聚苯乙烯树脂固定化D-海因酶的初步研究

D-海因酶广泛用于D-氨基酸的制备研究和生产中,目前已有许多固定化D-海因酶及含D-海因酶细胞的研究报道。尝试了不同功能基团的聚苯乙烯树脂进行D-海因酶的固定化,结果表明功能基为伯氨基和仲氨基效果较好,并选取聚苯乙烯树脂D92进行了固定化D-海因酶的研究。采用该树脂制备固定化酶的最优条件是：酶质量浓度6mg／mL、温度25℃、固化时间12h。所得固定化酶的最适作用温度45℃,最适作用pH为8.5,且作用温度及适宜pH较广,Km为游离酶的1,8倍,且储存稳定性、操作稳定性较好。45℃下半衰期为11d。     

海因酶研究新进展

海因酶在生产手性药物中间体D-氨基酸上具有广泛的应用价值。全面综述了海因酶的研究历史、分类、进化和酶学性质;总结了产海因酶的茵种筛选和产酶条件、D-海因酶的纯化、微生物海因酶基因的克隆及其在大肠杆茵中的表达等技术;阐述了酶法合成D-(-)-对羟基苯甘氨酸的工艺条件。     

L-海因酶与D-海因酶的序列及结构比较研究

运用生物信息学的研究方法,从序列及结构上对L型及D型海因酶进行了初步的比较。研究了两种类型的海因酶在序列、骨架结构及活性中心的区别,并探讨了产生这些差异的理论基础,为海因酶进一步的理论及应用研究提供一定的指导。     

Eupergit C250L固定化D-海因酶及其催化性质

D-海因酶是海因酶法制备D-氨基酸的关键酶。利用Burkholderic cepecia1003菌发酵产酶,所得海因酶纯化后,以Eupergit C250L为载体进行共价固定化。分别考察了酶液蛋白浓度、固定化时间对蛋白固定量和酶活回收率的影响以及固定化前后海因酶催化性质的变化。结果表明:较高的酶液蛋白浓度和较长的固定化时间均有助于改善海因酶的固定化效果;固定化可显著提高海因酶的最适作用温度,但对其最适作用pH影响不大;固定化后海因酶对D,L-BH和MH的米氏常数均有较大幅度的降低。固定化酶反应器的实验表明:40℃下,底物(D,L-BH)1.0 g.L-1,体积流速1.0 mL.min-1,经21 h转化,产物N-Phe质量浓度可达0.47 g.L-1,转化率达43.21%。     

海因酶法制备D-对羟基苯甘氨酸的研究进展

D-对羟基苯甘氨酸(D-HPG)主要用于合成β-内酰胺类半合成抗生素,是国内最紧缺的医药中间体之一。微生物酶法是目前获得光学纯D-HPG的重要途径,微生物中起催化作用的主要是D-海因酶和N-氨甲酰水解酶。文章综述了产酶微生物的来源,酶的理化性质,以及培养条件的优化、基因工程、酶的固定化技术生产D-HPG的研究进展。     

海因酶的研究进展

海因酶在生产手性药物中间体上具有广泛的应用价值,本文综述了海因酶的研究历史、分类与进化、酶学性质、工业应用及发展方向。     

聚乙烯醇包埋固定化微生物的研究及进展

对聚乙烯醇包埋固定化微生物的原理,固定化方法的改进以及固定化细胞的应用进行了综述,ＰＶＡ是一种廉价的包埋材料,具有实用价值。     

假单胞菌海因酶基因在大肠杆菌中的高效表达(英文)

为实现利用生物酶转化法进行D 对羟基苯甘氨酸的工业化生产 ,构建了 3株海因酶基因工程菌 .利用PCR技术从恶臭假单胞菌 (Pseudomonasputida)CPU 980 1染色体DNA中扩增得到长约1.8kb的含编码区和自身启动子的海因酶全基因 .通过将海因酶全基因插入pMD18 T质粒、海因酶基因的编码区与pET 17 b质粒重组、海因酶基因编码区和T7强启动子一起插入pMD18 T质粒分别得到重组质粒pMD dht、pET dht和pMD T7 dht.将上述重组质粒分别转化大肠杆菌 (Escherichiacoli) ,通过地高辛标记菌落原位杂交和海因酶活力测定两种方法 ,筛选出具有海因酶活力的阳性转化子 .结果表明 ,大肠杆菌的RNA聚合酶能够识别和结合来自恶臭假单胞菌海因酶基因的自身启动子 ,该启动子在大肠杆菌中能够工作 .基因工程菌E .coliBL2 1 pMD dht、E .coliBL2 1 pET dht和E .coliBL2 1 pMD T7 dht的海因酶活力分别为 170 0U L、190 0U L和 2 5 0 0U L ,比野生菌P .putidaCPU 980 1的海因酶活力分别提高了 8倍、9倍和 12倍 .薄层扫描结果显示 ,这些工程菌的海因酶表达量分别约占菌体总可溶性蛋白质的 2 0 %、31%和 5 7%.SDS PAGE显示 ,海因酶的单体分子量约为 5 0kD .经工程菌E .coliBL2 1 pMD T7 dht催化 ,底物对羟基苯海因的转化率在 13h内可达到 9     

海因酶的研究进展

海历酶在生产手性药物中间体上具有广泛的应用价值,本文综述了海因酶的研究历史、分类与进化、酶学性质、工业应用及发展方向。     

Recombinant α-L-rhamnosidase of Aspergillus terreus immobilization in polyvinylalcohol hydrogel and its application in rutin derhamnosylation

Abstract

Recombinant α-L-rhamnosidase from Aspergillus terreus expressed in Pichia pastoris was immobilized in LentiKats^® lens-shaped polyvinylalcohol (PVA) capsules with an activity of 7 U g^{? 1}, which was 21% of its original activity. Immobilization did not significantly affect the pH and temperature profile of α-L-rhamnosidase, K_M increased by a factor of 3.4 whereas V_max decreased more than 10-fold. No decrease in activity was observed after 27 repeated batch runs of rutin derhamnosylation. The enzyme proved to have an excellent storage stability (136 days) in 60 g L^{? 1} ethanol with no change in its activity.     

壳聚糖固定化琼脂酶的研究

采用壳聚糖微球对琼脂酶进行固定化,在单因素实验的基础上用正交试验法确定最佳固定化工艺。结果表明:在戊二醛体积分数为2.5%,交联时间为6 h,加酶量为15 mL,固定时间为3 h时固定酶的活力最高;固定化酶的最适反应温度及最适pH分别为50℃和8.5,高于游离酶;同时其热稳定性及操作稳定性均高于游离酶。     

纳米磁性壳聚糖微球固定化酵母醇脱氢酶的研究

建立了以纳米级磁性壳聚糖微球(magnetic chitosan microspheres , M-CS)为载体固定化酵母醇脱氢酶(yeast alcohol dehydrogenase,YADH)的方法,优化了YADH的固定化条件,考察了固定化酶的性质。结果表明,M-CS 呈规则的圆球形,粒径在30nm 左右,具有较好的磁响应性。酵母醇脱氢酶固定化适宜条件为:50 mg 磁性壳聚糖微球,加入20mL 0.25 mg/mL 酵母醇脱氢酶(蛋白质含量)磷酸盐缓冲液(0.05 mol/L ,pH 7.0) ,在4 ℃固定2h。M-CS 容易吸附酵母醇脱氢酶,但吸附的酶量受载体与酶的比例、溶液的离子浓度、溶液pH的影响明显,而温度对吸附的酶量的影响则相对较弱。相对于游离的酵母醇脱氢酶,固定化酶的最适温度略有升高,可明显改善其热稳定性、酸碱稳定性、操作稳定性和贮存稳定性。     

Variables that Affect Immobilization of Mucor Miehei Lipase on Nylon Membrane

Nylon membrane was used to immobilize Mucor miehei lipase. Variables that affect this immobilization procedure were studied by experimental design. A 2³ full factorial design was employed for this purpose. The protein retention and hydrolytic activity of the immobilized lipase were used as response variables. The rapid loss of enzyme activity was the main problem during repetitive use. Two strategies were used to improve the low operational stability: nylon treated with HCl and nylon coated with polyvinyl alcohol (PVA). Lipase-nylon-PVA was the best enzyme derivative, allowing performance of five consecutive assays, with a retained activity of 0.5 U mg of protein⁻¹ g of support⁻¹.     

Cell immobilization using PVA crosslinked with boric acid

A new cell immobilization technique is described in which polyvinyl alcohol is crosslinked with boric acid, with the addition of a small amount of calcium alginate. The presence of the calcium alginate improves the surface properties of the beads, preventing agglomeration. A pure culture of phenol-degrading Pseudomonas was immobilized in the PVA-alginate beads. Phenol was successfully degraded in a fluidized bed of the beads, indicating that cell viability was maintained following the immobilization procedure. The PVA-alginate beads proved to be very strong and durable, with no noticeable degradation of the beads after 2 weeks of continuous operation of the fluidized bed.     

叉鞭金藻固定化培养的初步研究

以海藻酸钙为载体,初步考察了CaCl2浓度、胶球大小、密度及初始细胞密度等条件：对叉鞭金藻固定化培养的影响,确定了该藻固定化生长的优化条件;当藻细胞密度大于10^6cells/ml,CaCl2浓度为0.15mol/L,在50ml培养液中加入150个微藻胶球时,藻细胞的生长量最大。与游离的叉鞭金藻相比,固定化叉鞭金藻生长速度慢,但生长周期长。     

Immobilization of Rhizomucor miehei lipase onto montmorillonite K-10 and polyvinyl alcohol gel

Abstract

Immobilization of enzymes from different sources on various supports in designed systems increases enzymes’ stability by protecting the active site of it from undesired effect of reaction environment. Also, immobilization decreases the cost of separation and facilities the reuse of the enzymes. Therefore, the design of new immobilization enzyme preparations has been an inevitable area of modern biotechnology. Herein, Rhizomucor miehei lipase (RML) was immobilized on montmorillonite K-10 (MMT-RML) by adsorption and in polyvinyl alcohol (PVA-RML) by entrapment to obtain a more stable and active lipase preparation. The free and immobilized lipase preparations were characterized for p-nitrophenyl palmitate hydrolysis. The apparent Michaelis–Menten (K_mapp) constant was almost the same for the free RML and PVA-RML, whereas the corresponding value was 17.7-fold lower for MMT-RML. PVA-RML and MMT-RML have shown a 1.1 and 23.8 folds higher catalytic efficiency, respectively, than that of the free RML. The half-lives of PVA-RML and MMT-RML were found to be 7.4 and 3.4 times longer than the free RML at 35?°C, respectively. PVA-RML and MMT-RML maintained 65% and 87% of their initial activities after four reuses. These results showed that the catalytic performance of RML has improved significantly by immobilization.