器壁固定化脂肪酶Pseudomonas cepacia lipase的非水活性与稳定性

许多脂肪酶在有机体系中表现出催化作用,可用于绿色有机合成. 但其催化活性和稳定性明显低于水/油（有机相）界面上的表现. 为了提高脂肪酶在有机反应体系中的活性和稳定性,依据脂肪酶的界面活化机制,以水为酶蛋白构象优化剂、羧甲基纤维素为赋形剂,通过物理吸附的方式,将典型的假单胞菌脂肪酶（Pseudomonas cepacia lipase）固定在锥形瓶的内壁上,形成简易的生物反应器. 为方便检测器壁固定化酶促反应动力学,选择特征吸收为640 nm的生化指示剂2,6-二氯靛酚为反应底物,乙酸乙烯酯为酰化试剂,丙酮为溶剂. 光谱检测表明,催化反应0.5 h后,器壁固定化脂肪酶转化底物的能力是脂肪酶粉的6倍. 在每次催化5 h共10次的循环催化中,器壁固定化脂肪酶的催化活性平均每次仅降低3.2%,而酶粉降低11.8%. 结果表明,该器壁固定化脂肪酶的活性和稳定性相对于酶粉明显提高,这将为通过固定化有效提高脂肪酶的非水催化作用提供重要的参考.     

脂肪酶活力测定研究进展

脂肪酶催化作用发生在油-水界面上,是一种典型的界面酶,因此其活力测定有别于其他的水相酶。如何准确测定酶活力的大小,对于研究该酶的特性及应用具有重要的意义。本文对脂肪酶检测的常用方法进行了综述与评价。     

有机相中脂肪酶催化作用的应用

近年来,由于许多微生物酶在有机相中的催化反应具有高度的立体选择性和区域选择性这一新特性的发现,使生物转化技术获得突破性进展,成为国际上非常热门的一个研究领域,尤以有机相中脂肪酶的研究最为活跃,在有机溶剂中,利用脂肪酶的催化作用已成功地进行了许多生物转化。酶拆分的独特作用是由于它们由卜氨基酸组成,其活性中心构成了一个不对称环境,有利于识别消旋体,但适于拆分的酶应有广泛的底物选择性,其中水解酶是较理想的酶类。脂肪酶（甘油酯水解酶,EC3．1．1．3）是专门在异相系统即在油一水的界面上起催化作用的酶,它对…     

荧光标记脂肪酶的固定化及其稳定性

将标记有荧光探针FITC(异硫氰基荧光素)的脂肪酶固定化,通过测定活性和荧光光谱,探究各种因素对固定化后荧光标记脂肪酶性质的影响,并分析活性、构象和荧光光谱三者之间的联系。研究结果表明:在固定化脂肪酶过程中,聚乙二醇400二丙烯酸酯能形成合理的网格结构,使酶活较高;配体诱导酶的催化构象,使酶活性提高到未诱导酶的2倍以上;配体抽提能使脂肪酶活性中心得到释放从而提高催化活力。固定化脂肪酶的稳定性大大提高,在90℃、强酸强碱下固定化酶仍保有原酶70%、60%以上的活性;用盐酸胍、脲等溶解变性剂浸泡15d后,酶活性仍然可以保持初始活性的70%以上。荧光光谱能较好地反映脂肪酶的活性和构象变化,最适pH和温度下脂肪酶的荧光强度最低,在溶解变性剂中,荧光强度随时间延长而逐渐降低,这表明不同条件下脂肪酶构象经历的去折叠过程不同。     

微生物脂肪酶的结构与功能研究进展

脂肪酶是催化油酯水解的一类酶的总称,在清洁剂、食品、纸浆、化工合成等工业都有广泛的应用.本文对各种来源的微生物脂肪酶的结构、生化性质、底物特异性和界面活化现象等方面进行了综述,并介绍了一些脂肪酶的特殊结构和性质.     

微生物脂酶及其在环境生物技术领域中的应用

脂酶是生物体内脂类物质 (三酰甘油脂 )生物转化过程中不可缺少的催化剂。除其生物学意义外 ,脂酶在食品加工、生物医学、化工及环境保护等众多领域中有着巨大的应用前景。脂酶具有在液相和非液相 (即有机相 )界面间起催化作用的独特性能 ,使其与酯酶不同。脂酶界面激活的概念源自以下事实 ,即脂酶的催化活性通常依赖于底物的聚集状态。可以认为脂酶的激活涉及到酶的活性部位的暴露和结构变化 ,这种变化需要在有水包油液滴存在下通过构象的改变来实现。脂酶的活性与反应体系的表面积有关。最近对几种脂酶结构的研究结果为深入理解其水解活性…     

脱脂棉固定化脂肪酶的非水活性与稳定性

脂肪酶具有非水催化作用,但其非水催化活性和稳定性需进一步提高,这是非水酶学的瓶颈问题之一。理想的策略是模拟脂肪酶的界面活化机制,以大分子代替水,优化、稳定化和有效分散酶蛋白,阻止其在有机相中变性。因此,选用多羟基、比表面积大、惰性、且与酶蛋白能兼容的大分子--脱脂棉纤维,作为固定化载体,以1∶0.9的质量比,通过物理吸附,将假单胞菌脂肪酶(Pseudomonas cepacia lipase)固定在脱脂棉纤维上。在催化己醇与乙酸乙烯酯的转酯反应中,反应1 h,脱脂棉固定化脂肪酶转化底物的能力是酶粉的3.7倍。在每次6 h共6次的循环催化中,固定化酶和酶粉转化底物的能力分别平均每次降低约0.3%和2.4%。表明脱脂棉固定化脂肪酶的非水活性,尤其是稳定性明显提高。这为通过固定化有效提高脂肪酶的非水催化作用,以满足工业应用的需要,提供了一种有效的途径和重要参考。     

微乳液中脂肪酶对扁桃酸乙酯水解反应和α－溴丙酸酯化反应的催化作用

针对脂肪酶作用于相界面和微乳液油水界面膜的特点,首次将柱状假丝酵母脂肪酶(Candida cyclindracea Lipase)加入水包油(o／w)型微乳液及油包水相似文献   

Candida rugosa脂肪酶同工酶的分离及选择固定化

采用“界面亲和层析”,从商品Candida rugosa脂肪酶（CRL）中分离到三个同工酶（CRL-1、CRL-2和CRL-3）,它们在水-有机溶剂双液相体系中催化(R,S)-萘普生甲酯的不对称水解反应,具有不同的立体选择性.分析表明：CRL-1和CRL-2上不同程度地非共价结合有小分子的酸性化合物,阻碍了其活性位点处疏水腔的完全开放;CRL-3上不含有该小分子酸性化合物,活性位点处疏水腔可处于完全开放构象.据此分别将CRL同工酶选择性地固定在不同的载体(GDX101和YWG-NH₂)上.通过简单易行的选择吸附步骤,可同时达到同工酶的分离及固定化目的,提出了一种对结构上相差不大同工酶分离的便利方法.     

Candida rugosa脂肪酶同工酶的分离及选择固定化

采用"界面亲和层析",从商品Candida rugosa脂肪酶(CRL)中分离到三个同工酶(CRL-1、CRL-2和CRL-3),它们在水-有机溶剂双液相体系中催化(R,S)-萘普生甲酯的不对称水解反应,具有不同的立体选择性.分析表明:CRL-1和CRL-2上不同程度地非共价结合有小分子的酸性化合物,阻碍了其活性位点处疏水腔的完全开放;CRL-3上不含有该小分子酸性化合物,活性位点处疏水腔可处于完全开放构象.据此分别将CRL同工酶选择性地固定在不同的载体(GDX101和YWG-NH2)上.通过简单易行的选择吸附步骤,可同时达到同工酶的分离及固定化目的,提出了一种对结构上相差不大同工酶分离的便利方法.     

Solvent-induced lid opening in lipases: A molecular dynamics study

In most lipases, a mobile lid covers the substrate binding site. In this closed structure, the lipase is assumed to be inactive. Upon activation of the lipase by contact with a hydrophobic solvent or at a hydrophobic interface, the lid opens. In its open structure, the substrate binding site is accessible and the lipase is active. The molecular mechanism of this interfacial activation was studied for three lipases (from Candida rugosa, Rhizomucor miehei, and Thermomyces lanuginosa) by multiple molecular dynamics simulations for 25 ns without applying restraints or external forces. As initial structures of the simulations, the closed and open structures of the lipases were used. Both the closed and the open structure were simulated in water and in an organic solvent, toluene. In simulations of the closed lipases in water, no conformational transition was observed. However, in three independent simulations of the closed lipases in toluene the lid gradually opened. Thus, pathways of the conformational transitions were investigated and possible kinetic bottlenecks were suggested. The open structures in toluene were stable, but in water the lid of all three lipases moved towards the closed structure and partially unfolded. Thus, in all three lipases opening and closing was driven by the solvent and independent of a bound substrate molecule.     

The atypical lipase B from Candida antarctica is better adapted for organic media than the typical lipase from Thermomyces lanuginosa

Candida antarctica lipase B (CALB) and Thermomyces lanuginosa lipase (TLL) were evaluated as catalysts in different reaction media using hydrolysis of tributyrin as model reaction. In o/w emulsions, the enzymes were used in the free form and for use in monophasic organic media, the lipases were adsorbed on porous polypropylene (Accurel EP-100). In monophasic organic media, the highest specific activity of both lipases was obtained in pure tributyrin at a water activity of >0.5 and at an enzyme loading of 10 mg/g support. With tributyrin emulsified in water, the specific activities were 2780 micromol min(-1) mg(-1) for TLL and 535 micromol min(-1) mg(-1) for CALB. Under optimal conditions in pure tributyrin, CALB expressed 49% of the activity in emulsion (264 micromol min(-1) mg(-1)) while TLL expressed only 9.2% (256 micromol min(-1) mg(-1)) of its activity in emulsion. This large decrease is probably due to the structure of TLL, which is a typical lipase with a large lid domain. Conversion between open and closed conformers of TLL involves large internal movements and catalysis probably requires more protein mobility in TLL than in CALB, which does not have a typical lid region. Furthermore, TLL lost more activity than CALB when the water activity was reduced below 0.5, which could be due to further reduction in protein mobility.     

Unlocking the mystery behind the activation phenomenon of T1 lipase: a molecular dynamics simulations approach

The activation of lipases has been postulated to proceed by interfacial activation, temperature switch activation, or aqueous activation. Recently, based on molecular dynamics (MD) simulation experiments, the T1 lipase activation mechanism was proposed to involve aqueous activation in addition to a double-flap mechanism. Because the open conformation structure is still unavailable, it is difficult to validate the proposed theory unambiguously to understand the behavior of the enzyme. In this study, we try to validate the previous reports and uncover the mystery behind the activation process using structural analysis and MD simulations. To investigate the effects of temperature and environmental conditions on the activation process, MD simulations in different solvent environments (water and water-octane interface) and temperatures (20, 50, 70, 80, and 100°C) were performed. Based on the structural analysis of the lipases in the same family of T1 lipase (I.5 lipase family), we proposed that the lid domain comprises α6 and α7 helices connected by a loop, thus forming a helix-loop-helix motif involved in interfacial activation. Throughout the MD simulations experiments, lid displacements were only observed in the water-octane interface, not in the aqueous environment with respect to the temperature effect, suggesting that the activation process is governed by interfacial activation coupled with temperature switch activation. Examining the activation process in detail revealed that the large structural rearrangement of the lid domain was caused by the interaction between the hydrophobic residues of the lid with octane, a nonpolar solvent, and this conformation was found to be thermodynamically favorable.     

The open lid mediates pancreatic lipase function

Pancreatic triglyceride lipase (PTL) and the homologous pancreatic lipase related protein 2 (PLRP2) provide a unique opportunity to understand the molecular mechanism of lipolysis. They differ in substrate specificity, sensitivity to bile salts, and colipase dependence despite their close amino acid and tertiary structure identity. One important structure, present in both lipases, is the lid which occupies different positions in the inactive and active forms of PTL. We investigated the role of the lid in lipase function by site-specific mutagenesis. By exchanging the lids between PTL and PLRP2, we created two chimeric lipases. Additionally, we made multiple substitution mutations in the PTL lid. PLRP2 with the PTL lid had kinetic properties similar to PLRP2. PTL with the PLRP2 lid was greatly impaired and had no activity at micellar bile salt concentrations even in the presence of colipase. Both chimeras showed interfacial activation suggesting that the closed lid position was maintained. A series of substitution mutations were made in positions Arg257 and Asp258. These mutations demonstrated the importance of these two residues to maintaining the normal activity, triglyceride acyl chain specificity, and colipase interaction of PTL. The preserved interfacial activation in the chimeras, the similar crystal structure of the two lids in the closed position, and the importance of Arg257 and Asp258 in mediating the open conformation of the lid argue that the position of the open lid influences the differences in activity against triglycerides, in sensitivity to bile salts, and in colipase dependence between PTL and PLRP2.     

Open and closed states of Candida antarctica lipase B: protonation and the mechanism of interfacial activation

Lipases (EC 3.1.1.3) are ubiquitous hydrolases for the carboxyl ester bond of water-insoluble substrates, such as triacylglycerols, phospholipids, and other insoluble substrates, acting in aqueous as well as in low-water media, thus being of considerable physiological significance with high interest also for their industrial applications. The hydrolysis reaction follows a two-step mechanism, or “interfacial activation,” with adsorption of the enzyme to a heterogeneous interface and subsequent enhancement of the lipolytic activity. Among lipases, Candida antarctica lipase B (CALB) has never shown any significant interfacial activation, and a closed conformation of CALB has never been reported, leading to the conclusion that its behavior was due to the absence of a lid regulating the access to the active site. The lid open and closed conformations and their protonation states are observed in the crystal structure of CALB at 0.91 Å resolution. Having the open and closed states at atomic resolution allows relating protonation to the conformation, indicating the role of Asp145 and Lys290 in the conformation alteration. The findings explain the lack of interfacial activation of CALB and offer new elements to elucidate this mechanism, with the consequent implications for the catalytic properties and classification of lipases.     

Lipase-catalysed hydrolysis of short-chain substrates in solution and in emulsion: a kinetic study

We have studied the enzymatic hydrolysis of solutions and emulsions of vinyl propionate, vinyl butyrate and tripropionin by lipases of various origin and specificity. Kinetic studies of the hydrolysis of short-chain substrates by microbial triacylglycerol lipases from Rhizopus oryzae, Mucor miehei, Candida rugosa, Candida antarctica A and by (phospho)lipase from guinea-pig pancreas show that these lipolytic enzymes follow the Michaelis–Menten model. Surprisingly, the activity against solutions of tripropionin and vinyl esters ranges from 70% to 90% of that determined against emulsions. In contrast, a non-hyperbolic (sigmoidal) dependence of enzyme activity on ester concentration is found with human pancreatic lipase, triacylglycerol lipase from Humicola lanuginosa (Thermomyces lanuginosa) and partial acylglycerol lipase from Penicillium camembertii and the same substrates. In all cases, no abrupt jump in activity (interfacial activation) is observed at substrate concentration corresponding to the solubility limit of the esters. Maximal lipolytic activity is always obtained in the presence of emulsified ester. Despite progress in the understanding of structure–function of lipases, interpretation of the mode of action of lipases active against solutions of short-chain substrates remains difficult. Actually, it is not known whether these enzymes, which possess a lid structure, are in open or/and closed conformation in the bulk phase and whether the opening of the lid that gives access to the catalytic triad is triggered by interaction of the enzyme molecule with monomeric substrates or/and multimolecular aggregates (micelles) both present in the bulk phase. From the comparison of the behaviour of lipases used in this study which, in some cases, follow the Michaelis–Menten model and, in others, deviate from classical kinetics, it appears that the activity of classical lipases against soluble short-chain vinyl esters and tripropionin depends not only on specific interaction with single substrate molecules at the catalytic site of the enzyme but also on physico-chemical parameters related to the state of association of the substrate dispersed in the aqueous phase. It is assumed that the interaction of lipase with soluble multimolecular aggregates of tripropionin or short-chain vinyl esters or the formation of enzyme–substrate mixed micelles with ester bound to lipase, might represent a crucial step that triggers the structural transition to the open enzyme conformation by displacement of the lid.     

Requirement of lid2 for interfacial activation of a family I.3 lipase with unique two lid structures

A family I.3 lipase from Pseudomonas sp. MIS38 (PML) is characterized by the presence of two lids (lid1 and lid2) that greatly change conformation upon substrate binding. While lid1 represents the commonly known lid in lipases, lid2 is unique to PML and other family I.3 lipases. To clarify the role of lid2 in PML, a lid2 deletion mutant (ΔL2-PML) was constructed by deleting residues 35-64 of PML. ΔL2-PML requires calcium ions for both lipase and esterase activities as does PML, suggesting that it exhibits activity only when lid1 is fully open and anchored by the catalytically essential calcium ion, as does PML. However, when the enzymatic activity was determined using triacetin, the activity of PML exponentially increased as the substrate concentration reached and increased beyond the critical micellar concentration, while that of ΔL2-PML did not. These results indicate that PML undergoes interfacial activation, while ΔL2-PML does not. The activities of ΔL2-PML for long-chain triglycerides significantly decreased while its activity for fatty acid ethyl esters increased, compared with those of PML. Comparison of the tertiary models of ΔL2-PML in a closed and open conformation, which are optimized by molecular dynamics simulation, with the crystal structures of PML suggests that the hydrophobic surface area provided by lid1 and lid2 in an open conformation is considerably decreased by the deletion of lid2. We propose that the hydrophobic surface area provided by these lids is necessary to hold the micellar substrates firmly to the active site and therefore lid2 is required for interfacial activation of PML. DATABASE: Triacylglycerol lipase (EC 3.1.1.3).     

Microbial lipases: at the interface of aqueous and non-aqueous media. A review

In recent times, biotechnological applications of microbial lipases in synthesis of many organic molecules have rapidly increased in non-aqueous media. Microbial lipases are the 'working horses' in biocatalysis and have been extensively studied when their exceptionally high stability in non-aqueous media has been discovered. Stability of lipases in organic solvents makes them commercially feasibile in the enzymatic esterification reactions. Their stability is affected by temperature, reaction medium, water concentration and by the biocatalyst's preparation. An optimization process for ester synthesis from pilot scale to industrial scale in the reaction medium is discussed. The water released during the esterification process can be controlled over a wide range and has a profound effect on the activity of the lipases. Approaches to lipase catalysis like protein engineering, directed evolution and metagenome approach were studied. This review reports the recent development in the field ofnon-aqueous microbial lipase catalysis and factors controlling the esterification/transesterification processes in organic media.     

Role of the lid hydrophobicity pattern in pancreatic lipase activity

Pancreatic lipase is a soluble globular protein that must undergo structural modifications before it can hydrolyze oil droplets coated with bile salts. The binding of colipase and movement of the lipase lid open access to the active site. Mechanisms triggering lid mobility are unclear. The *KNILSQIVDIDGI* fragment of the lid of the human pancreatic lipase is predicted by molecular modeling to be a tilted peptide. Tilted peptides are hydrophobicity motifs involved in membrane fusion and more globally in perturbations of hydrophobic/hydrophilic interfaces. Analysis of this lid fragment predicts no clear consensus of secondary structure that suggests that its structure is not strongly sequence determined and could vary with environment. Point mutations were designed to modify the hydrophobicity profile of the [240-252] fragment and their consequences on the lipase-mediated catalysis were tested. Two mutants, in which the tilted peptide motif was lost, also have poor activity on bile salt-coated oil droplets and cannot be reactivated by colipase. Conversely, one mutant in which a different tilted peptide is created retains colipase dependence. These results suggest that the tilted hydrophobicity pattern of the [240-252] fragment is neither important for colipase binding to lipase, nor for interfacial binding but is important to trigger the maximal catalytic efficiency of lipase in the presence of bile salt.