微生物脂肪酶稳定性研究进展

脂肪酶广泛应用于食品、药物、生物燃料、诊断、生物修复、化学品、化妆品、清洁剂、饲料、皮革和生物传感器等工业领域,微生物脂肪酶是商品化脂肪酶的重要来源。高温、酸性、碱性和有机溶剂等恶劣的工业生产环境使得脂肪酶的进一步工业应用受到限制,获取稳定性好的脂肪酶成为打破这一限制的关键环节。本文重点对提高微生物脂肪酶稳定性的策略进行了综述:挖掘极端微生物脂肪酶资源;利用定向进化、理性设计和半理性设计等蛋白质工程策略改造脂肪酶;利用物理吸附、封装、共价结合和交联等酶的固定化技术提高脂肪酶的稳定性;利用物理/化学修饰、表面展示以及多种改良策略相结合提高脂肪酶的稳定性。结合作者前期对酶工程的研究发现,新型酶催化剂的获得应该基于明确的设计思路,结合多种改造方法,基于定向进化-理性设计、定向进化-半理性设计、蛋白质工程-酶的固定化、蛋白质工程-物理/化学修饰、酶的固定化-物理/化学修饰等组合改造,比单一的改造方法具有更高的效率。     

微生物脂肪酶资源挖掘及其催化性能改良策略

脂肪酶催化在食品、医药、化工、能源等领域发挥重要作用.开发新型微生物脂肪酶资源,对脂肪酶进行修饰改良,是脂肪酶催化领域的重要研发内容.极端微生物和不可培养微生物脂肪酶的发掘是获取新型工业催化剂的热点;体外定向进化、杂合酶、表面展示等蛋白质工程等分子生物学技术手段为开发特定性质"新酶"提供了有力工具;生物印迹、pH记忆、定向固定化、交联酶晶体、脂质体包埋等高效物理化学修饰方法拓宽了脂肪酶原有的催化性质.微生物脂肪酶资源挖掘及其改良将推动脂肪酶的生物催化产业快速发展.     

微生物脂肪酶分子改造研究进展

有关脂肪酶分子改造的蛋白质工程研究 ,越来越引起研究人员的兴趣[1 - 4] 。在过去的短短几年中 ,关于如何定向改造蛋白质特定性状的研究有了一些明显的进展。1　脂肪酶简介脂肪酶被广泛用于催化三脂酰甘油酯及其他一些水不溶性酯类的水解、醇解、酯化、转酯化以及酯类逆向合成反应[5] 。它们是一类具有多种催化能力的酶 ,经常还能表现出磷脂酶、溶血磷脂酶、胆固醇酯酶、酰胺水解酶等其他一些酶的活性。目前 ,已有越来越多的各种微生物来源的脂肪酶被应用于洗涤剂、油脂与食品加工、有机合成、表面清洗、皮革与造纸工业等生产实践。虽然各…     

微生物脂肪酶的研究进展

详细综述了脂态酶微生物产生菌的选育、诱变育种及发酵生产技术,对微生物脂肪酶的性质、分离、纯化、固定化技术及应用进行了简要概述     

微生物脂肪酶蛋白质工程*

微生物脂肪酶催化的化学反应具有严格的立体选择性、位点选择性等专一性,催化活性高而副反应少,催化反应不需要辅助因子等特点,因此广泛应用于工农业生产中的诸多领域。利用蛋白质工程技术,提高微生物脂肪酶的特异性、活性和稳定性,对提高微生物脂肪酶制剂产品的市场竞争能力,扩大微生物脂肪酶的应用领域,具有重要的意义。综述了蛋白质工程技术在微生物脂肪酶改性方面的应用现状、存在问题及前景。     

微生物脂肪酶及其应用

自然界中有许多微生物能利用天然油脂和脂肪作为自身生长的碳源,这是由于脂肪酶作用使其分解成能被直接利用的小分子物质,脂肪酶（Ec．3．1．1．3）[1]分解脂肪,催化分解三酸甘油脂,产生脂肪酸、甘油脂和甘油。它们的催化反应如图1。脂肪酸在生物体起有相当重要的生理诈用,脂肪酶的分解产物除供给生物能量外,还是合成磷脂等物质的材料,脂肪酸在动植物组织及多种微生物中普遍存在,其性质多年前就被确定了。早在六十年代我国就开展微生物脂肪酸研究。1969年研制成解脂假丝酵母脂肪酸制剂。但同淀粉酶、蛋白酶相比脂肪酸的工业应用还…     

微生物脂肪酶的固定化及其在非水相催化中的应用研究

论述了应用于非水相酶催化反应的脂肪酶的固定化方法,载体与溶剂对固定化脂肪酶活力的影响,以及非水相中固定化脂肪酶催化反应的形式。     

极端微生物：一种新型的酶资源

极端微生物具有自身独特的特点和代谢产物 ,在食品工业、化工、药用工业和环境生物技术领域都有潜在的应用。一些酶已经得到纯化 ,其基因在宿主中已成功克隆。主要介绍和讨论极端微生物的类型、基因组及极端酶类的生产、分离与应用。     

基于核糖体基因序列快速鉴定产脂肪酶微生物

利用含罗丹明B的橄榄油检测平板从中国各省市油污土壤中分离、筛选产脂肪酶微生物菌株,扩增细菌的核糖体基因16S rDNA序列和真菌的ITS2序列,分析核糖体基因簇DNA,并结合形态学特征从而对产脂肪酶菌株进行分子生物学鉴定.核糖体基因16S rDNA序列分析及系统发育分析表明,分离得到的产脂肪酶细菌分别属于枯草芽孢杆菌(Bacillus subtilis)、产碱假单胞菌(Pseudomonas alcaligenes)、洋葱伯克霍尔德氏(Burkholderia cepacia)、琼氏不动杆菌(Acinetobater jurii)、嗜麦芽窄食单孢菌(Stenotrophomonas maltophilia)和荧光假单胞菌(Pseudomonas sp.);真菌核糖体基因转录间隔区(ITS2)序列及同源性分析表明产脂肪酶真菌分别属于黑曲酶(Aspergillus niger)、白地酶(Galactomyces geotrichum)、解脂耶氏酵母(Yarrowia lipolytica)、丝孢酵母(Trichosporon guehoae)和假丝酵母(Candida sp.).研究结果表明,核糖体基因簇的DNA分析技术为从自然界分离、鉴定产脂肪酶菌种提供了一种快速有效的手段,为产脂肪酶微生物资源开发利用奠定了技术基础.     

脂肪酶的固定化及其性质研究

采用吸附与交联相结合的方法国定化脂肪酶,研究了脂肪酶固定化的工艺条件,并考察了固定化脂肪酶的催化性能和稳定性。试验结果表明,WA20树脂固定化脂肪酶的最适条件是：酶液pH7．0、给酶量300IU／g树脂、固定时间8h,所得固定化脂肪酶的活力约为165IU／g树脂;固定化酶稳定性较高,在冰箱内贮存6个月活力没有下降,操作半衰期约为750h,而未用戌二醛文联的固定化脂肪酶操作半衰期仅约290h;固定化脂肪酶催化橄榄油水解的最适条件是：PH8．0、温度55℃、底物浓度60％（V／V）、搅拌转速500r／m。     

Activity and Stability Studies Of Mucor miehei Lipase Immobilized in Novel Microemulsion-based Organogels

Lipase from Mucor miehei was immobilized in bis-(2-ethylhexyl)sulfosuccinate sodium salt (AOT) as well as lecithin water-in-oil (w/o) microemulsion-based organogels (MBGs) formulated with biopolymers such as agar and hydroxypropylmethyl cellulose (HPMC), respectively. These lipase-containing MBGs prove to be novel solid-phase catalysts for use in organic media. Using these organogels at 25°C, various esterification reactions in non-polar solvents as well as in solvent free systems were possible. Apparent lipase activity was influenced to some extent by the nature and the concentration of biopolymers used. Lipase stability in such MBGs is much higher than that observed in w/o microemulsions. MBGs containing lipase functioned effectively in repeated batch syntheses of fatty esters. Kinetic studies have shown that ester synthesis catalyzed by immobilized lipase occurs via the Ping-Pong bi-bi mechanism in which only inhibition by excess of alcohol has been identified. Values of all kinetic parameters were determined.     

Activity and Stability Studies Of Mucor miehei Lipase Immobilized in Novel Microemulsion-based Organogels

Lipase from Mucor miehei was immobilized in bis-(2-ethylhexyl)sulfosuccinate sodium salt (AOT) as well as lecithin water-in-oil (w/o) microemulsion-based organogels (MBGs) formulated with biopolymers such as agar and hydroxypropylmethyl cellulose (HPMC), respectively. These lipase-containing MBGs prove to be novel solid-phase catalysts for use in organic media. Using these organogels at 25°C, various esterification reactions in non-polar solvents as well as in solvent free systems were possible. Apparent lipase activity was influenced to some extent by the nature and the concentration of biopolymers used. Lipase stability in such MBGs is much higher than that observed in w/o microemulsions. MBGs containing lipase functioned effectively in repeated batch syntheses of fatty esters. Kinetic studies have shown that ester synthesis catalyzed by immobilized lipase occurs via the Ping-Pong bi-bi mechanism in which only inhibition by excess of alcohol has been identified. Values of all kinetic parameters were determined.     

环氧交联剂和氨基载体固定化海洋假丝酵母脂肪酶*

游离酶经过固定化后,稳定性和环境耐受性得到提高,在食品、医药、化工、环境和皮革等领域可以很好的提高酶的利用率并降低生产成本,具有极大的应用潜力。新型交联剂在固定化酶工艺的应用极大推进了固定化酶研究的深入。借助新型交联剂聚乙二醇二缩水甘油醚(PEGDGE),利用氨基载体LX-1000HA固定化海洋假丝酵母脂肪酶,结合单因素和正交试验优化得到交联及固定化条件为:交联温度30℃,交联2h,交联剂浓度0.75%,pH7.0,加酶量800U,载体量0.5g,固定化2h,固定化温度45℃。根据上述最佳固定化工艺,制备得到固定化酶LX-1000HA-PEGDGE-CRL在最适条件下测得酶活达到160.81U/g,约为此前制备的固定化酶LX-1000HA-GA-CRL(由LX-1000HA和戊二醛交联脂肪酶得到)和LX-1000EA-PEGDGE-CRL(由短链氨基载体LX-1000EA和PEGDGE交联脂肪酶得到)酶活的2倍,发现固定化酶LX-1000HA-PEGDGE-CRL的最适反应温度相比于游离酶提高15℃;在70℃的环境中3h后酶活仍存留70%;循环使用6次后残留65%左右的酶活;酸碱耐受性和储存稳定性也表现良好,4℃保存30天后剩余约70%的初始酶活。同时,将制备的固定化酶LX-1000HA-PEGDGE-CRL与游离酶、固定化酶LX-1000HA-GA-CRL、固定化酶LX-1000EA-PEGDGE-CRL进行了比较,发现固定化酶LX-1000HA-PEGDGE-CRL在温度耐受性和重复使用性等方面具有更好的使用效果。     

脂肪酶产生菌分离,鉴定及酶性质的研究

从含油污泥中分离筛选出１７株产脂肪酶菌株,对其中一株进行鉴定,为无花果丝孢酵母（Ｔｒｉｃｈｏｓｐｆｉｇｕｅｒｉａｅ）．研究了该菌的最适产酶条件,并对其部分酶性质进行了研究．     

Cloning,Expression and Characterization of a Lipase Encoding Gene from Human Oral Metagenome

The human oral metagenomic DNA cloned into plasmid pUC19 was used to construct a DNA library in Escherichia coli. Functional screening of 40,000 metagenomic clones led to identification of a clone LIP2 that exhibited halo on tributyrin agar plate. Sequence analysis of LIP2 insert DNA revealed a 939 bp ORF (omlip1) which showed homology to lipase 1 of Acinetobacter junii SH205. The omlip1 ORF was cloned and expressed in E. coli BL21 (DE3) using pET expression system. The recombinant enzyme was purified to homogeneity and the biochemical properties were studied. The purified OMLip1 hydrolyzed p-nitrophenyl esters and triacylglycerol esters of medium and long chain fatty acids, indicating the enzyme is a true lipase. The purified protein exhibited a pH and temperature optima of 7 and 37 °C respectively. The lipase was found to be stable at pH range of 6–7 and at temperatures lower than 40 °C. Importantly, the enzyme activity was unaltered, by the presence or absence of many divalent cations. The metal ion insensitivity of OMLip1offers its potential use in industrial processes.     

Influence of self-assembled monolayer surface chemistry on Candida antarctica lipase B adsorption and specific activity

Immobilization of Candida antarctica B lipase was examined on gold surfaces modified with either methyl- or hydroxyl-terminated self-assembled alkylthiol monolayers (SAMs), representing hydrophobic and hydrophilic surfaces, respectively. Lipase adsorption was monitored gravimetrically using a quartz crystal microbalance. Lipase activity was determined colorimetrically by following p-nitrophenol propionate hydrolysis. Adsorbed lipase topography was examined by atomic force microscopy. The extent of lipase adsorption was nearly identical on either surface (approximately 240 ng cm⁻²), but its specific activity was sixfold higher on the methyl-terminated SAM, showing no activity loss upon immobilization. A uniform, 5.5 nm high, highly packed monolayer of CALB formed on the methyl-terminated SAM, while the adsorbed protein was disordered on the hydroxyl-terminated SAM. Hydrophobic surfaces thus may specifically orient the lipase in a highly active state.     

溶胶凝胶法固定化黑曲霉脂肪酶的性质研究

近年来溶胶-凝胶法固定脂肪酶已成为研究热点。选用TMOS、MTMS、ETMS和PTMS 4种硅烷试剂对黑曲霉脂肪酶进行了固定化研究。固定化的最佳配方为ETMS/TMOS=5：1、水与硅烷试剂分子比为8;固定化脂肪酶的固定率为80.2%、相对活性为136.3%;以乳化橄榄油作为底物,在50℃和pH4.0的条件下,固定化脂肪酶与游离脂肪酶K_m分别为1.899×10^-4M和2.789×10^-4M;最适反应pH均为pH4.0,固定化脂肪酶在pH4.0~pH5.5之间其活性能保持95%以上;固定化脂肪酶最适反应温度为60℃,较游离脂肪酶提高了10℃;固定化脂肪酶的酸碱稳定性和热稳定性较非固定化酶有显著的提高。固定化脂肪酶的使用寿命和保存稳定性良好,使用12次后仍能够保留71.7%活性,在室温避光条件下保存180天后仍可保留79.2%活性。     

Ultrastructure and Lipase Activity of Cotyledon cell During Pod Development in Peanut

A series of significant changes of the ultrastructure and lipase activity of cotyledon cell were found in peanut (Arachis hypogaea) during pod development. In he initial stage of cotyledon development there were many plastids which kept producing starch grain and there were low lipase activity and very few lipid and protein bodies in the cell. In the middle stage of cotyledon development, a great number of larger lipid bodies were seen in the cell and a lot of protein bodies formed in the vacuoles and continued to increase in size. Lipase activity increased in the cytoplasm, endoplasmic reticulum, protein bodies, plasmalemma and intercellular space. In the later stage of cotyledon development, the lipid bodies did not increase in number but became slightly larger. The protein bodies continued to increase both in number and in size. Lipase acttvity was even hegher in the cytoplasm. In the final stage the protein bodies became irregular in shape and some of them tended to disintegrate with their content entered into the space around the lipid bodies. The lipase activity in the cell declined. The results indicated that the lipid body originated in the cytoplasm and the protein body originated in the vacuole; that the accumulation of oil and protein in peanut cotyledon resulted from the formation and development of lipid and protein bodies in the cell, and that the changes of plasmid and lipase activity in the cell played a role in the development of lipid body during the development of cotyledon.     

微生物脂肪酶活性构像的形成及激活过程中的影响因子

微生物脂肪酶是一类具有重要应用价值的生物催化剂。作为一种胞外酶,其活性构像的形成及激活是一个高度复杂而特异性的生理过程。综述了作为微生物脂肪酶的结构成分,参与脂肪酶折叠和激活过程中的各种因子及其作用机制,这些因子包括脂肪酶特异性的折叠酶、脂肪酶激活因子、前序列、钙离子和二硫键等。