黑曲霉脂肪酶的耦合固定化及特性

研究了吸附-絮凝耦合的方法固定脂肪酶的工艺条件.结果表明:在33℃下,用0.03mol/L的磷酸二氢钾?氢氧化钠缓冲液控制体系pH为7.0,酶与树脂(质量比1∶8)作用吸附1h后,用0.2mL絮凝剂聚丙烯酰胺(w(PAM)=0.5%)处理,得到活力较高的固定化脂肪酶.固定化酶最适pH9.0,最适温度为45℃,活力为405U/g,酶活回收率可以达到40%.固定化脂肪酶制备简便,可重复使用,稳定性较高.     

PDA/SiO2大孔复合材料固定化荧光假单胞菌脂肪酶

以具有三维骨架结构的大孔聚合物为模板制备SiO_2大孔材料,通过多巴胺在SiO_2大孔材料孔道表面的原位聚合制得聚多巴胺表面功能化修饰的二氧化硅大孔材料(PDA/SiO_2)。应用SEM、EDX、MIP、BET、TG-DTA和FTIR等技术对修饰前后的材料进行表征。以PDA/SiO_2为载体固定荧光假单胞菌脂肪酶(PFL),优化固定化条件并对比游离脂肪酶和固定化脂肪酶的性质。结果表明SiO_2大孔材料具有三维连续贯通的孔道结构,孔径分布在300~500 nm,聚多巴胺修饰后形成聚多巴胺/二氧化硅复合纳米薄膜构筑的大孔材料。在固定化时间为14 h、p H值为8、初始脂肪酶浓度为0.4 mg·m L-1时,固定化效果最佳,酶活回收率达246%。与游离脂肪酶相比,固定化脂肪酶有更宽的温度和p H适用范围、热稳定性显著提高,并展现出良好的储存稳定性和操作稳定性,固定化脂肪酶的Km低于游离脂肪酶的,酶与底物的亲和性较好。     

Burkholderia Cepacia脂肪酶在氨基功能化离子液体修饰的SBA-15上的共价固定

合成了氨基以及氨基功能化离子液体修饰的介孔材料SBA-15(NH₂-SBA和NH₂-IL-SBA), 并以戊二醛为活化剂对NH₂-IL-SBA进行活化处理(CA-NH₂-IL-SBA), 通过元素分析、 N₂吸附-脱附、 X射线衍射、 红外光谱等方法研究了修饰及活化对SBA-15结构的影响. 将所得新型固定化载体用于Burkholderia cepacia脂肪酶(BCL)的吸附固定、 共价交联固定及聚集包被固定. 以三乙酸甘油酯的水解为模型反应, 考察了固定化BCL的酶活、 最适反应条件、 稳定性等酶学性质. 结果表明, 离子液体修饰后的载体保持了原有的孔道结构, 与氨基修饰以及原粉SBA-15吸附固定的BCL(BCL-NH₂-SBA和BCL-SBA-15)相比, 其固定化酶的比活力和稳定性都得到了明显提高, 对温度及低pH的敏感性降低. 其中聚集包被固定的BCL在获得了相对较高酶负载量的同时显示了最好的稳定性, 其热稳定性和重复使用性分别为BCL-SBA-15的4倍和2倍.     

纳米-微米复合孔泡沫陶瓷固定化脂肪酶

考察了泡沫陶瓷的孔径分布和表面性质对脂肪酶固定化的影响.研究表明,泡沫陶瓷的纳米孔孔径分布非常适合脂肪酶的固定化,对固定化酶的催化效率有决定性的影响.经1h的定化,泡沫陶瓷固定化酶的活性达商业化硅藻土固定化酶的1.33倍,体积活力为其2.63倍,蛋白载量为45.36mg/g陶瓷,比活为1215.39U/g,活力回收为41.2%.泡沫陶瓷固定化脂肪酶在有机相乙酸乙酯合成中表现优良,连续使用5次,每次反应3h,乙酸转化率均在93%左右.     

基于聚多巴胺的磁性纳米生物催化剂高效催化二氢杨梅素酰化

脂肪酶是一种三酰基甘油水解酶,目前广泛用于油脂化学、食品、有机合成和生物医药等领域.但是,游离脂肪酶在有机反应体系中容易失活,难以从反应体系中回收,导致其循环利用困难和生产成本增加.因此,需要对游离脂肪酶进行固定化,提高酶的稳定性和重复使用性,使其能够大规模用于工业生产.
　　磁性四氧化三铁纳米粒子(MNPs)具有其超顺磁性和大比表面积等性质,但MNPs需表面修饰才能进一步应用.近年来,仿生矿化法制备的聚多巴胺纳米材料受到人们关注.在仿生矿化过程中,单体多巴胺经自聚合作用后形成聚多巴胺,该反应活性高,能对各类有机和无机纳米材料进行表面修饰.而且,聚多巴胺表层中的活性基团能与含有氨基和巯基的生物大分子发生迈克尔加成或席夫碱反应,从而将生物大分子固定在材料表面.
　　本文利用聚多巴胺表面修饰MNPs,对所得聚多巴胺表面修饰的四氧化三铁纳米粒子(PD-MNPs)进行了结构表征.结果表明, PD-MNPs尺寸在14 nm左右.同时,成功将黑曲霉脂肪酶(ANL)固定在PD-MNPs上,结果显示在pH=8、固定化时间为12 h条件下,酶负载量为138 mg/g,酶活回收率达到83.6%,而且固定化酶的pH稳定性及热稳定性、储藏稳定性都优于游离酶.动力学研究表明,固定化酶Km值(63.2 mmol/L)低于游离酶(74.5 mmol/L),固定化酶的底物亲和性增强.进一步研究了固定化酶和游离酶在乙腈、二甲基亚砜、乙醇和[HMIm]BF4这四种溶剂中的溶剂耐受性,结果显示固定化酶的耐受性均强于游离酶.采用红外光谱对游离酶和固定化酶二级结构的分析表明,游离黑曲霉脂肪酶经固定化后,α-螺旋和β-折叠含量分别增加了0.84%和2.74%,使得固定化后α-螺旋和β-折叠中存在的氢键能够更好地保持酶结构刚性,避免因结构改变而引起酶失活,增强了固定化酶在溶剂中的耐受性.
　　二氢杨梅素是一种具有类黄酮结构的天然产物,具有抗氧化、抗菌、抗肿瘤和保护肝脏等作用,但其脂溶性很差,很难透过细胞膜被人体吸收.本课题组曾首次以乙酸乙烯酯为酰基供体,采用游离脂肪酶生物催化方法成功将二氢杨梅素酰化.本文考察了PD-MNPs固定化脂肪酶在二氢杨梅素酰化反应中的应用.结果表明,与游离酶相比,固定化酶在反应介质二甲基亚砜中的耐受性更强,反应48 h后其催化二氢杨梅素酰化的转化率接近80%,明显好于游离酶(69%).固定化酶催化二氢杨梅素酰化的最适底物摩尔比、温度和酶量分别为10：1(乙酸乙烯酯：二氢杨梅素)、45oC,和40 U.此外,固定化酶在外界磁场作用下能迅速从反应混合物中分离,从而可回收利用,在重复使用10次后,其活性仍保持在初始活性的55%以上,具有良好的工业应用前景.     

基于聚多巴胺的磁性纳米生物催化剂高效催化二氢杨梅素酰化（英文）

脂肪酶是一种三酰基甘油水解酶,目前广泛用于油脂化学、食品、有机合成和生物医药等领域.但是,游离脂肪酶在有机反应体系中容易失活,难以从反应体系中回收,导致其循环利用困难和生产成本增加.因此,需要对游离脂肪酶进行固定化,提高酶的稳定性和重复使用性,使其能够大规模用于工业生产.磁性四氧化三铁纳米粒子(MNPs)具有其超顺磁性和大比表面积等性质,但MNPs需表面修饰才能进一步应用.近年来,仿生矿化法制备的聚多巴胺纳米材料受到人们关注.在仿生矿化过程中,单体多巴胺经自聚合作用后形成聚多巴胺,该反应活性高,能对各类有机和无机纳米材料进行表面修饰.而且,聚多巴胺表层中的活性基团能与含有氨基和巯基的生物大分子发生迈克尔加成或席夫碱反应,从而将生物大分子固定在材料表面.本文利用聚多巴胺表面修饰MNPs,对所得聚多巴胺表面修饰的四氧化三铁纳米粒子(PD-MNPs)进行了结构表征.结果表明,PD-MNPs尺寸在14 nm左右.同时,成功将黑曲霉脂肪酶(ANL)固定在PD-MNPs上,结果显示在pH=8、固定化时间为12 h条件下,酶负载量为138 mg/g,酶活回收率达到83.6%,而且固定化酶的pH稳定性及热稳定性、储藏稳定性都优于游离酶.动力学研究表明,固定化酶Km值(63.2 mmol/L)低于游离酶(74.5 mmol/L),固定化酶的底物亲和性增强.进一步研究了固定化酶和游离酶在乙腈、二甲基亚砜、乙醇和[HMIm]BF_4这四种溶剂中的溶剂耐受性,结果显示固定化酶的耐受性均强于游离酶.采用红外光谱对游离酶和固定化酶二级结构的分析表明,游离黑曲霉脂肪酶经固定化后,α-螺旋和β-折叠含量分别增加了0.84%和2.74%,使得固定化后α-螺旋和β-折叠中存在的氢键能够更好地保持酶结构刚性,避免因结构改变而引起酶失活,增强了固定化酶在溶剂中的耐受性.二氢杨梅素是一种具有类黄酮结构的天然产物,具有抗氧化、抗菌、抗肿瘤和保护肝脏等作用,但其脂溶性很差,很难透过细胞膜被人体吸收.本课题组曾首次以乙酸乙烯酯为酰基供体,采用游离脂肪酶生物催化方法成功将二氢杨梅素酰化.本文考察了PD-MNPs固定化脂肪酶在二氢杨梅素酰化反应中的应用.结果表明,与游离酶相比,固定化酶在反应介质二甲基亚砜中的耐受性更强,反应48 h后其催化二氢杨梅素酰化的转化率接近80%,明显好于游离酶(69%).固定化酶催化二氢杨梅素酰化的最适底物摩尔比、温度和酶量分别为10:1(乙酸乙烯酯:二氢杨梅素)、45 ℃,和40 U.此外,固定化酶在外界磁场作用下能迅速从反应混合物中分离,从而可回收利用,在重复使用10次后,其活性仍保持在初始活性的55%以上,具有良好的工业应用前景.     

固定化脂肪酶活性的X射线微区分析

利用X射线微区分析的方法，对吸附交联法得到的固定化脂肪酶的微观活性进行了分析。结果表明：以合成出的大孔吸附树脂为固定化酶栽体，酶活较高，活性脂肪酶分布较均匀。并得到了固定化脂肪酶的活性定位的最佳条件。     

脂肪酸分子印迹对sol-gel固定化脂肪酶酯化活性和胶体结构的影响

基于sol-gel工艺的生物印迹对提高脂肪酶在非水相体系中的活性,扩大其应用范围具有重要作用.本研究以乙烯基三甲氧基硅烷(VTMOS)和四甲氧基硅烷(TMOS)为前趋体,系统考察了脂肪酸印迹分子对sol-gel脂肪酶固定化率和活性的影响,获得了最优的工艺条件.当VTMOS/TMOS为7∶1时,印迹后脂肪酶的比酶活和总酶活分别达到3311.0μmol/h/mg和2506.9μmol/h/gGel,比未印迹同摩尔比的固定化脂肪酶分别提高了2.06和1.79倍.系统考察了脂肪酸生物印迹效应和胶体结构对固定化酶表观活性的影响.氮气吸附—解吸附分析和扫描电镜观察表明,随着脂肪酸分子的参入,固定化脂肪酶颗粒平均孔径增大,对底物的传质阻力逐渐降低,但比表面积和孔体积的变化并不显著;印迹酶平均颗粒直径明显减小,各有机硅烷单体之间的成键能力减弱.表明脂肪酶活性的增加主要来源于疏水性脂肪酸侧链引起的脂肪酶的界面激活效应(生物印迹效应),同时固定化颗粒孔径的改变增加了底物和酶分子的结合,提高了固定化酶的表观活性.     

聚丙烯酸载体用于青霉素酰化酶的固定

以反应性单体丙烯酸和交联剂二乙烯基苯,以石油醚为致孔剂,通过悬浮聚合制备固定化酶的载体,并用于对青霉素酰化酶的固定。研究了丙烯酸与二乙烯基苯以不同摩尔比对青霉素酰化酶固定活性的影响,以及悬浮聚合时水油相比例的不同所合成的载体对固定化酶性能的影响。当丙烯酸和二乙烯基苯摩尔比为84.2:4时合成的载体固定青霉素酰化酶的酶活为2784U/g,而水油相比为2.75:1（丙烯酸和二乙烯基苯摩洋比为84.2:5）时固定青霉素酰化酶活达到2183U/g。固定青霉素酰化酶可使青霉素转化,得到半合成青霉素的中间体6-氨基青霉烷酸,由此可制成高效、广谱、服用方便的新青霉素。     

大孔阴离子树脂DEAE-E/H固定化氨基酰化酶的研究

以弱碱性大孔阴离子树脂DEAE-E/H为载体固定化氨基酰化酶.通过对影响固定化结果的几个因素,如树脂的离子类型、pH值、温度,以及自由酶液浓度等进行系统研究,得到了适宜的固定化条件:将DEAE-E/H转化为Ac-型;自由酶液浓度120U/ml,pH值6.5;固定化温度为常温.在此条件下制备的固定化氨基酰化酶比酶活可达1200U/g～1500U/g,酶活保留率超过60%.DEAE-E/H作为固定化载体,具有价格低廉,物理性能好,固定化方法简便等特点,具有很好的工业应用前景.     

Synthesis of SBA-15 from low cost silica precursor obtained from sugarcane leaf ash and its application as a support matrix for lipase in biodiesel production

Ordered mesoporous silica material was synthesized from a low-cost precursor, sugarcane leaf ash, was used as a support matrix for lipase for the production of biodiesel. The mesoporous samples were characterized using Fourier transform infra red spectroscopy. The surface topography and morphology of the mesoporous materials were studied using scanning electron microscope. The pore diameter, pore volume, Brunauer Emmett and Teller surface area of the mesoporous material were determined by N₂ gas adsorption technique. Different pore size Santa Barbara Acid-15 (SBA-15) samples were synthesized and their lipase immobilization capacity and specific enzyme activity of immobilization lipase were determined and compared. Lipase from Candida Antarctica immobilized on SBA-15 (C) had shown maximum percentage immobilization and specific enzyme activity. The immobilized lipase mesoporous matrix was used for biodiesel production from crude non-edible Calophyllum inophyllum oil. The percentage yield of fatty acid methyl ester, 97.6 % was obtained under optimized conditions: 100 mg of lipase immobilized on SBA-15, 6:1 methanol to oil molar ratio, the reaction of 2 g C. inophyllum oil with methanol.     

Selection of stabilizing additive for lipase immobilization on controlled pore silica by factorial design

Candida rugosa lipase was covalently immobilized on silanized controlled poresilica (CPS) previously activated with glutaraldehyde in the presence of several additives to improve the performance of the immobilized from in long-term operation. Proteins (albumin and lecithin) and organic molecules (β-cyclodextrin and polyethylene glycol [PEG]-1500) were added during the immobilization procedure, and their effects are reported and compared to the behavior of the immobilized biocatalyst in the absence (lacking) of additive. The selection of the most efficient additive at different lipase loadings (150–450 U/g of dry support) was performed by experimental design. Two 2²full factorial designs with two repetitions at the center point were employed to evaluate the immobilization yield. A better, stabilizing effect was found when small amounts of albumin or PEG-1500, were added simul-taneou sly to the lipase on to the support. The catalytic activity had a maximum (193 U/mg) for lipase loading of 150 U/g of dry support using PEG-1500 as the stabilizing additive. This immobilized system was used to perform esterification reactions under repeated batch cycles (for the synthesis of butyl butyrate as a model). The half-life of the lipase immobilized on CPS in the presence of PEG-150 was found to increase fivefold compared with the control (immobilized lipase on CPS without additive).     

Preparation and characterization of stable chitosan nanofibrous membrane for lipase immobilization

Nanofibrous membrane with a fiber diameter of 80-150 nm was fabricated from mixed chitosan/poly(vinyl alcohol) (PVA) solution by an electrospinning process. Field emission scanning electron microscope and transmission electron microscope were used to characterize the morphology of the nanofibrous membrane. It was found that chitosan nanofibrous membrane with stabilized morphology could be prepared through removing most of PVA from the nascent one with 0.5 M NaOH aqueous solution. This treatment also resulted in an obvious decrease in fiber diameter. The stabilized chitosan nanofibrous membrane was explored as support for enzyme immobilization due to the characteristics of excellent biocompatibility, high surface/volume ratio, and large porosity. Lipase from Candida rugosa was immobilized on the nanofibrous membrane using glutaraldehyde (GA) as coupling reagent. The properties of the immobilized lipase were assayed and compared with the free one. Results showed that, the observed lipase loading on this nanofibrous membrane was up to 63.6 mg/g and the activity retention of the immobilized lipase was 49.8% under the optimum condition. The pH and thermal stabilities of lipase were improved after it was immobilized on the chitosan nanofibrous membrane. In addition, the experimental results of reusability and storage stability indicated that the residual activities of the immobilized lipase were 46% after 10 cycles and 56.2% after 30 days, which were obviously higher than that of the free one.     

Adsorption and activity of lipase from Candida rugosa on the chitosan-modified poly(acrylonitrile-co-maleic acid) membrane surface

Efforts have recently been made to improve the biocompatibility of support surface for enzyme immobilization, which could create a specific microenvironment for the enzymes and thus benefit the enzyme activity. In this work, one natural macromolecule, chitosan, was tethered on the surface of poly(acrylonitrile-co-maleic acid) (PANCMA) membrane to prepare a dual-layer biomimetic support for enzyme immobilization. Lipase from Candida rugosa was immobilized on this dual-layer biomimetic support by adsorption. The properties of the immobilized enzyme were assayed and compared with those of the free one. It was found that the adsorption capacity of lipase on the chitosan-tethered PANCMA membrane increases with the decrease of ionic strength and there is an optimum pH value for the adsorption. The activity retention of the immobilized lipase on the chitosan-tethered membrane by adsorption (54.1%) is higher than that by chemical bonding (44.5%). In comparison with the immobilized lipase by chemical bonding, there is a decrease of the K(m) value and an increase of the V(max) value for the immobilized lipase by adsorption. Additionally, the experimental results of thermal stabilities indicate that the residual activity of the immobilized lipase at 50 degrees C is 38% by adsorption and 65% by chemical bonding.     

Covalent attachment of microbial lipase onto microporous styrene-divinylbenzene copolymer by means of polyglutaraldehyde

A novel method for immobilization of Thermomyces lanuginosus lipase onto polyglutaraldehyde-activated poly(styrene-divinylbenzene) (STY-DVB), which is a hydrophobic microporous support has been successfully developed. The copolymer was prepared by the polymerization of the continuous phase of a high internal phase emulsion (polyHIPE). The concentrated emulsion consists of a mixture of styrene and divinylbenzene containing a suitable surfactant and an initiator as the continuous phase and water as the dispersed phase. Lipase from T. lanuginosus was immobilized covalently with 85% yield on the internal surface of the hydrophobic microporous poly(styrene-divinylbenzene) copolymer and used as a biocatalyst for the transesterification reaction. The immobilized enzyme has been fully active 30 days in storage and retained the activity during the 15 repeated batch reactions. The properties of free and immobilized lipase were studied. The effects of protein concentration, pH, temperature, and time on the immobilization, activity, and stability of the immobilized lipase were also studied. The newly synthesized microporous poly(styrene-divinylbenzene) copolymer constitutes excellent support for lipase. It given rise to high immobilization yield, retains enzymatic activity for 30 days, stable in structure and allows for the immobilization of large amount of protein (11.4mg/g support). Since immobilization is simple yet effective, the newly immobilized lipase could be used in several application including oil hydrolysis, production of modified oils, biodiesel synthesis, and removal of fatty acids from oils.     

Physical and Covalent Immobilization of <Emphasis Type="Italic">Lipase</Emphasis> onto Amine Groups Bearing Thiol-Ene Photocured Coatings

In this study, amine groups containing thiol-ene photocurable coating material for lipase immobilization were prepared. Lipase (EC 3.1.1.3) from Candida rugosa was immobilized onto the photocured coatings by physical adsorption and glutaraldehyde-activated covalent bonding methods, respectively. The catalytic efficiency of the immobilized and free enzymes was determined for the hydrolysis of p-nitrophenyl palmitate and also for the synthesis of p-nitrophenyl linoleate. The storage stability and the reusability of the immobilized enzyme and the effect of temperature and pH on the catalytic activities were also investigated. The optimum pH for free lipase and physically immobilized lipase was determined as 7.0, while it was found as 7.5 for the covalent immobilization. After immobilization, the optimum temperature increased from 37 °C (free lipase) to 50–55 °C. In the end of 15 repeated cycles, covalently bounded enzyme retained 60 and 70 % of its initial activities for hydrolytic and synthetic assays, respectively. While the physically bounded enzyme retained only 56 % of its hydrolytic activity and 67 % of its synthetic activity in the same cycle period. In the case of hydrolysis V _max values slightly decreased after immobilization. For synthetic assay, the V _max value for the covalently immobilized lipase was found as same as free lipase while it decreased dramatically for the physically immobilized lipase. Physically immobilized enzyme was found to be superior over covalent bonding in terms of enzyme loading capacity and optimum temperature and exhibited comparable re-use values and storage stability. Thus, a fast, easy, and less laborious method for lipase immobilization was developed.     

Covalent immobilization of Candida antarctica lipase B on nanopolystyrene and its application to microwave-assisted esterification

Nanopolystyrene was used as a solid support for the covalent immobilization of Candida antarctica lipase B (CalB) using the photoreactive reagent 1-fluoro-2-nitro-4-azido benzene (FNAB) as a coupling reagent. The obtained derivative was then used as a biocatalyst in a microwave assisted esterification experiment. Factors such as contact time, pH, and enzyme concentration were investigated during immobilization. The hydrolytic activity, thermal, and operational stability of immobilized-CalB were determined. The maximum immobilized yield (218 μg/mg support) obtained at pH 6.8 exhibited optimum hydrolytic activity (4.42 × 10³ mU p-nitrophenol/min). The thermal stability of CalB improved significantly when it was immobilized at pH 10, however, the immobilized yield was very low (93.6 μg/mg support). The immobilized-CalB prepared at pH 6.8 and pH 10 retained 50% of its initial activity after incubation periods of 14 and 16 h, respectively, at 60 ℃. The operational stability was investigated for the microwave assisted esterification of oleic acid with methanol. Immobilized-CalB retained 50% of its initial activity after 15 batch cycles in the microwave-assisted esterification. The esterification time was notably reduced under microwave irradiation. The combined use of a biocatalyst and microwave heating is thus an alternative total green synthesis process.     

Immobilization and Properties of Lipase from Candida rugosa on Electrospun Nanofibrous Membranes with Biomimetic Phospholipid Moities

Reported here is a protocol to fabricate a biocatalyst with high enzyme loading and activity retention, from the conjugation of electrospun nanofibrous membrane having biomimetic phospholipid moiety and lipase. To improve the catalytic efficiency and activity of the immobilized enzyme, poly（acrylonitrile-co-2-methacryloyloxyethyl phosphorylcholine）s（PANCMPCs） were, respectively, electrospun into nanofibrous membranes with a mean diameter of 90 nm, as a support for enzyme immobilization. Lipase from Candida rugosa was immobilized on these nanofibrous membranes by adsorption. Properties of immobilized lipase on PANCMPC nanofibrous membranes were compared with those of the lipase immobilized on the polyacrylonitrile（PAN） nanofibrous and sheet membranes, respectively. Effective enzyme loading on the nanofibrous membranes was achieved up to 22.0 mg/g, which was over 10 times that on the sheet membrane. The activity retention of immobilized lipase increased from 56.4% to 76.8% with an increase in phospholipid moiety from 0 to 9.6%（molar fraction） in the nanofibrous membrane. Kinetic parameter Km was also determined for free and immobilized lipase. The Km value of the immobilized lipase on the nanofibrous membrane was obviously lower than that on the sheet membrane. The optimum pH was 7.7 for free lipase, but shifted to 8.3-8.5 for immobilized lipases. The optimum temperature was determined to be 35 ℃ for the free enzyme, but 42-44℃ for the immobilized ones, respectively. In addition, the thermal stability, reusability, and storage stability of the immobilized lipase were obviously improved compared to the free one.     

大尺寸SiO2大孔材料固定化漆酶

以表面固定Cu2+的改性大尺寸SiO2大孔材料作为载体,考察了时间、pH和给酶量对漆酶固定化效果的影响,并对固定化漆酶的活性和稳定性进行了研究。结果表明:5 h时吸附达到平衡,pH为4.5、漆酶与载体比例为5 mg·g-1时固定化效果最好,酶活回收率可达到100.4%;固定化漆酶的最适pH和最适温度较游离漆酶的均有升高且范围变宽,固定化后,漆酶的pH稳定性和热稳定性都得到显著提高;固定化漆酶的K m值略高于游离漆酶的;固定化漆酶具有良好的操作稳定性,与底物反应反复操作10批次后剩余酶活为72.7%。     

Immobilization of Pseudomonas fluorescens Lipase onto Magnetic Nanoparticles for Resolution of 2-Octanol

The lipase from Pseudomonas fluorescens (Lipase AK, AKL) was immobilized onto the magnetic Fe₃O₄ nanoparticles via hydrophobic interaction. Enzyme loading and immobilization yield were determined as 21.4?±?0.5?mg/g and 49.2?±?1.8?%, respectively. The immobilized AKL was successfully used for resolution of 2-octanol with vinyl acetate used as acyl donor. Effects of organic solvent, water activity, substrate ratio, and temperature were investigated. Under the optimum conditions, the preferred isomer for AKL is the (R)-2-octanol and the highest enantioselectivity (E?=?71.5?±?2.2) was obtained with a higher enzyme activity (0.197?±?0.01???mol/mg/min). The results also showed that the immobilized lipase could be easily separated from reaction media by the magnetic steel and remained 89?% of its initial activity as well as the nearly unchanged enantioselectivity after five consecutive cycles, indicating a high stability in practical operation.