菜豆环氧化物水解酶的表达及其催化特性研究

【背景】光学纯环氧化物及邻二醇是一类多功能手性砌块。与化学合成法相比,环氧化物水解酶(EHs)介导的生物转化法因环境友好而成为当前的研究热点。【目的】从菜豆(Phaseolus vulgaris)中克隆一种EH基因并进行原核表达,研究重组酶催化环氧苯乙烷(Styrene oxide,SO)的水解特性。【方法】通过计算机辅助分析EHs的一级结构,推测一种菜豆来源的未知功能蛋白(PvEH4)可能具有EH活性。利用RT-PCR技术,以菜豆总RNA为模板,扩增编码PvEH4的基因pveh4,并实现其在Escherichia coli BL21(DE3)中的表达。利用重组菌E.coli/pveh4全细胞催化SO水解,分析PvEH4的对映选择性和区域选择性。【结果】一级结构分析表明,PvEH4具有α/β折叠型EH特有的保守区域。SDS-PAGE结果显示PvEH4的表观分子量为39.4 kD。PvEH4针对SO的对映选择率(E值)为10.1,区域选择性系数αS和βR分别为99.5%和82.5%。当外消旋SO转化率达到68.1%时,可同时获得99.9%ees的(R)-SO和92.3%eep的(R)-苯乙二醇(Phenyl-1,2-ethanediol,PED),两者的产率分别为31.9%和65.6%。【结论】PvEH4的挖掘不仅增加了植物类EHs的数量,同时也为EHs的蛋白分子改造提供参考。     

Enantioselective total synthesis of altersolanol A and N

The development of the first enantioselective total synthesis of altersolanol N is reported. The decisive step of the synthesis is the enantioselective formation of the tetrahydroanthraquinone nucleus by a [4 + 2]-cycloaddition in high yield and with excellent diastereo- and enantioselectivity (>95:5 dr and 95:5 er). In addition, a demanding selective monoacetylation of the OH group at the C-2 position was achieved: an epoxide ring opening with the participation of a neighbouring acetyl group could be established. The route proved to be an efficient alternative to also access enantiomerically pure altersolanol A.     

The role of conformational flexibility of enzymes in the discrimination between amino acid and ester substrates for the subtilisin-catalyzed reaction in organic solvents

To investigate how the conformational flexibility of subtilisin affects its ability to discriminate between enantiomeric amino acid and ester substrates for the subtilisin-catalyzed reaction in an organic solvent, the flexibility around the active site and the surface of subtilisin was estimated from the mobility of a spin label bound to subtilisin by ESR spectroscopy. Many studies on enzyme flexibility focus on the active site. Both the surface and active site flexibility play an important role in the enantioselectivity enhancement of the enzyme-catalyzed reaction. It was found, however, that the different behavior observed for the enantioselectivity between the amino acid and ester substrates could be correlated with the flexibility around the surface rather than the flexibility at the active site of subtilisin. In other words, for the ester substrates, the greater flexibility around the surface of subtilisin induced by a conformational change resulting from the presence of an additive such as DMSO is essential for the enantioselectivity enhancement. This model is also supported by the Michaelis-Menten kinetic parameters for each enantiomeric substrate. Our findings provide insight into the enantioselectivity enhancement for the resolution of enantiomers for enzyme-catalyzed reactions in organic solvents.     

A cold-active esterase of <Emphasis Type="Italic">Streptomyces coelicolor</Emphasis> A3(2): from genome sequence to enzyme activity

The genome sequence of Streptomyces coelicolor A3(2) contains 51 putative lipase and esterase genes mostly of unknown function. The gene estB (locus SCO 6966) was expressed as a His-tagged protein in E. coli. Esterase B was active at low temperatures exerting its maximum activity at 30°C and retaining more than 25% of its activity at 4°C. The optimum pH was 8–8.5. The enzyme was active against short synthetic p-nitrophenylesters (C₂–C₁₀) with maximum activity towards the acetate ester (C₂). The esterase was tested on 13 series of racemic esters of potential interest for the synthesis of chiral pharmaceutical compounds. 4 of the series were substrates and a modest degree of enantioselectivity was observed (enantiomeric ratios of 1.1–1.9).     

Effect of immobilization support, water activity, and enzyme ionization state on cutinase activity and enantioselectivity in organic media

We studied the reaction between vinyl butyrate and 2-phenyl-1-propanol in acetonitrile catalyzed by Fusarium solani pisi cutinase immobilized on zeolites NaA and NaY and on Accurel PA-6. The choice of 2-phenyl-1-propanol was based on modeling studies that suggested moderate cutinase enantioselectivity towards this substrate. With all the supports, initial rates of transesterification were higher at a water activity (a(w)) of 0.2 than at a(w) = 0.7, and the reverse was true for initial rates of hydrolysis. By providing acid-base control in the medium through the use of solid-state buffers that control the parameter pH-pNa, which we monitored using an organo-soluble chromoionophoric indicator, we were able, in some cases, to completely eliminate dissolved butyric acid. However, none of the buffers used were able to improve the rates of transesterification relative to the blanks (no added buffer) when the enzyme was immobilized at an optimum pH of 8.5. When the enzyme was immobilized at pH 5 and exhibited only marginal activity, however, even a relatively acidic buffer with a pK(a) of 4.3 was able to restore catalytic activity to about 20% of that displayed for a pH of immobilization of 8.5, at otherwise identical conditions. As a(w) was increased from 0.2 to 0.7, rates of transesterification first increased slightly and then decreased. Rates of hydrolysis showed a steady increase in that a(w) range, and so did total initial reaction rates. The presence or absence of the buffers did not impact on the competition between transesterification and hydrolysis, regardless of whether the butyric acid formed remained as such in the reaction medium or was eliminated from the microenvironment of the enzyme through conversion into an insoluble salt. Cutinase enantioselectivity towards 2-phenyl-1-propanol was indeed low and was not affected by differences in immobilization support, enzyme protonation state, or a(w).     

Technical aspects of biocatalysis in non-CO2-based supercritical fluids

The number of biotransformation processes is increasing rapidly. Part of this success is based on the inherent properties of enzymes as chemo-, regio-, and enantioselective catalysts. Supercritical fluids (scF) are superior solvents inheriting adjustable and partly unique physical properties. These can be advantageously combined with biotransformations, as solvent power responds to pressure and temperature changes according to the reaction requirements. Among the scF, supercritical carbon dioxide has undoubtedly gained the highest attention. However, other scF are also recognized to enlarge the possibilities. Among these CH(4), C(2)H(6), C(2)H(4), C(3)H(8), CHF(3), and SF(6) are used as scF for biocatalysis. This review focuses on the use of non-CO(2) based scF for biotransformations. Wherever possible, special emphasis is given on the industrial viability of different biocatalytic processes.     

Engineering of NADPH-dependent aldo-keto reductase from <Emphasis Type="Italic">Penicillium citrinum</Emphasis> by directed evolution to improve thermostability and enantioselectivity

Penicillium citrinum β-keto ester reductase (KER) can catalyze the reduction of methyl 4-bromo-3-oxobutyrate (BAM) to methyl (S)-4-bromo-3-hydroxybutyrate with high optical purity. To improve the thermostability of KER, protein engineering was performed using error-prone polymerase chain reaction-based random mutagenesis. Variants with the highest levels of thermostability contained the single amino acid substitutions L54Q, K245R, and N271D. The engineered L54Q variant of KER retained 62% of its initial activity after heat treatment at 30°C for 6 h, whereas wild-type KER showed only 15% activity. The L54Q substitution also conferred improved enantioselectivity by KER. An Escherichia coli cell biocatalyst that overproduced the L54Q mutant of KER and glucose dehydrogenase as a cofactor regeneration enzyme showed the highest level of BAM reduction in a water/butyl acetate two-phase system.     

Directed evolution of a Baeyer–Villiger monooxygenase to enhance enantioselectivity

The Baeyer-Villiger monooxygenase (BVMO) BmoF1 from Pseudomonas fluorescens DSM 50106 was shown before to enantioselectively oxidize different 4-hydroxy-2-ketones to the corresponding hydroxyalkyl acetates, being the first example of a BVMO-catalyzed kinetic resolution of aliphatic acyclic ketones. However, the wild-type enzyme exhibited only moderate E values (E approximately 55). Thus, the enantioselectivity was enhanced by means of directed evolution and optimization of reaction conditions since it was found that higher E values (E approximately 70 for wild-type BmoF1) could already be obtained when performing biotransformations in shake flasks rather than small tubes. In a first step, random mutations were introduced by error-prone polymerase chain reaction, and BmoF1 mutants (>3,500 clones) were screened for improved activity and enantioselectivity using a microtiter-plate-based screening method. Mutations S136L and L252Q were found to increase conversion compared to wild type, while several mutations (H51L, F225Y, S305C, and E308V) were identified enhancing the enantioselectivity to a varying extent (E approximately 75-90). In a second step, beneficial mutations were recombined by consecutive cycles of QuikChange site-directed mutagenesis resulting in a double mutant (H51L/S136L) showing both improved conversion and enantioselectivity (E approximately 86).     

Effects of solvent, water activity and temperature on lipase and hydroxynitrile lyase enantioselectivity

The influence of the reaction conditions on the enantioselectivity of reactions catalysed by lipases or hydroxynitrile lyases (HNLs) in organic solvents was investigated. The lipases catalysed kinetic resolution of chiral secondary alcohols or chiral carboxylic acids and the HNLs catalysed asymmetric addition of hydrogen cyanide to aldehydes.

The temperature effects on enantioselectivity were studied in detail. From measurements of the enantiomeric ratio (E) at different temperatures the activation parameters ΔΔH^# and ΔΔS^# were determined. In the lipase-catalysed reactions the enthalpic and entropic effects on E always counteracted, while in a few of the HNL-catalysed reactions, ΔΔH^# and ΔΔS^# had opposite signs and therefore the effects cooperated to give high E values (−RTlnE = ΔΔG^# = ΔΔH^# − TΔΔS^#). In all the HNL-catalysed reactions and most of the lipase-catalysed ones, the enantioselectivity increased with decreasing reaction temperature. However, in one of the lipase-catalysed reactions, the enantioselectivity decreased with decreasing temperature. The theoretical background of these observations was discussed.

In the HNL-catalysed reactions, the enantioselectivity increased with increasing water content up to water saturation, while in the lipase-catalysed reactions the opposite trend was found in one case and in the others no significant effect was observed. Solvent mixtures of diisopropylether and hexane were used to obtain solvents with different log P values. The log P value of the solvent did not influence the enantioselectivity in the HNL-catalysed reactions, while the enantioselectivity increased with increasing log P value in two of the lipase-catalysed reactions. The reaction temperature was shown to be a very useful way to influence enzyme selectivity and the effects obtained could be rationalised. The influence of the reaction medium (solvent and water activity) is much more difficult to rationalise and predict.     

Identification and characterization of a highly S-enantioselective halohydrin dehalogenase from Tsukamurella sp. 1534 for kinetic resolution of halohydrins

Halohydrin dehalogenases are remarkable enzymes which possess promiscuous catalytic activity and serve as potential biocatalysts for the synthesis of chiral halohydrins, epoxides and β-substituted alcohols. The enzyme HheC exhibits a highly R enantioselectivity in the processes of dehalogenation of vicinal halohydrins and ring-opening of epoxides, which attracts more attentions in organic synthesis. Recently dozens of novel potential halohydrin dehalogenases have been identified by gene mining, however, most of the characterized enzymes showed low stereoselectivity. In this study, a novel halohydrin dehalogenase of HheA10 from Tsukamurella sp. 1534 has been heterologously expressed, purified and characterized. Substrate spectrum and kinetic resolution studies indicated the HheA10 was a highly S enantioselective enzyme toward several halohydrins, which produced the corresponding epoxides with the ee (enantiomeric excess) and E values up to >99% and >200 respectively. Our results revealed the HheA10 was a promising biocatalyst for the synthesis of enantiopure aromatic halohydrins and epoxides via enzymatic kinetic resolution of racemic halohydrins. What’s more important, the HheA10 as the first individual halohydrin dehalogenase with the highly S enantioselectivity provides a complementary enantioselectivity to the HheC.