聚乙烯醇-明胶复合膜固定化重组大肠杆菌NAD激酶的研究

为提高烟酰胺腺嘌呤二核苷酸(NAD)激酶的稳定性,采用复合膜对NAD激酶进行固定化研究。选用聚乙烯醇(PVA)、聚乳酸(PLA)、海藻酸钠(SA)和明胶(GEL)膜材料固定化NAD激酶。通过单因素实验确定最佳固定化条件为:PVA∶GEL为4∶1,加酶量为0.6 mL,固定化时间为6h,固定化温度为35℃,此时酶活力回收率达到最高值84%。固定化酶酶学性质分析结果表明,与游离酶进行比较,固定化后NAD激酶的最适温度由50℃提高至55℃,最适pH由8.0降至7.0,NAD激酶的热稳定性和pH稳定性均得到显著提高,但固定化酶的亲和力降低。固定化NAD激酶重复利用6次后,酶活性依然可维持初始酶活性的75%以上,表明聚乙烯醇-明胶复合膜固定化酶具有良好的操作稳定性。     

Simple-kinetic descriptions of alcohol dehydrogenase after immobilization on tresyl-chloride-activated agarose

Yeast alcohol dehydrogenase was successfully immobilized on tresyl-chloride-activated agarose; the optimized conditions allowed an enzyme activity recovery of over 90%. Comparison of free and immobilized enzyme properties showed an unchanged intrinsic activation energy of the reaction and a shift of optimum activity to a higher pH medium after immobilization. Comparison of the kinetic parameters for both substrates of the reaction showed that the Michaelis-Menten model could not take into consideration all the constraints induced by the immobilization on the enzyme properties but that the Theorell-Chance model was more appropriate. These results are discussed taking into consideration the factors affecting the immobilized enzyme. Finally, we discuss the possibilities of cofactor regeneration with this immobilized alcohol dehydrogenase.     

磁性纳米颗粒固定化乙醇脱氢酶的研究

本研究采用3-丙氨基三乙氧基硅烷(APTES)和戊二醛修饰包裹有SiO2磁性Fe3O4纳米颗粒表面,将其作为固定化载体固定化乙醇脱氢酶,研究固定化条件对固定化效率的影响,并对固定化酶性质进行分析。研究发现,当Fe3O4@SiO2纳米颗粒修饰上氨基和醛基后依然具有良好的水分散性和胶体稳定性,适合作为固定化载体。通过单因素优化,发现当最适给酶量为11. 3U/100 mg,搅拌转速为150 r/min,固定化p H和固定化温度分别控制在6. 5和5℃～15℃,固定化时长为45 min时,具有较好的固定化效果,固定化率可达到60. 2%。在此条件下制备得到的固定化酶与游离酶相比,固定化酶具有良好的耐高温和耐碱性。所得固定化乙醇脱氢酶在连续使用8次后,固定化率仍保留在57%左右,表明该固定化酶具有较好的操作稳定性,可为连续生产NADH提供技术依据。     

Immobilization of Aspergillus oryzae tannase and properties of the immobilized enzyme

Tannase enzyme from Aspergillus oryzae was immobilized on various carriers by different methods. The immobilized enzyme on chitosan with a bifunctional agent (glutaraldehyde) had the highest activity. The catalytic properties and stability of the immobilized tannase were compared with the corresponding free enzyme. The bound enzyme retained 20·3% of the original specific activity exhibited by the free enzyme. The optimum pH of the immobilized enzyme was shifted to a more acidic range compared with the free enzyme. The optimum temperature of the reaction was determined to be 40 °C for the free enzyme and 55 °C for the immobilized form. The stability at low pH, as well as thermal stability, were significantly improved by the immobilization process. The immobilized enzyme exhibited mass transfer limitation as reflected by a higher apparent K_m value and a lower energy of activation. The immobilized enzyme retained about 85% of the initial catalytic activity, even after being used 17 times.     

Enzymatic properties of immobilized Alcaligenes faecalis cells with cell-associated beta-glucosidase activity

Enzymatic properties of Alcaligenes faecalis cells immobilized in polyacrylamide were characterized and compared with those reported for the extracted enzyme, and with those measured for free cells. Many of the properties reflected those of the extracted enzyme rather than those measured in the free whole cells prior to immobilization, suggesting cell disruption during immobilization. These properties included the pH activity profile, a slightly broader pH stability profile, and the activation energy. Electron micrographs showed evidence of cell debris among the polymer matrix. The immobilized cells were not viable, and did not consume glucose. Thermal stability was less after immobilization with a half-life of 16 h at 45 degrees C, and 3.5 h at 50 degrees C. The immobilized preparation was more stable when stored lyophilized rather than in buffer, losing 23 and 52% activity, respectively, after six months. The enzyme was irreversibly inhibited by both acetate and citrate buffers. If the immobilized enzyme is to be used in conjunction with cellulases from Trichoderma reesei for cellulase saccharification, the optimal conditions would be pH 5.5 and 45 degrees C in a buffer containing no carboxylic acid groups.     

Immobilization of Enzyme into Poly(vinyl alcohol) Membrane

Glucoamylase, invertase, and cellulase were entrapped within poly(vinyl alcohol) (PVA) membrane cross-linked by means of irradiation of ultraviolet light. The conditions for immobilization of glucoamylase were examined with respect to enzyme concentration in PVA, sensitizer (sodium benzoate) concentration in PVA, irradiation time, and membrane thickness. Various characteristics of immobilized glucoamylase were evaluated. Among them, the pH activity curve for the immobilized enzyme was superior to that for the native one, and thermal stability was improved by immobilization with bovine albumin. The apparent K(m) was larger for immobilized glucoamylase than for the native one, while V(max) was smaller for the immobilized enzyme. Also, the apparent K(m) appeared to be affected by the molecular size of the substrate. Further, immobilized invertase and cellulase showed good stabilities in repeating usage.     

An enzyme-polymer film prepared with the use of poly(vinyl alcohol) bearing photosensitive aromatic azido groups

Photochemical reaction of poly(vinyl alcohol) bearing aromatic azido groups was applied for immobilization of beta-glucosidase (beta-D-glucoside glucohydrolase, EC 3.2.1.21.) in poly(vinyl alcohol) film. Photo-crosslinking and immobilization reactions proceeded by light irradiation for 25 min in air. The immobilized enzyme showed approx. 40% of its native enzyme activity with an apparent Michaelis constant of 3.9 mM. The Michaelis constant of the native enzyme was 2.3 mM. Some properties of the immobilized and native enzyme are compared.     

Immobilization of pancreatic lipase on polyvinyl alcohol by cyanuric chloride

Porcine pancreatic lipase (EC 3.1.1.3) was covalently immobilized onto 2,4,6-trichloro-s-triazine (cyanuric chloride) activated polyvinyl alcohol (PVA). The influence of activating agent and enzyme concentration on the immobilization process were evaluated.Hydrolytic activities of free and immobilized enzyme were determined and the immobilization yield was estimated by measuring the quantity of protein, both in free enzyme solution and in washing solutions after immobilization. After the optimization of immobilization process, the physical and chemical characterization of immobilized enzyme was performed. Additionally, the thermal, pH, storage, and operational stability of the immobilized and free enzymes were tested. Obtained data showed that the immobilized enzyme seemed better and offered some advantages in comparison with free enzyme.     

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。     

Cysteine enhances activity and stability of immobilized papain

Immobilization of papain on Sepharose 6B in the presence of different concentrations of cysteine affected the enzyme activity depending on cysteine concentration. The maximum specific activity was observed when papain was immobilized with 200 mM cysteine. The immobilization process brought significant enhancement of stability to temperature and extreme pH values with respect to free papain. After immobilization, the optimum temperature of papain activity increased by 20°C (from 60 to 80°C) and its optimum pH activity shifted from 6.5 to 8.0. Catalytic efficiency (k_cat/K_m) and specific activity of the immobilized enzyme do not significantly change after immobilization. The temperature profile of this form of immobilized papain showed a broad range of activity compared with both free and immobilized form of papain in the absence of cysteine. This significant behavior in terms of activation energy is also discussed.     

Immobilization of yeast alcohol dehydrogenase on magnetic nanoparticles for improving its stability

Yeast alcohol dehydrogenase (YADH) was immobilized covalently on Fe₃O₄ magnetic nanoparticles (10.6 nm) via carbodiimide activation. The immobilization process did not affect the size and structure of magnetic nanoparticles. The YADH-immobilized magnetic nanoparticles were superparamagnetic with a saturation magnetization of 61 emu g^–1, only slightly lower than that of the naked ones (63 emu g^–1). Compared to the free enzyme, the immobilized YADH retained 62% activity and showed a 10-fold increased stability and a 2.7-fold increased activity at pH 5. For the reduction of 2-butanone by immobilized YADH, the activation energies within 25–45 °C, the maximum specific activity, and the Michaelis constants for NADH and 2-butanone were 27 J mol^–1, 0.23 mol min^–1 mg^–1, 0.62 mM, and 0.43 M, respectively. These results indicated a structural change of YADH with a decrease in affinity for NADH and 2-butanone after immobilization compared to the free enzyme.     

Stabilization of a highly active but unstable alcohol dehydrogenase from yeast using immobilization and post-immobilization techniques

The alcohol dehydrogenase (ADH) from Baker's yeast is very active but extremely unstable under several different conditions. Mild immobilization methods such as one-point attachment to agarose activated with cyanogen bromide groups or ionic adsorption to agarose activated with charged groups allow high activity recoveries (80–100%) but do not promote protein stabilization. In contrast, immobilization methods that force the enzyme to be covalently attached at multiple points on the support fully inactivate the enzyme. Herein, we propose an interesting solution to address the dichotomy between activity and stability. We have developed a protocol in which the enzyme is immobilized on agarose activated with glyoxyl groups in the presence of acetyl cysteine, which results in the recovery of 25% of the enzyme activity but increases the thermal stability of the soluble enzyme 50-fold. However, this immobilization technique does not stabilize the enzyme quaternary structure. Hence, a post-immobilization technique using functionalized polymers has been used to cross-link all enzyme subunits. In this method, polycationic polymers (polyethylenimine) cross-link the quaternary structure with a negligible effect on catalytic activity, which results in a derivative that is 5-fold more stable than non-cross-linked derivatives under very dilute and acidic conditions that highly favor subunit dissociation. Therefore, the stability was increased 500-fold for this optimal derivative compared to diluted soluble enzyme, although the relative expressed activity was low (25%). However, the low expressed activity may be overcome by designing immobilized biocatalysts with high volumetric activities.     

Development of Silica Gel-Supported Modified Macroporous Chitosan Membranes for Enzyme Immobilization and Their Characterization Analyses

The present work was aimed at developing stability enhanced silica gel-supported macroporous chitosan membrane for immobilization of enzymes. The membrane was surface modified using various cross-linking agents for covalent immobilization of enzyme Bovine serum albumin. The results of FT-IR, UV–vis, and SEM analyses revealed the effect of cross-linking agents and confirmed the formation of modified membranes. The presence of silica gel as a support could provide a large surface area, and therefore, the enzyme could be immobilized only on the surface, and thus minimized the diffusion limitation problem. The resultant enzyme immobilized membranes were also characterized based on their activity retention, immobilization efficiency, and stability aspects. The immobilization process increased the activity of immobilized enzyme even higher than that of total (actual) activity of native enzyme. Thus, the obtained macroporous chitosan membranes in this study could act as a versatile host for various guest molecules.     

Immobilization of Papain on the Mesoporous Molecular Sieve MCM‐48

The immobilization of papain on the mesoporous molecular sieve MCM‐48 (with a pore size of 6.2 nm in diameter) with the aid of glutaraldehyde, and the characteristics of this immobilized papain are described. The optimum conditions for immobilization were as follows: 20 mg native free enzyme/g of the MCM‐48 and 0.75 % glutaraldehyde, 2 h at 10–20 °C and pH 7.0. Under these optimum conditions for immobilization, the activity yield [%] of the immobilized enzyme was around 70 %. The influence of the pH on the activity of the immobilized enzyme was much lower compared to the free enzyme. The thermostability of the immobilized enzyme, whose half‐life was more than 2500 min, was greatly improved and was found to be significantly higher than that of the free enzyme (about 80 min). The immobilized enzyme also showed good operational stability, and the activity of the immobilized enzyme continued to maintain 76.5 % of the initial activity even after a 12‐day continuous operation. Moreover, the immobilized enzyme still exhibited good storage stability. From these results, papain immobilized on the MCM‐48 with the aid of glutaraldehyde, can be used as a high‐performance biocatalyst in biotechnological processing, in particular in industrial and medical applications.     

Tyrosine hydroxylase activity of immobilized tyrosinase on enzacryl-AA and CPG-AA supports: Stabilization and properties

Frog epidermis tyrosinase has been immobilized on Enzacryl-AA (a polyacrylamide-based support) and CPG(zirclad)-Arylamine (a controlled pore glass support) in order to stabilize the tyrosine hydroxylase activity of the enzyme; in this way, the immobilized enzyme could be used to synthesize L-dopa from L-tyrosine. The activity immobilization yield Y(IME) (act) (higher than 86%), coupling efficiency (up to 90%), storage stability (no loss in 120 days), and reaction stability (t(1/2) was higher than 20 h in column reactors) were measured for tyrosinase after its immobilization. The results showed a noticeable improvement (in immobilization yield, coupling efficiency, and storage and operational stabilities) over previous reports in which tyrosinase was immobilized for L-dopa production. The activity and stability of immobilized enzyme preparations working in three different reactor types have been compared when used in equivalent conditions with respect to a new proposed parameter of the reactor (R(p)), which allows different reactor configurations to be related to the productivity of the reactor during its useful life time. The characteristic reaction inactivation which soluble tyrosinase shows after a short reaction time has been avoided by immobilization, and the stabilization was enhanced by the presence of ascorbate. However, another inactivation process appeared after a prolonged use of the immobilized enzyme. The effects of reactor type and operating conditions on immobilized enzyme activity and stability are discussed.     

A smart bioconjugate of chymotrypsin

alpha-Chymotrypsin was immobilized on Eudragit S-100 via covalent coupling with 93% retention of proteolytic activity. The conjugate behaved as a smart biocatalyst and functioned as a pH-dependent reversibly soluble-insoluble biocatalyst. The pH optimum of chymotrypsin broadened on immobilization, and the immobilized preparation showed better stability at and above pH 6.5 as compared to the free enzyme. The immobilized enzyme showed a slight shift in the temperature optimum and enhanced thermal stability retaining 70% of its original activity after 1 h of exposure to 40 degrees C as compared to the 25% residual activity for the free enzyme under identical conditions. K(m) and V(max) values did not change on immobilization. Also, the immobilized preparation was quite stable to reuse, it retained almost 85% of its original activity even after a fifth precipitation cycle. UV spectroscopy and circular dichroism were used to probe structural changes in the enzyme upon immobilization.     

Selective immobilization of Bacillus subtilis lipase A from cell culture supernatant: Improving catalytic performance and thermal resistance

Bacillus subtilis lipase A (BSLA) has been extensively studied through protein engineering; however, its immobilization and behavior as an insoluble biocatalyst have not been extensively explored. In this work, for the first time, a direct immobilization of recombinant BSLA from microbial culture supernatant was reported, using chemically modified porous with different electrostatic, hydrophobic, hydrophilic, and hydrophilic−hydrophobic enzyme-support interactions. The resulting biocatalysts were evaluated based on their immobilization kinetics, activity expression (pH 7.4), thermal stability (50 °C), solvent resistance and substrate preference. Biocatalysts obtained using glyoxyl silica support resulted in the selective immobilization of BSLA, resulting in an activity recovery of 50 % and an outstanding aqueous stabilization factor of 436, and 9.5 in isopropyl alcohol, compared to the free enzyme. This selective immobilization methodology of BSLA allows to efficiently generate immobilized biocatalysts, thus avoiding laborious purification steps from cell culture supernatant, which is usually a limiting step when large amounts of enzyme variants or candidates are assessed as immobilized biocatalysts. Direct enzyme immobilization from cell supernatant provides an interesting tool which can be used to facilitate the development and assessment of immobilized biocatalysts from engineered enzyme variants and mutant libraries, especially in harsh conditions, such as high temperatures or non-aqueous solvents, or against non-water-soluble substrates. Furthermore, selective immobilization approaches from cell culture supernatant or clarified lysates could help bridging the gap between protein engineering and enzyme immobilization, allowing for the implementation of immobilization steps in high throughput enzyme screening platforms for their potential use in directed evolution campaigns.     

Immobilization of porcine pancreatic lipase on glycidyl methacrylate grafted poly vinyl alcohol

Graft copolymerization of glycidyl methacrylate (GMA) on to polyvinyl alcohol (PVA) using benzophenone (BP) as initiator was carried out. Grafted PVA was used as carrier for pancreatic lipase immobilization. The effects of GMA and BP concentrations as well as grafting reaction times on grafting yields and activities of the immobilized lipase were determined. The influence of enzyme concentrations was also studied. The optimal conditions for the grafting reaction were: 1 h at 15 mM BP and 2.3 M GMA, the optimum enzyme concentration for immobilization was 1 mg/ml. After optimization of the immobilization process a physical and chemical characterization of the immobilized enzyme was performed. Furthermore, the thermal, pH, storage and operational stability of the immobilized enzyme in comparison to the free form was tested.     

Laccase immobilization on the tailored cellulose-based Granocel carriers

Extracellular laccase produced by Cerrena unicolor was immobilized by adsorption or covalent bonds formation on the cellulose-based carrier Granocel. Immobilization was optimized by changing the anchor groups and the methods of activation/immobilization. On the base of measured activity and stability of immobilized preparations, the covalent method was selected. It was shown that coupling of the enzyme to the carrier via divinyl sulfone or glutaraldehyde yielded an enzyme-carrier preparation of high activity and storage stability. Further optimization of the carrier's superstructure consisted in changing pore diameters and amount of functional groups on the carriers surface. Three-fold higher activity was noted when the enzyme was immobilized on NH2-modified Granocel with the highest size exclusion limit and amino group content. Relatively low products sorption was observed on the carrier surface. The effects of protein concentration and pH-value of the coupling mixture on immobilization efficiency were evaluated also.     

Characterization and evaluation of Aspergillus oryzae lactase coupled to a regenerable support

A derivative of crosslinked Sepharose, p-(N-acetyl-L-tyrosine azo) benzamidoethyl-CL-Sepharose 4B, was synthesized and used for the selective immobilization of thermostable lactase from Aspergillus oryzae.Preparations of soluble and immobilized lactase were evaluated under initial velocity conditions in a batch process. Immobilization had no significant effect on the pH optimum at 50 degrees C or kinetic parameters at pH 4.5 or pH 6.5 and 50 degrees C. At pH 4.5, the soluble enzyme possessed maximum activity at 60 degrees C and the immobilized at 55 degrees C; at pH 6.5 both showed maximum activity at 55 degrees C. The activation energy, entropy, and enthalpy decreased significantly with immobilization at pH 4.5 but not at pH 6.5. When the immobilized enzyme was placed in a packed-bed reactor, the effect of temperature on activity was altered as reflected by a marked decrease in the thermodynamic parameters of activation at both pH levels. Upon immobilization there was also a dramatic increase in the apparent thermal stability of the lactase, and the mean half-life at 50 degrees C was increased from 7.2 to 13 days at pH 4.5 and from 3.8 to 16 days at pH 6.5.