Glucose oxidase immobilization on a novel cellulose acetate-polymethylmethacrylate membrane

Glucose oxidase (GOD) was immobilized on cellulose acetate-polymethylmethacrylate (CA-PMMA) membrane. The immobilized GOD showed better performance as compared to the free enzyme in terms of thermal stability retaining 46% of the original activity at 70 degrees C where the original activity corresponded to that obtained at 20 degrees C. FT-IR and SEM were employed to study the membrane morphology and structure after treatment at 70 degrees C. The pH profile of the immobilized and the free enzyme was found to be similar. A 2.4-fold increase in Km value was observed after immobilization whereas Vmax value was lower for the immobilized GOD. Immobilized glucose oxidase showed improved operational stability by maintaining 33% of the initial activity after 35 cycles of repeated use and was found to retain 94% of activity after 1 month storage period. Improved resistance against urea denaturation was achieved and the immobilized glucose oxidase retained 50% of the activity without urea in the presence of 5M urea whereas free enzyme retained only 8% activity.     

葡萄糖氧化酶的有机相共价固定化

将葡萄糖氧化酶(GOD)在最适pH条件下冻干后,以戊二醛活化的壳聚糖为载体,分别在传统水相和1,4-二氧六环、乙醚、乙醇三种不同的有机相中进行共价固定化。通过比较水相固定化酶和有机相固定化酶的酶比活力、酶学性质及酶动力学参数,考察酶在有机相中的刚性特质对酶在共价固定化过程中保持酶活力的影响。结果表明,戊二醛浓度为0.1%、加酶量为80 mg/1 g载体、含水1.6%的1,4-二氧六环有机相固定化GOD与水相共价固定化GOD相比,酶比活力提高2.9倍,有效酶活回收率提高3倍;在连续使用7次后,1,4-二氧六环有机相固定化GOD的酶活力仍为相应水相固定化酶的3倍。在酶动力学参数方面,不论是表观米氏常数,最大反应速度还是转换数,1,4-二氧六环有机相固定化的GOD(Kmapp=5.63 mmol/L,Vmax=1.70μmol/(min.mgGOD),Kcat=0.304 s-1)都优于水相共价固定化GOD(Kmapp=7.33 mmol/L,Vmax=1.02μmol/(min.mg GOD),Kcat=0.221 s-1)。因此,相比于传统水相,GOD在合适的有机相中进行共价固定化可以获得具有更高酶活力和更优催化性质的固定化酶。该发现可能为酶蛋白在共价固定化时因构象改变而丢失生物活性的问题提供解决途径。     

Cross-linking of horseradish peroxidase adsorbed on polycationic films: utilization for direct dye degradation

Horseradish peroxidase (HRP) was immobilized on the polyaniline (PANI) grafted polyacrylonitrile (PAN) films. The maximum HRP immobilization capacity of the PAN-g-PANI-3 film was 221?μg/cm(2). The HRP-immobilized PAN-g-PANI-3 film retained 79?% of the activity of the same quantity free enzyme. The HRP-immobilized PAN-g-PANI-3 film was operated for the decolorization of two different benzidine-based dyes in the presence of hydrogen peroxide. The maximum decolorization grade was obtained at pH 6.0 for both dyes. The HRP-immobilized PAN-g-PANI-3 film was very effective for removal of Direct Blue-53 compared to Direct Black-38 from aqueous solutions. The immobilized HRP exhibited high resistance to proteolysis by trypsin compared to the free counterpart. Immobilized HRP preserved 83?% of its original activity even after 8?weeks of storage at 4?°C, while the free enzyme lost its initial activity after 3?weeks of storage period.     

Trehalase immobilization on aminopropyl glass for analytical use

Trehalase is the enzyme which hydrolyzes the disaccharide trehalose into two alpha-D-glucose molecules. In this article, we present the immobilization of trehalase on aminopropyl glass particles. The enzyme was extracted from Escherichia coli Mph2, a strain harboring the pTRE11 plasmid, which contains the trehalase gene. The partially purified enzyme had a specific activity of 356 U/mg and could be used for quantifying trehalose in the presence of sucrose, maltose, lactose, starch, and glycogen. Partially purified trehalase was immobilized by covalent coupling with retention of its catalytic activity. The support chosen for the majority of the experiments reported was aminopropyl glass, although spherisorb-5NH(2) and chitin were also tested. The immobilized enzyme was assayed continuously for 40 h, at pH 6.0 and 30 degrees C, and no release of enzyme molecules was detected during this procedure. The best condition found for storing the enzyme-support complex was at 4 degrees C in the presence of 25 mM sodium maleate, containing 7 mM beta-mercaptoethanol, 1 mM ethylenediaminetetraacetic acid (EDTA), and 50% glycerol. The enzyme under these conditions was stable, retaining approximately 100% of its initial activity for at least 28 days. The immobilized enzyme can be employed to detect trehalose molecules in micromolar concentration. The optimum pH value found was 4.5 and the K(m) app. 4.9 x 10(-3) M trehalose at pH 4.6 and 30 degrees C, with V(max) of 5.88 mumol glucose . min.(-1), as calculated by a Lineweaver-Burk plot. (c) 1997 John Wiley & Sons, Inc. Biotechnol Bioeng 54: 33-39, 1997.     

Simultaneous and sequential co-immobilization of glucose oxidase and catalase onto florisil

The co-immobilization of Aspergillus niger glucose oxidase (GOD) with bovine liver catalase (CAT) onto florisil (magnesium silicate-based porous carrier) was investigated to improve the catalytic efficiency of GOD against H2O2 inactivation. The effect of the amount of bound CAT on the GOD activity was also studied for 12 different initial combinations of GOD and CAT, using simultaneous and sequential coupling. The sequentially co-immobilized GOD-CAT showed a higher efficiency than the simultaneously co-immobilized GOD-CAT in terms of the GOD activity and economic costs. The highest activity was shown by the sequentially co-immobilized GOD-CAT when the initial amounts of GOD and CAT were 10 mg and 5 mg per gram of carrier. The optimum pH, buffer concentration, and temperature for GOD activity for the same co-immobilized GOD-CAT sample were then determined as pH 6.5, 50 mM, and 30 degrees C, respectively. When compared with the individually immobilized GOD, the catalytic activity of the co-immobilized GOD-CAT was 70% higher, plus the reusability was more than two-fold. The storage stability of the co-immobilized GOD-CAT was also found to be higher than that of the free form at both 5 degrees C and 25 degrees C. The increased GOD activity and reusability resulting from the co-immobilization process may have been due to CAT protecting GOD from inactivation by H2O2 and supplying additional O2 to the reaction system.     

Implantable hollow fiber bioreactor as a potential treatment for hypercholesterolemia: characterization of the catalytic unit

Previous studies have shown that the modification of low density lipoprotein (LDL) by the enzyme phospholipase A(2)(PLA(2))results in a reduction of cholesterol levels in the plasma of hypercholesterolemic rabbits, due to accelerated clearance of the modified LDL. In the current study, we established techniques and optimized the ratio of enzyme to support for the immobilization of PLA(2) on a polymeric support. Hollow fiber bioreactors made from polytetrafluoroethylene (PTFE) polymers were used to encapsulate immobilized PLA(2). This design was adopted to eliminate hemolysis of red blood cells by the enzyme. Characterization of the resulting immobilized enzyme in terms of its activity, Michaelis-Menten kinetic constants, and the variation of its activity with incubation time is presented. The enzyme activity was not significantly altered upon incubation at 37 degrees C in lipoprotein-deficient serum (LPDS), over the course of 2 months. The Michaelis-Menten kinetics constants are K(M) = 8.9 mM, V(max) = 6434.2 for the free enzyme and K(app) (M) = 16.7 mM, V(app) (max) = 619.7 for the immobilized enzyme. These data suggest that a system based on immobilized PLA(2) in conjunction with hollow fiber bioreactors (HFBs) may be a good candidate for lowering LDL levels in plasma. (c) 1995 John Wiley & Sons, Inc.     

Kinetic studies of sepharose-and CH-sepharose-immobilized dihydrofolate reductase

Dihydrofolate reductase, purified to homogeneity from amethopterin-resistant Lactobacillus casei, was immobilized by coupling to cyanogen bromide-activated Sepharose or carbodiimide-activated CH-Sepharose. Coupling yields were determined by amino acid analysis following the hydrolysis of the gel. Enzyme activity was measured by the conventional spectrophotometric procedure, thus permitting the facile characterization of the immobilized enzyme. The pH optimum of the immobilized enzyme was shifted to 5.8 compared with pH 5.5 for the soluble enzyme. The immobilized enzyme retained greater than 90%of the initial activity over a six-month period and could be reused as many as ten times without loss of activity. As observed with the soluble enzyme, the activity of immobilized enzyme, which was lost on denaturation with 4M guanidine hydrochloride, was recovered rapidly and completely by washing the gel with buffer. The K(m) (app) values for dihydrofolate and NADPH for the immobilized enzyme were increased 15-164-fold over the K(m) values measured for soluble dihydrofolate reductase. Scatchard analysis of the interaction of amethopterin with the immobilized enzyme yielded linear plots and a K(d) (app) value of 0.56 x10(-8)M, and revealed that all of the immobilized enzyme molecules were capable of binding the ligand.     

Glucose oxidase as label in histological immunoassays with enzyme-amplification in a two-step technique: coimmobilized horseradish peroxidase as secondary system enzyme for chromogen oxidation

A sensitive staining procedure for glucose oxidase (GOD) as marker in immunohistology is described. The cytochemical procedure involves a two-step enzyme method in which GOD and horseradish peroxidase (HRP) are coimmobilized onto the same cellular sites by immunological bridging or by the principle of avidin-biotin interaction. In this coupled enzyme technique, H2O2 generated during GOD reaction is the substrate for HRP and is utilized for the oxidation of chromogens such as 3,3'-diaminobenzidine or 3-amino-9-ethylcarbazole. Due to the immobilization of the capture enzyme HRP in close proximity to the marker enzyme (GOD), more intense and specific staining is produced than can be obtained with soluble HRP as coupling enzyme in the substrate medium. Indirect antibody labelled and antibody bridge techniques including the avidin (streptavidin)-biotin principle have proven the usefulness of this GOD labelling procedure for antigen localization in paraffin sections. Antigens such as IgA in tonsil, alpha-fetoprotein in liver and tissue polypeptide antigen in mammary gland served as models. The immobilized two-step enzyme procedures have the same order of sensitivity and specificity as comparable immunoperoxidase methods. The coupled GOD-HRP principle can be superior to conventional immunoperoxidase labelling for the localization of biomolecules in tissue preparations rich in endogenous peroxidase activities.     

Immobilization of glucose oxidase with Bombyx mori silk fibroin by only stretching treatment and its application to glucose sensor

Glucose oxidase (GOD) was immobilized in Bombyx mori silk fibroin membrane by only physical treatment, i.e., stretching without any chemical reagents. This is due to the structural transition of the silk fibroin membrane from random coil to antiparallel beta-sheet (Silk II) induced by the stretching treatment. Permeability coefficients of glucose and oxygen through the fibroin membrane were determined; the permeability of glucose decreased with increasing degree of stretching. The immobilized enzyme activity was characterized with apparent Michaelis constant K(m) (app) and maximal activity V(m). Optimum pH of the activity of the immobilized enzyme was shifted to the value around neutrality, and the activity was maintained to the higher values on both sides of the optimum pH compared with the case of free enzymes. Thermal stability was scarcely lost even at 50 degrees C, although the free enzyme lost about 70% of the original activity. Thus, the stabilities of the enzyme vs. pH and heat were much improved by the immobilization with silk. Glucose sensor prepared with this GOD-immobilized fibroin membrane was developed; the capabilities such as the response time, calibration curve, and repeating usage were determined.     

Poly(2-hydroxyethyl methacrylate) for enzyme immobilization: impact on activity and stability of horseradish peroxidase

On the basis of their versatile structure and chemistry as well as tunable mechanical properties, polymer brushes are well-suited as supports for enzyme immobilization. However, a robust surface design is hindered by an inadequate understanding of the impact on activity from the coupling motif and enzyme distribution within the brush. Herein, horseradish peroxidase C (HRP C, 44 kDa), chosen as a model enzyme, was immobilized covalently through its lysine residues on a N-hydroxysuccinimidyl carbonate-activated poly(2-hydroxyethyl methacrylate) (PHEMA) brush grafted chemically onto a flat impenetrable surface. Up to a monolayer coverage of HRP C is achieved, where most of the HRP C resides at or near the brush-air interface. Molecular modeling shows that lysines 232 and 241 are the most probable binding sites, leading to an orientation of the immobilized HRP C that does not block the active pocket of the enzyme. Michaelis-Menten kinetics of the immobilized HRP C indicated little change in the K(m) (Michaelis constant) but a large decrease in the V(max) (maximum substrate conversion rate) and a correspondingly large decrease in the k(cat) (overall catalytic rate). This indicates a loss in the percentage of active enzymes. Given the relatively ideal geometry of the HRPC-PHEMA brush, the loss of activity is most likely due to structural changes in the enzyme arising from either secondary constraints imposed by the connectivity of the N-hydroxysuccinimidyl carbonate linking moiety or nonspecific interactions between HRP C and DSC-PHEMA. Therefore, a general enzyme-brush coupling motif must optimize reactive group density to balance binding with neutrality of surroundings.     

Glucose oxidase as label in histological immunoassays with enzyme-amplification in a two-step technique: coimmobilized horseradish peroxidase as secondary system enzyme for chromogen oxidation

Summary A sensitive staining procedure for glucose oxidase (GOD) as marker in immunohistology is described. The cytochemical procedure involves a two-step enzyme method in which GOD and horseradish peroxidase (HRP) are coimmobilized onto the same cellular sites by immunological bridging or by the principle of avidin-biotin interaction. In this coupled enzyme technique, H₂O₂ generated during GOD reaction is the substrate for HRP and is utilized for the oxidation of chromogens such as 3,3-diaminobenzidine or 3-amino-9-ethylcarbazole. Due to the immobilization of the capture enzyme HRP in close proximity to the marker enzyme (GOD), more intense and specific staining is produced than can be obtained with soluble HRP as coupling enzyme in the substrate medium. Indirect antibody labelled and antibody bridge techniques including the avidin (streptavidin)-biotin principle have proven the usefulness of this GOD labelling procedure for antigen localization in paraffin sections. Antigens such as IgA in tonsil, alpha-feroprotein in liver and tissue polypeptide antigen in mainmary gland served as models. The immobilized twostep enzyme procedures have the same order of sensitivity and specificity as comparable immunoperoxidase methods. The coupled GOD-HRP principle can be superior to conventional immunoperoxidase labelling for the localization of biomolecules in tissue preparations rich in endogenous peroxidase activities.     

Preparation and characterization of enzymes immobilized by graft copolymerization to different polysaccharides

A method of enzyme immobilization by graft copolymerization on polysaccharides is reported. Glycidylmethacrylate was used as a vinylating reagent and the reaction product with enzymes (HRP, GOD, Am, ChT) was copolymerized with different matrices (cellulose, Sepharose, Sephadex, Starch). Various factors affect the final activity of copolymers; these include the redox system, the type of support, and the quantity and type of vinyl monomer added. Using a fixed quantity of enzyme and support (3 mg enzyme, 100 mg support), the coupling efficiency varied from 2 to 50%. The most important characteristics in these immobilized systems were tested (stability in continuous washing, kinetic characteristics, storage, thermal, and lyophilization stability). Immobilized-enzyme graft copolymers have very similar kinetic behavior to that of the free enzyme. Diffusion is not seriously limited, as shown by kinetic parameters and energy activation values, and this indicates that the immobilization reaction does not alter the enzymatic activity.     

Covalent immobilization of glucose oxidase onto poly(styrene-co-glycidyl methacrylate) monodisperse fluorescent microspheres synthesized by dispersion polymerization

In this study, micron-sized poly(styrene-co-glycidyl methacrylate) (PSt-GMA) fluorescent microspheres of 5.1microm in diameter were synthesized via dispersion polymerization of styrene and glycidyl methacrylate in the presence of 1,4-bis(5-phenyloxazol-2-yl) benzene (POPOP), which provided surface functional groups for covalent immobilization of enzymes. In an effort to study the biocompatibility of the microspheres' surface, glucose oxidase and beta-d-(+)-glucose were selected as a catalytic system for enzymatic assays. A colorimetric method was adopted in evaluating enzymatic activity by introducing horseradish peroxidase (HRP). Both the immobilization amount and the apparent activity of immobilized glucose oxidase from Aspergillus niger (GOD) were determined at different conditions. The results show that the immobilized enzymes retained approximately 28 to 34% activity, as compared with free enzymes, without pronounced alteration of the optimum pH and temperature. Kinetics studies show that the corresponding values of K(m) and V(max) are 23.2944 mM and 21.6450M/min.mg GOD for free enzymes and 35.1780 mM and 15.4799M/min.mg GOD for immobilized enzymes. The operational stability studies show that immobilized GOD could retain nearly 50% initial activity after being washed 20 times. The results suggest that the resultant PSt-GMA fluorescent microspheres provide a suitable surface for covalent immobilizing biomolecules; therefore, they have the potential of being used in fluorescence-based immunoassays in high-throughput screening or biosensors.     

Immobilization of horseradish peroxidase on activated wool

This work is aimed to immobilize partially purified horseradish peroxidase (HRP) on wool activated by multifunctional reactive center, namely cyanuric chloride. The effect of cyanuric chloride concentration, pH and enzyme concentration on immobilization of HRP was studied. FT-IR and SEM analyses were detected for wool, activated wool and immobilized wool-HRP. The wool-HRP, prepared at 2% (w/v) cyanuric chloride and pH 5.0, retained 50% of initial activity after seven reuses. The wool-HRP showed broad optimum pH at 7.0 and 8.0, which was higher than that of the soluble HRP (pH 6.0). The soluble HRP had an optimum temperature of 30 °C, which was shifted to 40 °C for immobilized enzyme. The soluble and wool-HRP were stable up to 30 and 40 °C after incubation for 1 h, respectively. The apparent kinetic constant values (K_ms) of wool-HRP were 10 mM for guiacol and 2.5 mM for H₂O₂, which were higher than that of soluble HRP. The wool-HRP was remarkably more stable against proteolysis mediated by trypsin. The wool-HRP exhibited more resistance to heavy metal induced inhibition. The wool-HRP was more stable to the denaturation induced by urea, Triton X-100, isopropanol, butanol and dioxan. The wool-HRP was found to be the most stable under storage. In conclusion, the wool-HRP could be more suitable for several industrial and environmental purposes.     

Enhancement of stability of immobilized glucose oxidase by modification of free thiols generated by reducing disulfide bonds and using additives

Stability of glucose oxidase (GOD) immobilized with lysozyme has been considerably enhanced by modification of free thiols generated by reducing disulfide bonds using beta-mercaptoethanol and N-ethylmaleimide in conjunction with additives like antibiotics and salts. Thermal stability of immobilized GOD was quantified by means of the transition temperature, Tm and the operational stability by half-life t1/2 at 70 degrees C. Modification of the free thiols in the enzyme coupled with the presence of kanamycin, NaCl, and K2SO4, led to increase in Tm, to 80, 82 and 84 degrees C (compared to 75 degrees C in control) and t1/2 by 7.7-, 11- and 22-fold, respectively, indicating that this method can be effectively used for enhancing the stability of enzymes.     

Surface functionalization of porous polypropylene membranes with polyaniline for protein immobilization

Commercial porous polypropylene membranes were chemically modified with polyaniline (PANI) using ammonium persulfate as the oxidizer. The influence of polymerization conditions on the membrane properties was studied by adsorption analysis and membrane permeability. The PANI-coated polypropylene (PANI/PP) membranes possessed high affinity toward the proteins, which can be immobilized onto the membrane surface through physical adsorption or covalent immobilization. The quantity of immobilized horseradish peroxidase (HRP) and its activity depended on the quantity and quality (oxidation level) of PANI. The storage conditions for PANI/PP membranes containing immobilized HRP were studied. HRP immobilized on the PANI/PP membrane was shown to retain 70% of its activity after 3-month storage at +5 degrees C, suggesting that this material can be used for practical application, such as in bioreactors as enzyme membranes.     

Studies on the activity and stability of immobilized horseradish peroxidase on poly(ethylene terephthalate) grafted acrylamide fiber

Having been activated with glutaraldehyde, modified poly(ethylene terephthalate) grafted acrylamide fiber was used for the immobilization of horseradish peroxidase (HRP). Both the free HRP and the immobilized HRP were characterized by determining the activity profile as a function of pH, temperature, thermal stability, effect of organic solvent and storage stability. The optimum pH values of the enzyme activity were found as 8 and 7 for the free HRP and the immobilized HRP respectively. The temperature profile of the free HRP and the immobilized HRP revealed a similar behaviour, although the immobilized HRP exhibited higher relative activity in the range from 50 to 60 °C. The immobilized HRP showed higher storage stability than the free HRP.     

Fabrication of hydrogen peroxide biosensor based on Ni doped SnO2 nanoparticles

Ni doped SnO(2) nanoparticles (0-5 wt%) have been prepared by a simple microwave irradiation (2.45 GHz) method. Powder X-ray diffraction (XRD) and transmission electron microscopy (TEM) studies confirmed the formation of rutile structure with space group (P(42)/mnm) and nanocrystalline nature of the products with spherical morphology. Direct electrochemistry of horseradish peroxidase (HRP)/nano-SnO(2) composite has been studied. The immobilized enzyme retained its bioactivity, exhibited a surface confined, reversible one-proton and one-electron transfer reaction, and had good stability, activity and a fast heterogeneous electron transfer rate. A significant enzyme loading (3.374×10(-10) mol cm(-2)) has been obtained on nano-Ni doped SnO(2) as compared to the bare glassy carbon (GC) and nano-SnO(2) modified surfaces. This HRP/nano-Ni-SnO(2) film has been used for sensitive detection of H(2)O(2) by differential pulse voltammetry (DPV), which exhibited a wider linearity range from 1.0×10(-7) to 3.0×10(-4)M (R=0.9897) with a detection limit of 43 nM. The apparent Michaelis-Menten constant (K(M)(app)) of HRP on the nano-Ni-SnO(2) was estimated as 0.221 mM. This excellent performance of the fabricated biosensor is attributed to large surface-to-volume ratio and Ni doping into SnO(2) which facilitate the direct electron transfer between the redox enzyme and the surface of electrode.     

High-performance bioanode based on the composite of CNTs-immobilized mediator and silk film-immobilized glucose oxidase for glucose/O2 biofuel cells

A high-performance bioanode based on the composite of carbon nanotubes (CNTs)-immobilized mediator and silk film (SF)-immobilized glucose oxidase (GOD) was developed for glucose/O(2) biofuel cell (BFC). Ferrocenecarboxaldehyde (Fc) was used as the mediator and covalently immobilized on the ethylenediamine (EDA)-functionalized CNTs (CNTs-EDA). GOD was cross-linked on the SF with glutaraldehyde (GA) as the cross-linking agent. The resulting electrode (CNTs-Fc/SF-GOD/glassy carbon (GC) electrode) exhibited good catalytic activity towards glucose oxidation and excellent stability. For the assembled glucose/O(2) BFC with the CNTs-Fc/SF-GOD/GC electrode as the bioanode and a commercial E-TEK Pt/C modified GC electrode as the cathode, the open circuit potential is 0.48 V and the maximum power density of 50.70 μW cm(-2) can be achieved at 0.15 V.     

Monovalent cation-induced conformational change in glucose oxidase leading to stabilization of the enzyme

Glucose oxidase (GOD) from Aspergillus niger is an acidic dimeric enzyme having a high degree of localization of negative charges on the enzyme surface and dimer interface. We have studied the effect of monovalent cations on the structure and stability of GOD using various optical spectroscopic techniques, limited proteolysis, size exclusion chromatography, differential scanning calorimetry, and enzymic activity measurements. The monovalent cations were found to influence the enzymic activity and tertiary structure of GOD, but no effect on the secondary structure of the enzyme was observed. The monovalent cation-stabilized GOD was found to have a more compact dimeric structure but lower enzymic activity than the native enzyme. The enzyme's K(m) for D-glucose was found to be slightly enhanced for the monovalent cation-stabilized enzyme (maximum enhancement of about 35% for LiCl) as compared to native GOD. Comparative denaturation studies on the native and monovalent cation-stabilized enzyme demonstrated a significant resistance of cation-stabilized GOD to urea (about 50% residual activity at 6.5 M urea) and thermal denaturation (Delta T(m) maximum of 10 degrees C compared to native enzyme). However, pH-induced denaturation showed a destabilization of monovalent cation-stabilized GOD as compared to the native enzyme. The effectiveness of monovalent cations in stabilizing GOD structure against urea and thermal denaturation was found to follow the Hofmeister series: K(+) > Na(+) > Li(+).