壳聚糖与丙烯腈接枝共聚物的制备及固定化α-淀粉酶研究

本文以过硫酸钾/亚硫酸氢钠为引发体系,制备了丙烯腈接枝壳聚糖的共聚物,并以 其为载体固定化α-淀粉酶,探讨了固定化酶的最佳制备条件和固定化酶的性质,并与游离 酶、壳聚糖作为载体的固定化α-淀粉酶进行了比较,结果表明,丙烯腈接枝壳聚糖共聚物 是固定化α-淀粉酶的优良载体。     

壳聚糖与丙烯腈接枝共聚物的制备及固定化a—淀粉酶研究

主以过硫酸钾／亚硫酸氢钠为引发体系,制备了丙烯腈接枝壳聚糖的共聚物,并以其载体固定化a-淀粉酶,探讨了固定化酶的最佳制备条件和固定化酶的性质,并与游离酶、壳聚糖作为载体的固定化a-淀粉酶进行了比较,结果表明,丙烯腈接枝壳聚糖共聚物是固定化a-淀粉酶的优良载体。     

次价键力在化学键合法固定辣根过氧化酶过程中的作用机理

将甲基丙烯酸缩水甘油酯(GMA)接枝聚合在微米级硅胶微粒表面,又通过环氧基团的开环反应将乙二胺(EDA)键合在接枝微粒表面,制备了双功能复合载体EDA-PGMA/SiO2,通过共价偶联法实施了辣根过氧化酶(HRP)的固定化.本文重点考察静电相互作用与疏水相互作用两种次价键力在共价键合法固定HRP过程中的作用,探讨作用机理.结果表明,在水介质中,复合载体EDA-PGMA/SiO2表面胺基的质子化作用,使载体微粒的ζ电位在较大的pH范围内保持正值;当介质的pH=8.5,大于HRP的等电点时,酶蛋白与载体之间所产生的强静电相互作用会显著促进HRP的固定化;EDA的键合率在30％附近的载体,静电相互作用对固酶的促进作用最强,固定化酶的偶联率与比活力具有最高值.疏水相互作用对化学法固定辣根过氧化酶也会产生明显的作用,当以接枝微粒PGMA/SiO2为载体时,增大NaCl浓度,可有效促进酶蛋白与载体之间的疏水相互作用,提高固定化酶的偶联率与比活力.     

壳聚糖-精氨酸树脂固定化胰凝乳蛋白酶及其性质

以具柔性亲水手臂的壳聚糖-精氨酸树脂为载体,用戊二醛交联胰凝乳蛋白酶,获得壳聚糖-精氨酸树脂固定化胰凝乳蛋白酶. 最佳固定化条件为:m(酶)∶ m(载体)=20∶ 1 000、戊二醛体积分数为1.0%、pH=5.20、30 ℃交联60 min. 固定化酶活力达850 U/g,Km为1.83 mmol/L,比游离酶增大33.6%,比交联壳聚糖固定化酶低24.0%. 壳聚糖-精氨酸树脂固定化胰凝乳蛋白酶水解时间进程曲线与游离酶基本一致,均在反应30 min达到最大速率,最适温度为70 ℃,比游离酶升高10 ℃;在75 ℃时的半衰期可达6.0 h,比游离酶提高约4.3倍;最适pH值为5.92,比游离酶向酸性偏移2pH单位. 4 ℃贮存半衰期为49 d.     

多酚氧化酶在聚乙烯醇接枝谷氨酸树脂Cu(Ⅱ)配合物上的固定化

研究了固定化酶载体－聚乙烯醇接枝谷氨酸枝脂的合成及树脂络合金属铜离子后对多酚氧化酶的固定化。用红外光谱表征了树脂的结构,用DTA测定了树脂的热行为。考察了固定化酶的特性。结果表明,该树脂与Cu^2 配位后的高分子配合物能较好地对多酚氧化酶固定化,此固定化酶最适pH值为5．59和6．64,能重复多次使用,经5次使用后其活力仍保留20％。固定化酶的热稳定性比游离酶高,而米氏常数基本相同。     

以HPD-750大孔树脂为载体材料固定化果胶酶

HPD-750树脂是中极性大孔吸附树脂,生物相容性好,机械性能稳定,具有较大的比表面积,可用于固定化酶载体材料。本文以HPD-750大孔树脂为载体固定化果胶酶,研究各因素对固定化酶的影响,并采用正交试验对固定化条件进行优化。结果表明,当pH为4.0、固定化温度为45℃、固定化时间为4h、加酶量为0.16g/mL时,固定化酶活力可达5146U/mg。以HPD-750大孔树脂为载体材料制备的固定化酶相较于游离酶具有更好的酸碱稳定性和热稳定性。在循环使用10次后,酶活力依然保留80%以上;4℃储藏25d之后,其酶活力仍保留60%以上。与D311大孔树脂、聚丙烯酰胺和海藻酸钠微球制备的固定化酶相比,HPD-750大孔树脂固定化酶的活性、操作稳定性、机械稳定性和储存稳定性都较好。该结果说明,HPD-750大孔树脂可作为固定化酶较好的载体材料。     

壳聚糖–精氨酸树脂固定化胰凝乳蛋白酶及其性质

以自制的多孔、具柔性亲水手臂的壳聚糖–精氨酸树脂为载体,戊二醛为交联剂固定胰凝乳蛋白酶,确定了酶与载体的最佳比例为20 mg酶/g湿树脂,交联剂的最佳用量为10 mL 1.0%戊二醛/1.5 g湿树脂,交联时间为60 min,所得固定化酶的活力回收率达68.95%。固定化胰凝乳蛋白酶的Km为8.36 mg/mL,比游离酶增大1.52倍,其酶促反应10 min达到最大速率,具有接近游离酶的催化时间进程曲线;其最适温度为70 ℃,比游离酶升高10 ℃;其最适pH值为5.92,比游离酶酸性偏移2个pH值。此外,固定化胰凝乳蛋白酶具有良好的热稳定性和贮存稳定性,75 ℃时的半衰期为8 h,4 ℃时的半衰期为46天。     

核苷酸锆固定化脂肪酶的制备及其催化性能

开发了以核苷酸锆纳米颗粒为载体固定化脂肪酶的方法,考察了固定化时间、缓冲液pH值及浓度和酶载量等因素对固定化酶在有机相中催化烯丙醇酮酯交换反应性能的影响.结果表明,一元尿苷酸锆(粒径30～50nm)是较佳的载体,在磷酸缓冲液pH=8.0和浓度为0.03mol/L时,酶与载体质量比为4,固定化6h制得的固定化酶效果最佳....     

氨化大孔球状聚氯乙烯固定化木瓜蛋白酶的研究

以氨化大孔球状聚氯乙烯为载体,采用戊二醛载体交联的方法,将木瓜蛋白酶进行了固定化。以酪蛋白为底物,测定了固定化酶的活力回收。研究了固定化条件对固定化酶活力回收的影响。同时,对所得固定化酶的性质,如温度-活力关系、pH-活力关系、热稳定性以及重复使用性进行了考察。结果表明,所得固定化木瓜蛋白酶具有较好的稳定性和重复使用性。     

巨大芽胞杆菌环氧水解酶的固定化及其催化性能

考察了多种载体对巨大芽孢杆菌ECU1001环氧水解酶的固定化.以大孔DEAE-纤维素离子交换树脂为载体时,固定化酶的活力回收达70%.进一步考察了温度和pH对固定化酶活力的影响,并使用该固定化酶进行了缩水甘油苯基醚对映选择性水解批次反应.结果表明,在较低的底物浓度下该固定化酶的稳定性较好,10批反应后仍然剩余72.4%的活力.     

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.     

Collagen-Immobilized Lipases Show Good Activity and Reusability for Butyl Butyrate Synthesis

Candida rugosa lipases were immobilized onto collagen fibers through glutaraldehyde cross-linking method. The immobilization process has been optimized. Under the optimal immobilization conditions, the activity of the collagen-immobilized lipase reached 340 U/g. The activity was recovered of 28.3 % by immobilization. The operational stability of the obtained collagen-immobilized lipase for hydrolysis of olive oil emulsion was determined. The collagen-immobilized lipase showed good tolerance to temperature and pH variations in comparison to free lipase. The collagen-immobilized lipase was also applied as biocatalyst for synthesis of butyl butyrate from butyric acid and 1-butanol in n-hexane. The conversion yield was 94 % at the optimal conditions. Of its initial activity, 64 % was retained after 5 cycles for synthesizing butyl butyrate in n-hexane.     

Immobilized Lipase from Candida sp. 99–125 on Hydrophobic Silicate: Characterization and Applications

Lipase Candida sp. 99–125 has been proved to be quite effective in catalyzing organic synthesis reactions and is much cheaper than commercial lipases. Mesoporous silicates are attractive materials for the immobilization of enzymes due to their unique structures. The present research designed a hydrophobic silicate with uniform pore size suitable for the comfort of lipase Candida sp. 99–125 for improving its activity and stability. The resulting immobilized lipase (LP@PMO) by adsorption was employed to catalyze hydrolysis, esterification, and transesterification reactions, and the performances were compared with the lipase immobilized on hydrophilic silicate (LP@PMS) and native lipase. The LP@PMO showed as high activity as that of native lipase in hydrolysis and much increased catalytic activity and reusability in the reactions for biodiesel production. Besides, LP@PMO also possessed better organic stability. Such results demonstrate that immobilization of lipase onto hydrophobic supports is a promising strategy to fabricate highly active and stable biocatalysts for applications.     

Immobilization of Candida antarctica Lipase B by Adsorption to Green Coconut Fiber

An agroindustrial residue, green coconut fiber, was evaluated as support for immobilization of Candida antarctica type B (CALB) lipase by physical adsorption. The influence of several parameters, such as contact time, amount of enzyme offered to immobilization, and pH of lipase solution was analyzed to select a suitable immobilization protocol. Kinetic constants of soluble and immobilized lipases were assayed. Thermal and operational stability of the immobilized enzyme, obtained after 2 h of contact between coconut fiber and enzyme solution, containing 40 U/ml in 25 mM sodium phosphate buffer pH 7, were determined. CALB immobilization by adsorption on coconut fiber promoted an increase in thermal stability at 50 and 60 °C, as half-lives (t _1/2) of the immobilized enzyme were, respectively, 2- and 92-fold higher than the ones for soluble enzyme. Furthermore, operational stabilities of methyl butyrate hydrolysis and butyl butyrate synthesis were evaluated. After the third cycle of methyl butyrate hydrolysis, it retained less than 50% of the initial activity, while Novozyme 435 retained more than 70% after the tenth cycle. However, in the synthesis of butyl butyrate, CALB immobilized on coconut fiber showed a good operational stability when compared to Novozyme 435, retaining 80% of its initial activity after the sixth cycle of reaction.     

Catalytic activity of lipase immobilized onto ultrathin films of cellulose esters

Ultrathin (approximately 2.0 nm) films of cellulose acetate (CA), cellulose acetate propionate (CAP), and cellulose acetate butyrate (CAB) supported on Si wafers have been prepared by adsorption and characterized by means of ellipsometry, atomic force microscopy (AFM), and contact angle measurements. CA, CAP, and CAB ultrathin films were characterized in air just after their formation and after annealing under reduced pressure at temperature higher than the corresponding melt temperature. Upon annealing, CA, CAP, and CAB ultrathin films became smoother and more hydrophobic, evidencing molecular reorientation at the solid-air interface. CA, CAP, and CAB films were used as supports for the immobilization of lipase. The adsorption of lipase onto annealed films was more pronounced than that onto untreated films, showing the strong affinity of lipase for the more hydrophobic substrates. Enzymatic activity was evaluated by a standard procedure, namely, (spectrophotometric) measurement of p-nitrophenol, the product formed from the hydrolysis of p-nitrophenyl dodecanoate (p-NPD). Lipase immobilized onto hydrophobic films exhibited higher activity than that of free lipase and could be recycled three times while retaining relatively high activity (loss of ca. 30% of original enzymatic activity). The effect of storing time on the activity of immobilized lipase was studied. Compared with free lipase, that immobilized onto more hydrophobic films retained 70% activity after 1 month. More importantly, the latter level of activity is similar to that of free lipase. However, lipase immobilized onto more hydrophilic films retained 50% and 30% activity after 20 and 30 days, respectively. These results are explained in terms of surface wettability and the contribution of the interactions between the polar residues of lipase and the glucopyranosyl moieties of cellulose ester to maintain the natural conformation of immobilized enzyme.     

Characterization and utilization of Candida rugosa lipase immobilized on controlled pore silica

Candida rugosa lipase was immobilized by covalent binding on controlled poresilica (CPS) using glutaraldehyde ascross-linking agent under aqueous and nonaqueous conditions. The immobilized C. rugosa was more active when the coupling procedure was performed in the presence of a nonpolar solvent, hexane. Similar optima pH (7.5–8.0) was found for both free and immobilized lipase. The optimum temperature for the immobilized lipase was about 10°C higher than that for the free lipase. The thermal stability of the CPS lipase was alsogreater than the original lipase preparation. Studies on the operational stability of CPS lipase revealed good potential for recycling under aqueous (olive-oil hydrolysis) and nonaqueous (butyl butyrate synthesis) conditions.     

Characterization of Sol-gel bioencapsulates for ester hydrolysis and synthesis

Candida rugosa lipase was entrapped in silica sol-gel particles prepared by hydrolysis of methyltrimethoxysilane and assayed by p-nitrophenyl palmitate hydrolysis, as a function of pH and temperature, giving pH optima of 7.8 (free enzyme) and 5.0–8.0 (immobilized enzyme). The optimum temperature for the immobilized enzyme (50–55°C) was 19°C higher than for the free enzyme. Thermal, operational, and storage stability were determined with n-butanol and bytyric acid, giving at 45°C a half-life 2.7 times greater for the immobilized enzyme; storage time was 21 d at room temperature. For ester synthesis, the optimum temperature was 47°C, and high esterification conversions were obtained under repeated batch cycles (half-life of 138 h).     

Effect of surface hydrophobicity/hydrophilicity of mesoporous supports on the activity of immobilized lipase

Taking advantage of the virtue of hydrophilic surface, lipase was firstly immobilized on SBA-15 as a support. Then the surface of the SBA-15 with enzyme entrapped inside the channels was modified by grafting with organic moieties. It has been found that the silylation with n-decyltrimethoxysilane (DE) and 3-(trimethoxysilyl)propyl methacrylate (MA) following the lipase immobilization increases the surface hydrophobicity. But the surface modified by MA shows more hydrophilicity than that modified by DE. The activity assay indicates that the hydrolytic activity for the hydrolysis of insoluble or partly soluble substrates increases with enhanced surface hydrophobicity.     

Intensification of lipase performance for long-term operation by immobilization on controlled pore silica in presence of polyethylene glycol

In agreement with previous studies, promising results were obtained when lipase was immobilized on controlled pore silica (CPS) in the presence of polyethylene glycol (PEG 1500). This methodology rendered immobilized derivatives with higher operational stability than those lacking PEG 1500. This article extends the scope of this approach by evaluating the combined effects of PEG concentration and lipase loading employing a multivariate statistical approach. A 2² factorial design with center point was adopted for a full understanding of these effects and their interactions. Conditions that maximize the immobilization yield were different from those attained for the biocatalyst’s operational stability. Possible reasons for the increase in both activity and stability of lipase immobilized on CPS in the presence of PEG 1500 are discussed in light of the influence of surface hydrophilic/hydrophobic balance.     

单分散磁性纳米粒子固定化猪胰脂肪酶的研究

借助溶热法制备了一种亲水及生物相容良好的Fe3O4磁性纳米粒子,用γ-氨丙基三乙氧基硅烷直接对所得磁性粒子表面改性,然后用戊二醛偶联法制得了固定化猪胰脂肪酶.表征研究显示,所得磁性粒子粒径约200 nm,具有良好的单分散性和磁响应性.考察了戊二醛浓度、给酶量和反应时间对脂肪酶固定化过程的影响,并通过游离酶与固定化酶的比...