固定化乙酰胆碱酯酶的制备及其特性研究

本研究以期研制出能重复使用的固定化乙酰胆碱酯酶(AChE),为天然产物复杂体系中AchE抑制剂筛选新方法的发展奠定基础.以氨基化硅胶(APS-Si)微球为载体,戊二醛为交联剂对乙酰胆碱酯酶进行交联固定化,并研究了酶的最佳固定化条件和固定化酶的性质.结果表明,0.05 g氨基化硅胶微球载体,用戊二醛溶液活化6 h后,在给酶量5 U,28℃固定16 h条件下,得到固定化酶的活性最大.固定化酶在常温(20～40℃),以及较宽pH范围内(pH 6～10)均具有较高的活性,并且具有良好的保存稳定性和可重复利用率,为基于固定化靶酶亲和-色谱质谱联用分析快速筛选乙酰胆碱酯酶抑制剂新方法的发展奠定了基础.     

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.     

壳聚糖固定化胰蛋白酶的研究

以壳聚糖为载体，戊二醛为交联剂，采用两种方法制备了固定化胰蛋白酶。考察了固定化反应中pH值，戊二醛的浓度，以及给酶量对固定化胰蛋白酶活力的影响，并研究了这两种固定化胰蛋白酶的性质。实验结果表明，以戊二醛预交联的网状壳聚糖为载体制备的固定化胰蛋白酶具有更加优良的性能，在最佳固定化反应条件下，酶的活性加收率可达56％。此固定化胰蛋白酶的最适pH为7．0－8．5，最适温度为60℃，Km值为2．52mol/L，固定化胰蛋白酶表现出较好的热稳定性，pH贮存稳定性，以及在乙醇水溶液中的稳定性。     

京尼平交联磁性壳聚糖微球的制备及其脂肪酶的固定化

采用反相悬浮法与溶胶凝胶法结合制备磁性壳聚糖微球,并以此为载体,京尼平为交联剂,脂肪酶为模型酶进行固定化,研究了酶固定化的最优条件和固定化酶的性质。结果表明,在京尼平浓度为0.6 g/L、交联温度为55 ℃、交联时间8 h,固定化酶的比活力最大,为4.31 U/g。固定化酶在25~35 ℃,pH值在8.0有最大活性,其米氏常数Km为0.26 mol/L。同时,固定化酶具有良好的热稳定性及pH稳定性,可重复利用,且能进行磁分离。     

壳聚糖固定化乳酸脱氢酶的制备及酶学性质研究

以磁性壳聚糖作为载体,戊二醛作为交联剂,对乳酸脱氢酶(LDH)进行固定化.固定化的最适条件为:戊二醛浓度6%,pH值7.5,酶的偶联时间2 h.对游离及固定化LDH酶学性质的研究表明,酶促反应的最适pH值为9.2,最适温度分别为37℃和50℃,对乳酸的表观米氏常数分别为1.6 mmol/L和0.9 mmol/L.游离酶和固定化酶在40℃放置150 min后,其活力分别为最初的56.5%和76.1%.固定化酶在4℃贮存4周后,活力仍保留50%以上.固定化酶在室温下与底物重复反应6次后,活力仍保留60%以上,说明固定化酶具有较好的热稳定性、贮存稳定性和复用性.     

树枝状大分子聚酰胺-胺用于氨基酰化酶的固定化研究

以树枝状大分子修饰的硅胶为载体,戊二醛为交联剂,对氨基酰化酶进行固定化研究。考察了树枝状大分子的代数、戊二醛浓度、反应温度与时间对氨基酰化酶固定化效果的影响,并且考察了该固定化酶的最佳酶解条件。结果表明,随着树枝状大分子代数的增加,固定化的酶量随之增大,同时,固定后的酶仍然保持较高的活性。     

介孔材料的修饰及固定青霉素酰化酶的稳定性研究

利用扩孔剂的作用合成出较大孔径(12 nm)的介孔材料SBA-15, 并进行表面氨基修饰, 以此为载体, 以戊二醛为交联剂, 对青霉素酰化酶进行组装固定, 并对固定化青霉素酰化酶(PGA)的稳定性进行了深入的研究. 实验结果表明, PGA与载体交联后仍保持活性. 热稳定性研究结果表明, 制备的固定化青霉素酰化酶在低于60 ℃时保持稳定; pH在6~11范围内保持稳定; 固定化酶重复使用10次之后, 仍具有高达90%的残留活力.     

阳离子交换树脂吸附交联固定鸡肝酯酶的实验研究

研究了基于酶抑制原理的农药残留生物传感器中固定化酶的制备方法.以离子交换树脂作为固定化载体,戊二醛为交联剂,采用吸附交联相结合的方法制备了固定化鸡肝酯酶.在 10℃下吸附75min,以及酶活力浓度固定在6U/ml±2U/ml,在交联过程中戊二醛浓度0.04%,10℃下交联1h的条件下可以获得最佳的固定效果.并且,用吸附交联制得的固定化酶相对于用吸附法制得固定化酶用于流动分析过程,其热稳定性和耐冲刷性更好.同时,在保存阶段也具有更好的稳定性.     

固定化脲酶的制备及应用

以壳聚糖作为载体,戊二醛作为交联剂对脲酶进行固定化。固定化的最适条件为:酶的偶联时间60min,戊二醛浓度0.5%,pH值7.0。对游离及固定化脲酶的酶学性质研究表明,酶促反应的最适pH均为7.0,最适温度分别为33℃和70℃。米氏常数分别为29.8mmol/L和13.9mmol/L。与游离酶相比,固定化酶的热稳定性和贮存稳定性更佳。应用固定化酶测定了试样中的微量组分。     

磁性纳米氮化铝颗粒固定化β-葡萄糖苷酶的性质

以戊二醛为交联剂,研究了磁性纳米氮化铝颗粒固定化β-葡萄糖苷酶的条件及固定化酶的结构特征,并考察了固定化酶的某些酶学性质.结果表明,在4.5 ml磁性纳米氮化铝颗粒悬液(100 mg/ml)中加入0.5 ml戊二醛溶液(2%)超声波分散后,加入5 ml β-葡萄糖苷酶溶液(50 mg/ml),于20℃,pH 5.0和100 r/min条件下固载3.5 h,酶蛋白和酶活回收率分别为82.6%和78.4%.固定化β-葡萄糖苷酶的结构松散,不改变酶的结构特征.与游离酶相比,固定化酶对对硝基苯基-β-D-葡萄糖苷水解反应的最佳反应温度有所降低,最佳反应pH值有所升高,而米氏常数Km值有所增大,且具有良好的贮存稳定性和操作稳定性,表明磁性纳米氮化铝颗粒适合作为β-葡萄糖苷酶的固定化载体.     

亲和色谱法筛选中药中血管紧张素转化酶抑制剂

以壳聚糖微球为载体、戊二醛（glutaraldehyde,GA）为交联剂对血管紧张素转化酶（Angiotensin converting enzyme,ACE）进行固定化．用固化的ACE作为亲和介质,利用血管紧张素转化酶抑制剂（Angiotensin convertingenzym einhibitor,ACEI）与ACE之间的亲和作用,结合高效液相色谱对亲和前后的体系进行检测,比较两者各组分色谱峰的差异,以此实现快速筛选复杂体系中的ACE抑制剂．应用赖诺普利（Lisinopril）、九肽抑制剂、依那普利（Enalapril）、培哚普利（Perindopril）、卡托普利（Captopril）等已上市的ACEI对方法进行验证,反映方法具有高度选择性．将方法应用于中药地龙及山楂筛选,发现共有5个组分与ACE有亲和作用,并且都能抑制ACE酶活性,它们对酶活性抑制的IC50值在0．45～4．62μg／mL范围．通过对亲和方法重现性考察,6次测定的相对标准偏差小于1％,说明方法可靠．提出的亲和色谱．色谱指纹差异法非常适合于从中药及天然产物等复杂混合物库中快速筛选靶点活性物质．     

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。     

Amperometric Biosensor Based on Immobilization of Oxalate Oxidase in a Mucin/Chitosan Matrix

An amperometric electrode for oxalate determination immobilizing the oxalate oxidase in a mucin/chitosan (muc/chit) gel with glutaraldehyde as crosslinking agent is presented. The effect of muc/chit weight ratio and volume percent (vol.%) of glutaraldehyde was studied. A very low dynamic response was observed in the case of 100% chitosan with 5 vol.% crosslinking agent. The addition of mucin to chitosan for enzyme immobilization resulted in a biosensor with much better performance, concerning to dynamic response, sensitivity, and stability, with 75% of the initial response after two months. The ratio muc/chit 70/30 was considered optimum for the immobilization. A slight crosslinking and the incorporation of mucin largely influences the swelling and diffusion of the analyte; a direct effect of these properties on the calibration slope was found; the hydrophilic environment for the biomolecule also favor the enzymatic activity through a higher enzyme‐substrate interaction.     

蛋黄-壳结构Fe3O4@SiO2@PMO磁性微球的制备及对漆酶的固定化

以蛋黄-壳结构的Fe₃O₄@SiO₂@PMO磁性微球作为载体, 采用交联法对漆酶进行固定, 考察了戊二醛浓度等对固定效果的影响, 并对固定后漆酶的活性进行了研究. 结果表明, 蛋黄-壳结构的磁性微球负载漆酶仅需6 h, 磁性微球对漆酶的固载量高达475 mg/g. 固定后漆酶的稳定性显著提高, 在pH=2.5~4.5的强酸性条件下, 固定后漆酶酶活仍可保持70%以上, 即使温度升高至60 ℃, 固定后漆酶的相对酶活仍保持65%以上. 这说明漆酶经所合成的材料固定后, 其耐酸和耐热能力都明显优于游离漆酶. 包覆的Fe₃O₄粒子使得材料很容易经磁铁分离法回收, 固定后漆酶经磁分离循环使用10次后仍然能保留85%的酶活, 具有良好的可操作性和稳定性, 有效降低了漆酶的使用成本.     

Optimization of protease immobilization by covalent binding using glutaraldehyde

Immobilization of a protease, Flavourzyme, by covalent binding on various carriers was investigated. Lewatit R258-K, activated with glutaraldehyde, was selected among the tested carriers, because of the highest immobilized enzyme activity. The optimization of activation and immobilization conditions was performed to obtain high recovery yield. The activity recovery decreased with increasing carrier loading over an optimal value, indicating the inactivation of enzymes by their reaction with uncoupled aldehyde groups of carriers. The buffer concentrations for carrier activation and enzyme immobilization were optimally selected as 500 and 50 mM, respectively. With increasing enzyme loading, the immobilized enzyme activity increased, but activity recovery decreased. Immobilization with a highly concentrated enzyme solution was advantageous for both the immobilized enzyme activity and activity recovery. Consequently, the optimum enzyme and carrier loadings for the immobilization of Flavourzyme were determined as 1.8 mg enzyme/mL and 0.6 g resin/mL, respectively.     

l-DOPA production by immobilized tyrosinase

The production of l-DOPA using l-tyrosine as substrate, the enzyme tyrosinase (EC 1.14.18.1) as biocatalyst, and l-ascorbate as reducing agent for the o-quinones produced by the enzymatic oxidation of the substrates was studied. Tyrosinase immobilization was investigated on different supports and chemical agents: chitin flakes activated with hexamethylenediamine and glutaraldehyde as crosslinking agent, chitosan gel beads, chitosan gel beads in the presence of glutaraldehyde, chitosan gel beads in the presence of polyvinyl pyrrolidone, and chitosan flakes using glutaraldehyde as crosslinking agent. The last support was considered the best using as performance indexes the following set of immobilization parameters: efficiency (90.52%), yield (11.65%), retention (12.87%), and instability factor (0.00). The conditions of immobilization on chitosan flakes were optimized using a two-level full factorial experimental design. The independent variables were enzyme-support contact time (t), glutaraldehyde concentration (G), and the amount of enzyme units initially offered (U _C). The response variable was the total units of enzymatic activity shown by the immobilized enzyme (U _IMO). The optimal conditions were t=24 h, G=2% (v/v), and U _C=163.7 U. Under these conditions the total units of enzymatic activity shown by the immobilized enzyme (U _IMO) was 23.3 U and the rate of l-DOPA production rate was 53.97 mg/(L·h).     

交联血管紧张素转化酶聚集体的制备及性质

制备了交联血管紧张素转化酶聚集体（ACE-CLEAs）,比较了ACE-CLEAs及游离ACE的酶学性质,包括最适酶促反应温度、最适pH值、Km、vmax、温度稳定性及pH稳定性等。 以酶活力回收率为参考,确定了制备ACE-CLEAs的最佳条件为：饱和度为80%的(NH4)2SO4溶液作为沉淀剂,沉淀时间0.5 h,质量分数为0.02%的戊二醛作为交联剂,交联时间1 h。 通过比较酶学性质发现,ACE-CLEAs比游离ACE具有更好的温度稳定性及pH稳定性,且与游离ACE接近的Km值表明,ACE-CLEAs对底物的亲和力与游离酶几乎相当。     

多层开管毛细管酶反应器的制备及在蛋白质酶切中的应用

以石英毛细管作为酶固定化的载体, 在毛细管内壁上逐步合成树枝形大分子聚酰胺-胺(PAMAM), 再通过交联剂戊二醛将胰蛋白酶直接键合到该大分子的末端氨基上, 并对酶固定化条件进行了优化, 制备了多层酶反应器. 利用该酶反应器对马心细胞色素C等蛋白质进行了酶切, 并对酶切的条件进行了优化. 实验结果表明, 该固定化酶反应器具有较高的酶切效率、良好的重现性和稳定性, 可用于蛋白质组学的研究.     

Direct introduction of amine groups into cellulosic paper for covalent immobilization of tyrosinase: support characterization and enzyme properties

Tyrosinase is used to eliminate phenolic compounds from wastewater. Therefore, its immobilization is important to enhance catalytic efficiency. Papery materials are of particular interest for use as support for enzyme immobilization since the porous microstructure of fiber networks in papers can provide a suitable reaction environment, especially in flow-type catalytic reactions. However, immobilization of protein onto papery structure needs chemical modifications in severe conditions. To overcome this challenge, a cellulosic paper was directly amine-functionalized in moderate conditions and used for tyrosinase immobilization. The support was pretreated with HCl (0.5 N) solution and then sequentially immersed in ethylenediamine (EDA), glutaraldehyde solution (2% v/v) and the crude enzyme. In comparison with the untreated one, the immobilized enzyme on the EDA-treated support offered a 3.7-fold increase in activity. The FTIR spectra as well as EDX analysis proved the presence of amine groups in the cellulosic paper and also covalent immobilization of tyrosinase on the modified support. When considering the effect of pH on the activity at 25 °C, a maximum relative activity of 134% at pH 6 was revealed. Similarly, evaluating the effect of temperature on the activity at pH 7 displayed a maximum relative activity of 152% at 35 °C. The immobilized enzyme was suitable for use for more than four cycles to degrade a phenolic compound at severe pH and temperature conditions. Additionally, the immobilized enzyme was active after treatment of the surface at different pHs and temperatures for 105 min. The chemically modified cellulosic paper can be used as a support for enzyme immobilization.