黑曲霉F044脂肪酶的分离纯化及酶学性质研究

黑曲霉F044脂肪酶发酵上清液经硫酸铵沉淀、透析、DEAESepharoseFastFlow阴离子交换层析和SephadexG-75凝胶过滤层析得到电泳纯的脂肪酶,纯化倍数为73·71倍,活性回收率为34%。对纯化脂肪酶性质研究表明:该脂肪酶分子量约为35~40kD,水解橄榄油的最适温度和最适pH分别为45℃和7·0,在60℃以下和pH2·0~9·0之间有很好的稳定性。该脂肪酶的水解活性对Ca2 表现明显的依赖性,而Mn2 、Fe2 和Zn2 对脂肪酶则有显著的抑制作用。在最适条件下水解pNPP的Km和Vmax分别为7·37mmol/L和25·91μmol/(min·mg)。其N-端的15个氨基酸序列为Ser(Glu/His)-Val-Ser-Thr-Ser-Thr-Leu-Asp-Glu-Leu-Gln-Leu-Phe-Ala-Gln。     

适于非水相催化用细菌脂肪酶基本性质的研究

对假单胞菌产脂肪酶的基本酶学性质进行了研究．该酶水解油脂时的最适作用ｐＨ为９．０,最适作用温度为４５℃;在ｐＨ７．０～１０．０范围内稳定,在６０℃以下热稳定性良好．Ｋ＋、Ｃａ２＋、Ｍｇ２＋等金属离子对酶有明显的激活作用,而Ｈｇ２＋、Ｃｕ２＋、Ｓｎ２＋等重金属离子却对酶有较强的抑制作用;几种表面活性剂和胆汁盐均使酶发生不同程度的失活．该酶在水解油脂时表现出１,３－位置专一性,且对不同种类和来源的油脂水解作用速率不同     

棘腹蛙消化道脂肪酶的分布及pH和温度对脂肪酶活力的影响

采用聚乙烯醇橄榄油乳化液水解法,测定了棘腹蛙消化道不同部位的脂肪酶活力,研究了pH和温度对脂肪酶活力的影响。结果显示,棘腹蛙消化道不同部位脂肪酶活力依次为回肠>直肠>十二指肠>胃>食道。pH和温度显著影响脂肪酶的活力,二者对脂肪酶活力影响的关系曲线均呈现为单峰型,食道、胃和肠道脂肪酶活力的最适pH值分别为5.0、5.0和7.5,最适温度均为35℃。     

壳聚糖固定化德氏根霉脂肪酶的研究

研究了壳聚糖吸附和戊二醛交联对脂肪酶固定化条件,在室温条件下将0．4g酶粉溶于pH6．0缓冲液中,加入10g壳聚糖,摇匀,再加入浓度为0．6％戊二醛交联6h,得到固定化酶,酶活力回收率约为54．2％。固定化酶的半失活温度比游离酶的高,半失活温度由游离酶的47℃提高到100℃,最适反应温度由40℃上升至80℃,最适pH由6下降到5．5,固定化酶K’m值由游离酶的Km 50mg／mL增加到56mg／mL。该固定化脂肪酶用于酯的合成;在80℃条件下经过10批次连续水解植物油反应,固定化酶的活力仍保持在82．6％以上。     

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.     

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。     

改性壳聚糖固定化脂肪酶的研究

以化学改性后的壳聚糖为载体固定假丝酵母99-125脂肪酶,研究了不同的活化剂对壳聚糖表面羟基基团的活化程度,及以活化后壳聚糖为载体采用不同固定化方法对假丝酵母脂肪酶固定效果的影响。结果表明1-乙基-3-(3-甲基氨基)丙基碳二亚胺可有效的活化壳聚糖表面羟基,活化后的壳聚糖表面氨基与戊二醛偶联后形成的壳聚糖为良好的脂肪酶固定化载体,其固定脂肪酶的水解活力可高达86.8U/g。此外,还对影响固定化进程中的各种因素进行了研究,确定最优条件,比较了固定化前后酶的热稳定性、有机溶剂稳定性及最适反应温度。并考察了该固定化脂肪酶催化合成棕榈酸十六酯的操作稳定性,结果表明,连续反应16批之后棕榈酸十六酯的转化率仍能达到85%以上。     

固液态发酵中橄榄油对Rhizopus chinensis全细胞脂肪酶的影响

主要对华根霉全细胞脂肪酶固态和液态两种发酵过程进行比较,并着重探讨不同培养方式下橄榄油对其合成活力和水解活力的影响。结果表明：液态培养较有利于菌体生长,对脂肪酶的生产也有一定的促进作用。橄榄油的加入不仅有利于菌体生长、提高脂肪酶水解活力,更可使脂肪酶的合成活力显著增加,液态发酵下的效果更为明显。橄榄油在整个发酵过程中可能既作为碳源又是脂肪酶的诱导物。另外,全细胞脂肪酶的水解活力和合成活力在固液态发酵条件下均存在不对应性,表明华根霉可能产性质不同的脂肪酶同功酶。     

固液态发酵中橄榄油对Rhizopus chinensis全细胞脂肪酶的影响*

主要对华根霉全细胞脂肪酶固态和液态两种发酵过程进行比较,并着重探讨不同培养方式下橄榄油对其合成活力和水解活力的影响。结果表明:液态培养较有利于菌体生长,对脂肪酶的生产也有一定的促进作用。橄榄油的加入不仅有利于菌体生长、提高脂肪酶水解活力,更可使脂肪酶的合成活力显著增加,液态发酵下的效果更为明显。橄榄油在整个发酵过程中可能既作为碳源又是脂肪酶的诱导物。另外,全细胞脂肪酶的水解活力和合成活力在固液态发酵条件下均存在不对应性,表明华根霉可能产性质不同的脂肪酶同功酶。     

奶牛瘤胃微生物元基因组文库中脂肪酶的筛选与酶学性质

利用含有三油酸甘油酯的脂肪酶选择性筛选培养基,从奶牛瘤胃微生物元基因组文库15360个克隆中,筛选得到了18个脂肪酶阳性克隆,其插入片段大约为60kb,并且各个克隆的插入片段各不一样。利用p-NPP法对脂肪酶克隆的脂肪酶活性分析,表明均具有大小不等的脂肪酶活性。底物特异性分析表明Lipase6、Lipase7和Lipase8分别对C16底物(对硝基苯棕榈酸酯)、C12底物(对硝基苯月桂酸酯)和C16底物(对硝基苯棕榈酸酯)水解能力最强。Lipase6、Lipase7、Lipase8的脂肪酶最适pH为7.5;Lipase8的脂肪酶活性半衰期随反应温度的升高而缩短,70oC时能达到30min。本研究所筛选的脂肪酶具有不同的底物特异性和较好的热稳定性,这对于工业化生产具有一定的应用潜力。     

Lipase applications in oil hydrolysis with a case study on castor oil: a review

Lipase (triacylglycerol acylhydrolase) is a unique enzyme which can catalyze various types of reactions such as hydrolysis, esterification, alcoholysis etc. In particular, hydrolysis of vegetable oil with lipase as a catalyst is widely studied. Free lipase, lipase immobilized on suitable support, lipase encapsulated in a reverse micelle and lipase immobilized on a suitable membrane to be used in membrane reactor are the most common ways of employing lipase in oil hydrolysis. Castor oil is a unique vegetable oil as it contains high amounts (90%) of a hydroxy monounsaturated fatty acid named ricinoleic acid. This industrially important acid can be obtained by hydrolysis of castor oil. Different conventional hydrolysis processes have certain disadvantages which can be avoided by a lipase-catalyzed process. The degree of hydrolysis varies widely for different lipases depending on the operating range of process variables such as temperature, pH and enzyme loading. Immobilization of lipase on a suitable support can enhance hydrolysis by suppressing thermal inactivation and estolide formation. The presence of metal ions also affects lipase-catalyzed hydrolysis of castor oil. Even a particular ion has different effects on the activity of different lipases. Hydrophobic organic solvents perform better than hydrophilic solvents during the reaction. Sonication considerably increases hydrolysis in case of lipolase. The effects of additives on the same lipase vary with their types. Nonionic surfactants enhance hydrolysis whereas cationic and anionic surfactants decrease it. A single variable optimization method is used to obtain optimum conditions. In order to eliminate its disadvantages, a statistical optimization method is used in recent studies. Statistical optimization shows that interactions between any two of the following pH, enzyme concentration and buffer concentration become significant in presence of a nonionic surfactant named Span 80.     

Lipase from marine strain using cooked sunflower oil waste: production optimization and application for hydrolysis and thermodynamic studies

The marine strain Pseudomonas otitidis was isolated to hydrolyze the cooked sunflower oil (CSO) followed by the production of lipase. The optimum culture conditions for the maximum lipase production were determined using Plackett–Burman design and response surface methodology. The maximum lipase production, 1,980 U/ml was achieved at the optimum culture conditions. After purification, an 8.4-fold purity of lipase with specific activity of 5,647 U/mg protein and molecular mass of 39 kDa was obtained. The purified lipase was stable at pH 5.0–9.0 and temperature 30–80 °C. Ca²⁺ and Triton X-100 showed stimulatory effect on the lipase activity. The purified lipase was highly stable in the non-polar solvents. The functional groups of the lipase were determined by Fourier transform-infrared (FT-IR) spectroscopy. The purified lipase showed higher hydrolytic activity towards CSO over the other cooked oil wastes. About 92.3 % of the CSO hydrolysis was observed by the lipase at the optimum time 3 h, pH 7.5 and temperature 35 °C. The hydrolysis of CSO obeyed pseudo first order rate kinetic model. The thermodynamic properties of the lipase hydrolysis were studied using the classical Van’t Hoff equation. The hydrolysis of CSO was confirmed by FT-IR studies.     

Hydrolysis of rice bran oil using an immobilized lipase from Candida rugosa in isooctane

The kinetics of enzymatic hydrolysis of rice bran oil in isooctane by immobilized Candida rugosa lipase in a batch reactor showed competitive inhibition by isooctane with a dissociation constant, K1, of 0.92 M. Continuous hydrolysis of rice bran oil was performed in recycling, packed bed reactor with 4352 U of immobilized lipase; the optimum recycle ratio was 9 and the operational half-life was 360 h without isooctane but 288 h with 25% (v/v) isooctane in rice bran oil.     

游离脂肪酶催化蓖麻油制备蓖麻油酸

游离脂肪酶与固定化脂肪酶相比具有成本低、反应速率快等优势,是油脂化工中新的研究方向。前期研究表明,游离脂肪酶NS81006能高效催化多种油脂水解,进一步研究其对含独特羟基的绿色石油材料蓖麻油的水解过程,对于促进游离脂肪酶在新能源领域的应用具有重要意义。本文对影响游离脂肪酶NS81006催化蓖麻油水解过程的主要因素,温度、酶用量、水用量和搅拌速率进行了研究和优化,在优化后的条件下48 h水解率可达94.8%,且发现通过离心分离可有效实现NS81006的重复使用,连续回用5个批次,游离脂肪酶仍能有效催化水解反应。而对比高温高压法水解蓖麻油,发现游离脂肪酶NS81006具有明显优势。     

Characteristics of immobilized lipase-catalyzed hydrolysis of olive oil of high concentration in reverse phase system

Candida rugosa lipase immobilized by adsorption on swollen Sephadex LH-20 could almost completely hydrolyze 60% (v/v) olive oil in isooctane. Kinetic analysis of the lipase-catalyzed hydrolysis reaction was found to be possible in this system. Amount of fatty acids produced was linearly proportional to the enzyme concentration of 720 mug/g wet gel. The specific enzyme activity was 217 units/mg protein at 60% (v/v) olive oil concentration. When the initial rate is plotted versus concentration of olive oil, this system did not follow Michaelis-Menten kinetics. Maximum activity was obtained at pH 7, but optimum temperature shifted towards higher one with the increase of olive oil concentration. Among the various chemical compounds tested, Hg(2+) and Fe(2+) inhibited the lipase seriously. As the concentration of olive oil increased, the rate of the hydrolysis also increased, but degree of the hydrolysis was observed to decrease. The supply of water from the inside of the gel to the surface of the gel was the main factor for the control of the rate of hydrolysis in batch hydrolysis. The immobilized lipase was used to hydrolyze olive oil two times. Achievement of chemical equilibrium took a longer time with the addition of water and the degree of hydrolysis decreased in the second consecutive trial. After the second hydrolysis trial, the gels were regenerated in a packed column first by eluting out both residual fatty acids around the gel particles and the accumulated glycerol with ethanol and then with 0.05M phosphate buffer, pH 7. The immobilized lipase on the regenerated gel showed the same hydrolysis activity as the original one.     

Partial purification and characterization of almond seed lipase

A lipase was partially purified from the almond (Amygdalus communis L.) seed by ammonium sulfate fractionation and dialysis. Kinetics of the enzyme activity versus substrate concentration showed typical lipase behavior, with K(m) and V(max) values of 25 mM and 113.63 micromol min(-1) mg(-1) for tributyrin as substrate. All triglycerides were efficiently hydrolyzed by the enzyme. The partially purified almond seed lipase (ASL) was stable in the pH range of 6-9.5, with an optimum pH of 8.5. The enzyme was stable between 20 and 90 degrees C, beyond which it lost activity progressively, and exhibited an optimum temperature for the hydrolysis of soy bean oil at 65 degrees C. Based on the temperature activity data, the activation energy for the hydrolysis of soy bean oil was calculated as -5473.6 cal/mol. Soy bean oil served as good substrate for the enzyme and hydrolytic activity was enhanced by Ca(2+), Fe(2+), Mn(2+), Co(2+), and Ba(2+), but strongly inhibited by Mg(2+), Cu(2+), and Ni(2+). The detergents, sodiumdeoxicholate and Triton X-100 strongly stimulated enzyme activity while CTAB, DTAB, and SDS were inhibitors. Triton X-405 had no effect on lipase activity. The partially purified enzyme retained its activity for more than 6 months at -20 degrees C, beyond which it lost activity progressively.     

卡门柏青霉-PG3脂肪酶的研究

从242株青霉属菌株中筛选出脂肪酶产生菌青霉-PG3。经鉴定,定名为卡门柏青霉(Penicillium camembertii Thom)。卡门柏青霉-PG3在由4％豆饼粉,0.5％糊精,0.75％橄榄油,0.5％K_2HPO_4,0.1％(NH_4)_2SO_4组成的液体培养基中,28℃,振荡培养96小时,发酵液脂肪酶活力(39℃,pH7.0)达60U/ml。PG3脂肪酶以橄榄油为底物,水解反应最适温度为48℃,最适pH为8.0。pH稳定范围6.0—11.0。Cu~(2+),Ca~(2+),Fe~(2+),Pb~(2+)等金属离子对酶活力有抑制作用。PG3脂肪酶对椰子油、菜籽油、亚麻油等油脂的水解率分别达到96％,94％和90％。     

帆布固定化脂肪酶及其性能的研究

研究了用高碘酸钠氧化帆布纤维,使其纤维衍生化成为醛基,与脂肪酶交联进行固定化的过程。通过醛基被交联程度来评价交联过程的优劣。首先对纤维的氧化过程进行了简单优化,进而通过反复交联法与酶蛋白交联。以大豆油和橄榄油水解作为固定化酶的性能评价指标。实验结果表明,通过采用反复交联的方法,可提高载体表面酶蛋白质量分数30％左右。酶活力平均达到4U／cm^2,其对温度、pH的耐受性相比游离酶均有不同程度提高。同时利用油脂在固定化酶过程对酶进行保护,使其对温度、pH等的耐受性进一步增强。在维持较高水解率条件下,可在温和条件下连续反应7批,反应半衰期达140h以上。     

Lipase-mediated hydrolysis of blackcurrant oil

Four commercially available lipases, both free and immobilized, were tested for their ability to catalyze hydrolysis of blackcurrant (Ribes nigrum) oil using two different approaches. The lipase from Mucor miehei was studied free and immobilized in two different ways. The former series of enzymic reactions were performed in tap water at 40 degrees C, but the latter series of enzymic processes were carried out in mixtures of isooctane and phosphate buffer (in a typical 2/1 ratio of the components) at 30 degrees C. These conditions were optimized to increase and/or to maximize the yields of the products, which were priority targets in this study. A rate of hydrolysis and a selective preference of the hydrolytic enzymes towards fatty acids, with a special focus on enrichment of alpha-linolenic acid and/or gamma-linolenic acid, were studied. Higher rates of hydrolysis of the blackcurrant oil in the former series of reactions were observed with the immobilized lipase from Pseudomonas cepacia used as biocatalyst. In the latter approach, the most favorable results of the rate of hydrolysis of the target blackcurrant oil were achieved with the immobilized lipase from Mucor miehei employed as biocatalyst. Only three lipases, selected from a series of lipases tested during this investigation, displayed specificity towards alpha-linolenic acid and gamma-linolenic acid, i.e. the immobilized lipase from P. cepacia, lipase from M. miehei and lipase from P. fluorescens.     

Purification and general properties of a metal-insensitive lipase from Rhizopus japonicus NR 400

Lipase [triacylglycerol lipase, EC 3.1.1.3] has been purified to homogeneity from Rhizopus japonicus NR 400 by chromatography on hydroxylapatite, octyl-Sepharose and Sephacryl S-200. It showed a molecular weight of about 30,000 by SDS-PAGE and a specific activity of 68,900 units/mg protein. The enzyme catalyzed the hydrolysis of tricapryn and tricaprylin rapidly in comparison with other triglycerides. This lipase had an optimum pH of around 5, and albumin enhanced its activity between pH 3 and 8. The composition of fatty acids liberated from linseed oil by the lipase was similar to that in the case of pancreatic lipase. The lipase activity was not affected by the addition of 1 mM metal ions or bile salts. Stimulation of the lipase activity was observed upon addition of albumin to the reaction mixture. Immunotitration experiments were also performed with antibodies raised against the purified lipase.