大孔载体对米曲霉氨基酰化酶的固定化研究

用合成的大孔丙烯酸甲酯-—二乙烯苯交联共聚物(聚丙烯酸甲酯)、丙烯酰胺-N,N′-亚甲基双丙烯酰胺交联共聚物(聚丙烯酰胺)及它们的功能基化产物作为固定化氨基酰化酶的载体。考察了载体性质对固定化氨基酰化酶效果的影响。比较了底物浓度、pH、磷酸缓冲液浓度、温度对氨基酰化酶溶液酶及固定化酶的影响。利用其中一种载体制成固定化酶柱,对DL-蛋氨酸进行了连续拆分,考察固定化酶的操作稳定性。     

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.     

固定化细胞酶法拆分N-乙酰-D,L-3-甲氧基丙氨酸

利用氨基酰化酶固定化细胞酶法拆分了N-乙酰-D,L-3-甲氧基丙氨酸. 考察了温度、pH值、底物浓度、金属离子和拆分时间对酶促反应的影响. 确定了氨基酰化酶固定化细胞手性拆分N-乙酰-D,L-3-甲氧基丙氨酸的最佳工艺条件为pH=7.0, 反应温度50 ℃及底物浓度500 mmol/L. 10^-4 mol/L的Co²⁺和Mg²⁺对氨基酰化酶有显著激活作用, Cu²⁺和Zn²⁺对酶促反应有明显抑制作用. 在最佳条件下, 氨基酰化酶固定化细胞对N-乙酰-L-3-甲氧基丙氨酸的摩尔转化率达96%.     

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.     

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.     

高分子载体对米曲霉氨基酰化酶的固定化研究

合成了一系列不同结构的丙烯酸甲酯—二乙烯基苯交联共聚物,并用多乙烯多胺胺解制得了功能基化交联共聚物。研究了交联度、致孔剂用量和不同的功能基化试剂对这些载体固定化氨基酰化酶效果的影响。比较了固定化氨基酰化酶与溶液酶的酶学性质。用这种载体制成固定化酶柱,对N—乙酰—DL—蛋氨酸和N—乙酰—DL—苯丙氨酸进行连续拆分,得到了很好的效果。     

固定化青霉素酰化酶新型载体PEI/SiO2的制备及其特性

通过γ-氯丙基三甲氧基硅烷的媒介, 将聚乙烯亚胺(PEI)化学偶联在硅胶微粒表面, 制备了固定化青霉素酰化酶的新型复合载体PEI/SiO2, 最终制得了活性高且稳定性好的固定化青霉素酰化酶. 通过测定复合载体表面PEI的偶合量, 考察了各种反应条件对复合载体制备的影响规律; 通过红外光谱与电导滴定法测定, 对复合载体表面的化学结构与组成进行了表征; 为探索复合载体PEI/SiO2固定化酶的作用机理, 测定了复合载体在固定化酶前的ζ电位. 研究结果表明, 通过氯丙基硅烷偶联剂的媒介, 聚胺大分子PEI可以充分地被化学偶联在SiO2表面, 键合量可达到15%. 偶联反应的适宜条件: 反应温度90-94 ℃; 反应时间5h; PEI的质量浓度0.45-0.50 g/mL. 由于PEI分子链中含有大量氨基, 少量的共价键联与大量的物理吸附相结合, 既可使青霉素酰化酶被快速稳定地固定化, 又能很好地保持酶的构象, 使其具有较高的催化活性与活力回收率, 而且具有良好的连续操作稳定性, 重复使用15次, 固定化酶的活性可稳定地保持在初活性的87.5%水平上.     

固定化酶树脂进行酶固定化反应条件的研究

本文通过研究固定化青霉素酰化酶的酶活力,考察了固定化酶反应条件即缓冲溶液浓度、pH值、酶浓度以及反应时间等对固定化酶活力的影响。研究了反应条件与固定化酶活性之间的影响规律,从而为进一步优化固定化酶条件、提高固定化酶活性提供了实验依据与参考。     

微波辐射高效共价固定青霉素酰化酶

为提高青霉素酰化酶的共价固定化效率, 在微波辐射条件下将酶蛋白共价固定于介孔泡沫硅(MCFs)的孔道中. 通过正硅酸四乙酯水解缩合制备介孔泡沫硅, 再于微波辅助下将青霉素酰化酶共价固定在其孔道中. 以固定化酶相对活力和活力回收为指标, 考察了加酶量、固定化温度、微波辐射时间等条件对酶固定化效率的影响. 实验结果表明: 当加酶量为60 mg/g, 固定化温度为20 ℃, 微波辐射140 s, 固定化酶相对活力达到178.1%, 表观活力为1191.3 U/g(以湿重计). 与常规方法相比, 微波辅助固定化酶时, 固定化酶相对活力提高34.5%, 固定化时间亦大幅缩短至数分钟, 这为青霉素酰化酶的高效共价固定化提供了一条新的途径.     

化学修饰木瓜蛋白酶的固定化及性质研究

在底物保护和无底物保护下,用丁二酸酐对木瓜蛋白酶进行化学修饰,以三硝基苯磺酸法测定修饰酶的平均氨基修饰度,以棉布为载体,戊二醛为交联剂,对修饰前后的木瓜蛋白酶分别进行固定化.考察了温度、pH和表面活性剂SDS对化学修饰的固定化木瓜蛋白酶活力的影响,并与固定化天然木瓜蛋白酶进行了比较.研究表明,化学修饰固定化木瓜蛋白酶的最适反应温度为80℃;最适pH为9.0;在SDS浓度为20mg/mL时酶活也仍能保持在40%左右;米氏常数为187g/L.与天然的固定化酶相比,化学修饰的固定化木瓜蛋白酶的热稳定性、耐碱性和耐洗涤性得到了显著提高.     

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.     

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。     

Activity of Candida rugosa lipase immobilized on gamma-Fe2O3 magnetic nanoparticles

We report the stability and enzymatic activity of Candida rugosa Lipase (E.C.3.1.1.3) immobilized on gamma-Fe2O3 magnetic nanoparticles. The immobilization strategies were either reacting the enzyme amine group with a nanoparticle surface acetyl, or amine groups. In the former, the enzyme was attached through a C=N bond, while in the latter it was connected using glutaraldehyde. AFM images show an average particle size of 20 +/- 10 nm after deconvolution. The enzymatic activity of the immobilized lipase was determined by following the ester cleavage of p-nitrophenol butyrate. The covalently immobilized enzyme was stabile and reactive over 30 days.     

Properties of Immobilized Laccase on Mesostructured Cellular Foam Silica and its Use in Dye Decolorization

Laccase was immobilized on mesostructured cellular foam (MCF), a kind of mesoporous silica with large pore size by adsorption–cross linking method. The effects of immobilization time, temperature, pH, amount of enzyme and content of glutaraldehyde on the immobilization were optimized. The activities and stabilities towards pH and temperature of the immobilized enzyme were studied, and significantly improved enzymatic properties and good operational stability were obtained for the immobilized laccase. Dye decolorization tests showed that the immobilized enzyme could decolorize Alizarin Red and Indigo Blue solution fast and efficiently in the presence of ABTS.     

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...     

The Use of PAMAM Dendrimers as a Platform for Laccase Immobilization: Kinetic Characterization of the Enzyme

The kinetic behavior of the enzyme laccase in solution and immobilized onto carbon platforms using poly(amido amine) (PAMAM) dendrimers has been investigated. The results with the immobilized enzymes have demonstrated that almost ten times more enzyme on the carbon support is required for satisfactory kinetic rates to be achieved. Furthermore, the study as a function of the substrate concentration revealed that the kinetic behavior of the enzyme in solution fits the Michaelis?CMenten model. However, when the enzyme is immobilized onto the carbon surface, the catalyzed reaction follows a particular kinetic behavior with apparent positive cooperativity. The highest activity with laccase (in solution or immobilized) is achieved around pH?4.5, and the substrate conversion rate clearly diminishes with rising pH. The optimum temperature lies around 60?°C. The enzyme displays good catalytic activity in a wide range of pH and temperature values. The stability tests evidenced that there is no appreciable reduction in the enzymatic activity after immobilization within the first 30?days. Taking into account both the kinetic and stability tests, one can infer that the use of PAMAM dendrimers seems to be a very attractive approach for the immobilization of enzymes, as well as a feasible and useful methodology for the anchoring of enzymes with potential application in many biotechnological areas.     

Urea potentiometric biosensor based on urease immobilized on chitosan membranes

Potentiometric biosensors based on urease (E.C. 3.5.1.5.) immobilized on chitosan membranes coupled to all-solid-state nonactin ammonium ion selective electrodes are described. The enzyme was immobilized on the chitosan membranes by four procedures: (A) adsorption; (B) adsorption followed by reticulation with dilute aqueous glutaraldehyde solution; (C) activation with glutaraldehyde followed by contact with the enzyme solution; and (D) activation with glutaraldehyde, contact with the enzyme solution and reduction of the Schiff base with sodium borohydride. The response characteristics of the biosensors obtained with these enzymatic membranes were determined and compared. The biosensor with best response characteristics, obtained by procedure (B), showed the following characteristics of response to urea: (i) linearity in the 10(-4) to 10(-2) M range; (ii) slope of up to 56 mV per decade; (iii) response time between 30 s and 2 min; and (iv) lifetime of 2 months. This biosensor was tested in the determination of urea in blood serum samples.     

Acetylcholine Biosensor Based on Dendrimer Layers for Pesticides Detection

We tested a new design of an enzyme biosensor based on acetylcholinesterase (AChE) and choline oxidase (ChO) immobilized on the supported monomolecular layer composed of poly(amidoamine) (PAMAM) dendrimers of the fourth generation (G4) mixed with 1‐hexadecanethiol (HDT). The resulting enzymatic activity, measured amperometrically, was substantially depressed in the presence of the organophosphate pesticide dimethyl‐2,2‐dichlorovinylphosphate (DDVP, Dichlorvos), carbamate pesticides carbofuran and carbamate drug eserine. The detection limits (1.3×10^?3 ppb for DDVP, 0.01 ppb for carbofuran and 0.03 for eserine) were considerably lower than so far reported for AChE based amperometric and potentiometric sensors. The relative simple protocol of biosensor preparation, high sensitivity and stability is very promising for determination of environmental pollutants in field conditions.     

A simple polyacrylamide gel electrophoresis procedure for separation of polyamidoamine dendrimers

A simple, inexpensive, and rapid electrophoresis technique was developed for use as a routine tool for evaluating purity of polyamidoamine (PAMAM) dendrimers. A variety of factors influencing migration of generations 0-7 dendrimers on nongradient polyacrylamide gels were evaluated. The low generation dendrimers were found to be very sensitive to diffusion during or after electrophoresis. The proposed method incorporates steps that minimize diffusion, in order to obtain improved resolution and sensitivity, especially for the lower-molecular-weight dendrimers. This was accomplished by inclusion of a dendrimer fixation step with glutaraldehyde and performing the electrophoresis separation, fixation, staining, and destaining at 4 degrees C. PAMAM dendrimer separation was studied under basic and acidic conditions. Electrophoresis under acidic conditions gave increased resolution and sensitivity over separation at alkaline pH. Oligomers and trailing generations could be clearly separated and visualized under these conditions. The smallest PAMAM dendrimer, generation 0, was visible at 1.5 microg under the optimized acidic conditions. With slight modifications, this technique should be applicable to separation of other water-soluble dendrimers.     

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).