Peracetylated β-cyclodextrin as additive in enzymatic reactions: enhanced reaction rate and enantiomeric ratio in lipase-catalyzed transesterifications in organic solvents

Peracetylated β-cyclodextrin has been employed as a macrocyclic additive to enhance the enantiomeric ratio E and reaction rate in Pseudomonas cepacia lipase (PSL)-catalyzed enantioselective transesterification of 1-(2-furyl)ethanol in organic solvents. The beneficial action of the cyclodextrin used as a regulator of lipase was tentatively interpreted as increasing the conformational flexibility of the enzyme and undergoing host–guest complexation with the product, thereby preventing product inhibition and leading to an enhancement of the enantiomeric ratio E and the reaction rate. The effect of the organic solvent on the present cyclodextrin-mediated enzymatic transesterification has been studied.     

Tuning lipase enantioselectivity in organic media using solid-state buffers.

The enantioselectivity exhibited by Candida antarctica lipase B (CALB) in predominantly organic media has been studied for different enzyme protonation states. Alcoholysis of (+/-)-2-phenyl-4-benzyloxazol-5(4H)-one (1) using butan-1-ol as the nucleophile in low-water organic solvents was used as a model reaction. Using either organo-soluble bases or the newly introduced solid-state buffers of known pK(a), the protonation state of the lipase was altered. By choice of the appropriate solid-state buffer or organic base, the enantioselectivity could be selectively tuned. Both Et(3)N and the solid-state buffer pair CAPSO/CAPSO.Na were found to increase the enantioselectivity of the reaction catalyzed by CALB and that of another lipase (Mucor miehei). Significant differences to both the enantioselectivity and catalytic rate were observed, especially under hydrated conditions where byproduct acid was formed.     

Effect of organic solvents on the yield and specificity of cyclodextrins by recombinant cyclodextrin glucanotransferase (CGTase) from Anaerobranca gottschalkii

Cyclodextrin glucanotransferase (CGTase, EC 2.4.1.19) is an enzyme that degrades starch and starch related glucans into cyclodextrins (CDs) by intramolecular transglycosylation reaction. The biochemical activity of recombinant CGTase from Anaerobranca gottschalkii for the yield and product specificity of cyclodextrins was investigated in the presence of organic solvents. Compared with the control of starch bioconversion, addition of various organic solvents generally increased the total CD and product specificity by affecting product inhibition and/or intermolecular transglycosylation reaction. The highest conversion (45 %) of starch to CDs was obtained in the presence of ethanol, while the simultaneous addition of two organic solvents, decanol-ethanol, comparatively showed a reduced total yield of 39 %. Despite this, the highest product ratio of 91 % α-CD, and 64 % β-CD was obtained in the presence of decanol and cyclohexane respectively. The effect of organic solvents on the yield and specificity of CD was attributed mainly to their effect on product inhibition and transglycosylation reaction. Although the use of two organic solvents showed almost a significant increase in total yield of CDs, it resulted in a comparatively lower specific product yield compared to their respective individual effect. Generally, normal enzyme activity was favoured at higher temperature of 65 °C, but the addition of organic solvents, in most cases, was found to decrease the bioconversion. Thus, the preferred optimal condition was reduced to 40 °C, where the maximal conversion of starch to CDs in general and α-CD in particular was achieved.     

Enhancement of Enantioselectivity in the Optical Resolution of Primary Alcohols with Modified Cyclodextrin Colyophilized Lipase

Colyophilization of lipase was carried out with immobilized β‐cyclodextrins (β‐CyD) bearing methyl, acetyl, benzoyl, and nicotinoyl substituents. The colyophilizates enhanced stereoselectivity in the acylation of several alcohols. The enantioselectivity in the acylation of ethyl‐1‐hydroxymethyl‐phenylphosphine oxide using colyophilized lipase with nicotinoyl‐β‐CyD increased approximately threefold (from E=34 to E=113). The amphiphilic character of modified CyDs has been found to influence the enhancement of enantioselectivity.     

Metal ions dramatically enhance the enantioselectivity for lipase-catalysed reactions in organic solvents

We propose a simple and a powerful method to enhance the enantioselectivity for lipase-catalysed transformations in organic solvents by an addition of metal ion-containing water to the reaction mixture. In this paper, various metal ions such as LiCl or MgCl2 are tested to improve the enantioselectivity for the model reactions. The enantioselectivities obtained are dramatically enhanced, the E values of which are about 100-fold as compared with the ordinary conditions without a metal ion, for example, E = 200 by addition of LiCl. Furthermore, lowering the reaction temperature led to an almost perfect enantioselectivity of lipase in the presence of a metal ion, for example, E = 1,300 by addition of LiCl. Also, a mechanism for the drastic enhancement by metal ions is discussed briefly on the basis of the EPR spectroscopic study and the initial rate for each enantiomer of the substrate.     

Highly efficient and enantioselective enzymatic acylation of amines in aqueous medium

A new strategy based on the unique catalytic properties, stability and enantioselectivity of the relatively unknown penicillin acylase from Alcaligenes faecalis has been developed for the effective and enantioselective acylation of amines in aqueous medium. In contrast to lipase-catalyzed acylations in organic solvents, the penicillin acylase-catalyzed acylation of amines in aqueous solution is a rapid and chemoselective process leading to a product which can subsequently be deacylated by the same enzyme, imposing secondary enantiocontrol and leading to effective resolution.     

在非水介质中进行酶促反应的几个重要问题

介绍了在非水介质中酶促反应的最新进展。较深入地讨论了介质性质对酶的催化活性及立体选择性的影响，有机溶剂中必需水含量对酶催化反应的重要性，描述了非缓冲体系中的盐及其它极性添加剂对酶活性的影响，介绍了在非均相的低共熔体系中进行酶促合成肽的研究。     

有机相中固定化脂肪酶催化合成植物甾醇酯

酶法合成植物甾醇酯具有反应条件温和、产物纯度和产量高等优点,但非水相酶催化的活性和稳定性普遍较低.本文以大孔树脂固定化脂肪酶为催化剂,并在催化过程中添加乳糖的类似物,构建了有机相高效合成植物甾醇酯的工艺过程.以酯化率为考察指标,对脂肪酶和反应溶剂进行筛选,对酯化条件进行优化,同时考察了糖的种类及添加量对酶催化性能的影响.结果表明,大孔树脂NKA吸附固定化的褶皱假丝酵母(Candida rugosa)脂肪酶(NKA-CRL)为最适宜的催化剂,以正己烷为反应介质,在酸醇摩尔比为2和添加酶蛋白质量7.5%的海藻糖的条件下,40°C反应10 h,酯化率达到96.6%.连续6次催化后,植物甾醇的酯化率仍维持在85.0%以上.     

有机相酶催化拆分制备(S)-2-氯-1-(2-噻吩)-乙醇

首次在有机相中对酶催化条件下的2-氯-1-(2-噻吩)-乙醇的反应进行了研究. 通过对不同来源酶的筛选, 找到了Novozym 435和Alcaligenes sp两种选择性较好的酶, 它们均对该反应具有较高的选择性和较快的反应速度, 在此基础上进一步通过对溶剂、温度、摇床转速以及酶用量的筛选, 确定了能够有效拆分2-氯-1-(2-噻吩)-乙醇的较佳反应条件. 当温度35 ℃, 酶量10 mg/mL, 反应72.5 h, 产物的ee值为98.5%时收率为48.6%.     

A novel lipase enzyme panel exhibiting superior activity and selectivity over lipase B from Candida antarctica for the kinetic resolution of secondary alcohols

A novel, commercially available lipase enzyme panel performing kinetic bioresolutions of a number of secondary alcohols is reported. The secondary alcohols that have been chosen are known from the literature to be particularly challenging substrates to resolve. Following initial screening, four co-solvents were investigated for each lead enzyme in an effort to assess their tolerance to common organic solvents. The superiority of these novel enzymes over lipase B from Candida antarctica (CALB) has been demonstrated.     

Biothermal Analysis Performed In Organic Solvents

Abstract

A thermal assay probe (enzyme thermistor) was used to study the performance of enzymic analyses by immobilized enzymes in organic solvents and in mixtures of organic solvents and aqueous buffer. It was found that rather small amounts of alcohols (around 5 %, v/v) in the buffer approximately doubled the registered temperature changes for glucose oxidase and catalase, mainly by increasing the total enthalpy change of the reaction. the heat production for peroxidase catalyzed reactions was as much as 45 times higher in toluene compared to buffer. the advantage of increased substrate solubility in organic solvents was demonstrated by operating a lipase column in cyclohexane. All enzymes studied showed good stability in the organic solvents used.     

Immobilization/stabilization of lipase fromCandida rugosa

With the aim of fixing the enzyme to the matrix by multiple covalent linkages, lipase from Candida rugosa (formerly cylindracea) has been insolubilized through its amino groups on Sepharose 6B previously activated with 2,3-epoxy-1-propanol. Two main variables that are known to control the number of bonds formed have been tested: the contact time between enzyme and activated support, and the temperature at which the immobilization reaction is carried out. Studies on activity and stability of the different derivatives prepared showed that higher temperatures and longer contact times lead to insolubilized enzymes that are more resistant to inactivation by temperature and the presence of organic solvents. At 50 degrees C and pH 7.2, the insoluble lipase was found to be 140 times more stable than its soluble counterpart.     

Organic solvent-free, enantio- and diastereoselective, direct Mannich reaction in the presence of water

An organocatalyst-mediated, asymmetric Mannich reaction in the presence of water without using organic solvents has been developed. A highly reactive siloxytetrazole hybrid catalyst has been developed for the reaction of dimethoxyacetaldehyde, while the sodium salt of siloxyproline is an effective catalyst of alpha-imino glyoxylate. Excellent enantioselectivity can be realized, and the usage of organic solvents can be reduced compared to the conventional reactions in organic solvents.     

Lipase-catalysed stereoselective esterifications using gelatin-based hydrogels

A hydrogel stable in an organic solvent has been developed. This pseudo-solid aqueous gel (PAG) consists of only native gelatin and water, and has been used for immobilization of enzymes. A relatively high amount of gelatin is required in order to obtain stable gels. PAGs containing the enzyme Candida antarctica lipase (SP 525) were successfully used in catalysing the esterification of R/S-(±)-2-octanol and hexanoic acid in hexane. The conversions as well as the enantiomeric excess values of the product, R-(−)-2-octyl hexanoate, were high and comparable to those obtained with microemulsion-based gels. The PAGs containing immobilized lipase gave reproducible results and may be re-used several times. The gels are easy to prepare and use, non-toxic and biocompatible. The PAGs retain their integrity in organic solvents and may be used in preparative-scale synthesis of organic compounds.     

Molecular modelling studies of substrate binding to the lipase from Rhizomucor miehei

Lipase enzymes have found increasingly widespread use, especially in biotransformation reactions in organic synthesis. Due to their efficiency and high enantioselectivity, they can be employed in a variety of reactions to carry out asymmetric hydrolyses, esterifications and transesterifications. However, the reasons for their stereospecificity have not been fully correlated with the enzyme structure. Employing molecular modelling techniques and existing experimental data, a transesterification reaction using Rhizomucor miehei lipase was studied. The results indicate that the major controlling factor for this reaction is hydrophobic in nature, providing support for previous literature hypotheses. In addition, computational experiments suggest that the origin of enantioselectivity is the formation of essential hydrogen bonds in and around the catalytic triad of active site residues. Only one enantiomer of the substrate is able to form these hydrogen bonds during the formation of the first tetrahedral transition state.     

Activity and Enantioselectivity of the Hydroxynitrile Lyase MeHNL in Dry Organic Solvents

Water concentration affects both the enantioselectivity and activity of enzymes in dry organic media. Its influence has been investigated using the hydrocyanation of benzaldehyde catalyzed by hydroxynitrile lyase cross‐linked enzyme aggregate (MeHNL‐CLEA) as a model reaction. The enzyme displayed higher enantioselectivity at higher water concentration, thus suggesting a positive effect of enzyme flexibility on selectivity. The activity increased on reducing the solvent water content, but drastic dehydration of the enzyme resulted in a reversible loss of activity.     

底物,水量对脂肪酶不对称拆分萘普生的影响

选择了一种便于底物－产物分离的微水－有机两相体系,将对Ｓ－（＋＿萘普生酯有高度对映体选择性的ＣＣＬ脂肪酶固定于硅藻土上。合成了了一种能提高酶催化反应速度的激活的酯－萘普生氯乙酯。     

Enantioselective enzymatic resolution of racemic alcohols by lipases in green organic solvents

The effects of two eco-friendly solvents, 2-methyltetrahydrofuran (MeTHF) and cyclopentyl methyl ether (CPME), on the enzyme activity and enantioselectivity of Novozym 435, Candida rugosa lipase (CRL), Porcine pancreas lipase (PPL), Lipase AK, Lipase PS, and Lipozyme, a series of commercial lipases, in the enantioselective transesterfications of racemic menthol, racemic sulcatol and racemic α-cyclogeraniol were studied. Vinyl acetate was chosen as the acyl donor and the reactions were carried out at water activity 0.06. The activity of lipases in CPME was similar to that observed in other largely employed organic solvents [toluene and tert-butyl methyl ether (MTBE)], and was slightly lower in MeTHF. However, for most of the lipases tested, the enantioselectivity was higher in the eco-friendly solvents. Lipase AK exhibited a high enantioselectivity (E = 232) for the resolution of racemic menthol but the reaction rate was low. Lipase formulation (the enzyme was frozen and lyophilized in potassium phosphate buffer without and with 5% (w/v) of sucrose, d-mannitol, or methoxy poly(ethylene glycol)) was tested with this lipase in order to improve its activity, which increased up to 4.5 times, compared to the untreated enzyme. CALB was found to be a useful biocatalyst for the resolution of racemic sulcatol, where high activity and enantioselectivity were obtained (E ≥ 1000). For the resolution of the racemic primary alcohol α-cyclogeraniol, most of the lipases tested were active but not enantioselective, except lipase PS which displayed a moderate enantioselectivity (E = 19). The effect of the presence of a low percentage of two ionic liquids (ILs) 1-Butyl-3-methylimidazolium bis(trifluoromethylsulfonyl)imide ([BMIM][TFSI]) (5% (v/v)) and 1-Butyl-3-methylimidazoliumtetrafluoroborate ([BMIM][BF4]) (1% (v/v)) in the medium was also investigated. Only in the case of CRL the ILs slightly increased the enantioselectivity from E = 91 to E = 103 and E = 120 for [BMIM][TFSI] and [BMIM][BF4], respectively. However, in all cases ILs caused a decrease of enzyme activity.     

On the enhanced reactivity and selectivity of triazole formation in molecular flasks. A theoretical rationale

The azide-alkyne cycloaddition assisted by a self-assembled molecular flask developed by Rebek and coworkers (Org. Lett., 2002, 4, 327) has been simulated by means of the ONIOM methodology, thereby evidencing the reliability of this theoretical approach to model such large encapsulated systems. Experimental evidences accounting for this transformation within the supramolecular assembly such as the significant rate enhancement, complete regioselectivity, and product inhibition as the reaction proceeds have been qualitatively disentangled through estimation of the energy barriers and the structural characteristics of the corresponding host-guest complexes.     

Dynamic kinetic resolution of benzoins by lipase-metal combo catalysis

The synthesis of some noncommercial racemic 1,2-diaryl-2-hydroxyethanones (benzoins) is described, optimizing the previously reported methodologies. In a further step, the kinetic resolution of these substrates is reported, obtaining conversions of around 50% and ee(p) higher than 99% in very short reaction times. As enzymatic catalyst, after screening of several enzymes, the lipase TL (from Pseudomonas stutzeri) was the most efficient, working in an organic solvent with a very low log P value, such as THF. Finally, the dynamic-kinetic resolution of different benzoins using a lipase-ruthenium-catalyzed transesterification in organic solvents is described for the first time, obtaining conversions up to 90% maintaining the excellent enantioselectivity in all cases.