorporated into the homologous gene encoding for the more labile BsubE by spliced overlap-extension PCR. The melting temperature of the two wild-type esterases and the mutant was evaluated by circular dichroism spectroscopy, while the kinetic parameters and the stability were determined with a photometric assay. The cap domain mutant maintained its activity, with a catalytic efficiency more similar to BsteE, while it exhibited an increase of the melting temperature by 4 °C compared to BsubE. Additional point mutations based on the differences of the parent enzymes gave a further increase of the thermostability up to 11 °C compared to BsubE; however, a significant reduction in activity was observed.     

Scale-up of Baeyer–Villiger monooxygenase-catalyzed synthesis of enantiopure compounds

Several Baeyer–Villiger monooxygenases converting a wide spectrum of substrates have been discovered, cloned, and characterized throughout the last few years. Still, only a few of them are applicable for large-scale conversion predominantly due to their sensitivity towards high substrate and/or product concentrations. The recently cloned and characterized 4-hydroxyacetophenone monooxygenase from Pseudomonas putida JD1 shows excellent enantioselectivity towards 3-phenyl-2-butanone with E?>?100 but is inhibited by concentrations >10 mM of both substrate and product. This obstacle could be circumvented by in situ substrate feed and product removal using a hydrophobic Lewatit® adsorbent resin. Thus, the concentration of 3-phenyl-2-butanone could be increased from 1.4 to >26 mM without significant reduction in conversion.