Optimization of the coating of octyl-CALB with ionic polymers to improve stability and decrease enzyme leakage

Abstract

Lipase B from Candida antarctica (CALB) immobilized on octyl-agarose (OC) was submitted to coating with polyethylenimine (PEI) and dextran sulfate (DS). Using lowly loaded enzyme preparations, the properties of OC-CALB preparations hardly improved, suggesting too large the distance between enzyme molecules. However, using OC-CALB preparations with maximum loading, CALB stability was greatly improved in different conditions after PEI coating. Moreover, the CALB release from the OC support in the presence of detergents, or during thermal or organic solvent inactivations was greatly reduced after this treatment (PEI plus DS coating). The results pointed that the main positive effect of this coating could be derived from the physical intermolecular crosslinking of the CALB molecules with the polymers that reduce the enzyme desorption from the support. The coating of OC-CALB-PEI with DS only produced a minimal improvement on enzyme performance. Even though the enzyme release was much more difficult after physical crosslinking, all enzyme molecules could be released from the OC support combining an ionic detergent (SDS), high buffer concentration, pH 3 and 45?°C, while using the OC-CALB just 2% SDS at pH 7 and 25?°C was enough to release all enzyme. The support could be reused several cycles. Thus, this strategy permitted to greatly reduce the enzyme desorption during operation and to improve enzyme stability while keeping the enzyme immobilization reversibility.     

Kinetics of enzyme action of Cartazyme NS-10 prior to bleaching of kraft pulp

The kinetics of enzyme treatment of hardwood kraft pulp with commercial xylanase Cartazyme NS-10 was investigated. The enzyme treatment process was found to follow closely the topochemical modified equation of Prout–Tompkins. The influence of the initial enzyme concentration was studied and the applicability of the power kinetic equation was established for the initial rate of the process. An equation of practical use was obtained, which provides the temperature function of the amount of the reducing substances, depending on the enzyme initial concentration. This function made it possible to control the process of prior enzyme treatment of unbleached kraft pulp.     

Polyvinylamine‐coated polyester fibers as a carrier matrix for the immobilization of peroxidases

Biocatalytic transformations that employ immobilized enzymes become increasingly important for industrial applications. Synthetic or natural textile fiber materials such as polyester, polyamide or viscose are support materials that are comparatively inexpensive. Contrary to traditional support materials, their flexibility enables their use in reactors of any geometry and a fast and residue‐free removal from batch reactors. In this study a permanently immobilized peroxidase (Baylase®) has been investigated on polyester felt as a solid support as a new heterogeneous catalyst system. The polyester felt was functionalized by coating with polyvinylamine and subsequent activation with glutaraldehyde as a crosslinking agent. The enzyme load on the textile surface, the activity of the immobilized protein after repeated use as well as the storage stability was evaluated. Scanning electron micrographs and UV Vis spectroscopy made it possible to verify the enzyme immobilization on the textile surface. Furthermore, the load of immobilized peroxidase was determined by ICP OE spectrometry to be 9–12 mg per gram of textile. The activity of immobilized Baylase® remained high over 35 reaction cycles and a storage period of 8 weeks.     

亚栖热菌透性化细胞的耦合固定化研究

将海藻酸盐凝胶包埋法与交联法和聚电解质静电自组装覆膜法相耦合,对含有海藻糖合酶活性的亚栖热菌的透性化细胞进行了固定化研究。结果表明,利用重氮树脂和聚苯乙烯磺酸钠对海藻酸凝胶微球交替覆膜,可以显著提高凝胶微球在磷酸盐缓冲液中的稳定性,以碳二亚胺对固定化细胞进行交联处理则可以提高固定化细胞中海藻糖合酶的热稳定性。透性化细胞经包埋－交联－覆膜耦合固定化后,酶活回收率为32％,最适酶反应pH值由6.5左右升至7.0左右,最适反应温度未变,仍为60℃。所得固定化细胞间歇反应时,催化麦芽糖转化为海藻糖的转化率可达60％,重复使用4次（每次50℃、反应24h）,酶活损失小于20％,转化率可保持在50％以上。     

微胶囊固定化过氧化氢酶的制取及对H_2O_2的分解作用

以乙基纤维素为膜材,用溶液干燥法制取了微胶囊固定化过氧化氢酶,探讨了制取过程中明胶的加入对微胶囊产率及固定化过氧化氢酶活性的影响,同时论述了存放时间、温度以及环境ｐＨ值对微胶囊固定化过氧化氢酶稳定性的影响．深入研究了微胶囊固定化过氧化氢酶对Ｈ２Ｏ２的分解作用,获得了十分有意义的结果     

Hydrolysis of milk lactose by immobilized beta-galactosidase-hen egg white powder

Immobilized beta-galactosidase was obtained by crosslinking the enzyme with hen egg white using 2% glutaraldehyde. The gel obtained could be lyophilized to give a dry enzyme powder. The pH optimum of both the soluble and immobilized enzyme was found to be 6.8. The immobilized enzyme showed a higher K(m) for the substrates. The extent of enzyme inhibition by galactose was reduced upon immobilization. The stability towards inactivation by heat, urea, gamma irradiation, and protease treatment were enhanced. The bound enzyme as tested in a batch reactor could be used repeatedly for the hydrolysis of milk lactose. The possible application of this system for small-scale domestic use has been suggested.     

Catalytic properties of thioredoxin immobilized on superparamagnetic nanoparticles

Thioredoxin (Trx1), a very important protein for regulating intracellular redox reactions, was immobilized on iron oxide superparamagnetic nanoparticles previously coated with 3-aminopropyltriethoxysilane (APTS) via covalent coupling using the EDC (1-ethyl-3-{3-dimethylaminopropyl}carbodiimide) method. The system was extensively characterized by atomic force microscopy, vibrational and magnetic techniques. In addition, gold nanoparticles were also employed to probe the exposed groups in the immobilized enzyme based on the SERS (surface enhanced Raman scattering) effect, confirming the accessibility of the cysteines residues at the catalytic site. For the single coated superparamagnetic nanoparticle, by monitoring the enzyme activity with the Ellman reagent, DTNB = 5,5′-dithio-bis(2-15 nitrobenzoic acid), an inhibitory effect was observed after the first catalytic cycle. The inhibiting effect disappeared after the application of an additional silicate coating before the APTS treatment, reflecting a possible influence of unprotected iron-oxide sites in the redox kinetics. In contrast, the doubly coated system exhibited a normal in-vitro kinetic activity, allowing a good enzyme recovery and recyclability.     

Purine pyrophosphorylase as a selective genetic marker in a mouse lymphoma, P388, in cell culture

It is possible to use the purine pyrophosphorylase in mammalian cell culture systems as a genetic marker in selecting small numbers of enzyme positive cells from large populations of pyrophosphorylase negative cells of the mouse lymphoma line P388 in medium containing amethopterin, hypoxanthine, glycine and thymidine. Conversely, it is readily possible to obtain pyrophosphorylase-deficient cells by treatment with 8-Azaguanine. We were unsuccessful in demonstrating DNA-mediated transformation using DNA from enzyme positive cells incubated with cells which were enzyme negative.     

Functionalization of magnetic nanowires by charged biopolymers

We report on a facile method for the preparation of biocompatible and bioactive magnetic nanowires. The method consists of the direct deposition of polysaccharides by layer-by-layer (LbL) assembly onto a brush of metallic nanowires obtained by electrodeposition of the metal within the nanopores of an alumina template supported on a silicon wafer. Carboxymethylpullulan (CMP) and chitosan (CHI) multilayers were grown on brushes of Ni nanowires; subsequent grafting of an enzyme was performed by conjugating free amine side groups of chitosan with carboxylic groups of the enzyme. The nanowires are finally released by a gentle ultrasonic treatment. Transmission electron microscopy, electron energy-dispersive loss spectroscopy, and x-ray photoelectron spectroscopy indicate the formation of an homogeneous coating onto the nickel nanowires when one, two, or three CMP/CHI bilayers are deposited. This easy and efficient route to the biochemical functionalization of magnetic nanowires could find widespread use for the preparation of a broad range of nanowires with tailored surface properties.     

Konjac glucomannan hydrolysate: A potential natural coating material for bioactive compounds in spray drying encapsulation

This research aimed to develop a suitable coating material for encapsulating a plant bioactive compound via spray drying. A suitable process for modifying the rheological property of konjac glucomannan (KGM) solution by enzymatic treatment was developed. A plant bioactive compound, andrographolide, was selected to use as core material. Mannanase (1500 units of enzyme) was used in the treatment of KGM solution. The concentration of KGM solution was varied from 9 to 18% (w/w). It was found that 12% (w/w) was the optimum KGM concentration that could be hydrolyzed to a viscosity of <100 mPa·s. HPLC analysis of hydrolyzed solution found a fair amount of DP4–DP7 oligosaccharides (where DP is degree of polymerization) were obtained. The solution was then used as coating material in spray drying with inlet air temperature of 170°C and outlet air temperature of 85°C. It was found that 12% (w/w) konjac glucomannan hydrolysate (KGMH) was suitable for coating 2% (w/w) andrographolide. Its efficiency of encapsulation was also higher than that of KGMH combined with gamma‐cyclodextrin or beta‐cyclodextrin. This study revealed a great potential of using KGMH solution for pharmaceutical and food industries in the spray drying encapsulation process.     

β-Glucosidase coating on polymer nanofibers for improved cellulosic ethanol production

β-Glucosidase (βG) can relieve the product inhibition of cellobiose in the cellulosic ethanol production by converting cellobiose into glucose. For the potential recycled uses, βG was immobilized and stabilized in the form of enzyme coating on polymer nanofibers. The βG coating (EC-βG) was fabricated by crosslinking additional βG molecules onto covalently attached βG molecules (CA-βG) via glutaraldehyde treatment. The initial activity of EC-βG was 36 times higher than that of CA-βG. After 20 days of incubation under shaking, CA-βG and EC-βG retained 33 and 91% of each initial activity, respectively. Magnetic nanofibers were also used for easy recovery and recycled uses of βG coating. It is anticipated that the recycled uses of highly active and stable βG coating can improve the economics of cellulosic ethanol production so long as economical materials are employed as a host of enzyme immobilization.     

Nonporous magnetic materials as enzyme supports: studies with immobilized chymotrypsin.

Chymotrypsin has been immobilized to several nonporous magnetic materials. Nickel particles were considered to be most suitable as immobilized enzyme supports. Chymotrypsin immobilized to nonporous magnetic supports was not fouled significantly by either whole milk or clarified yeast homogenate. AE-cellulose-chymotrypsin was rapidly fouled by both these materials and chymotrypsin immobilized to acrylic-based ion exchangers was slowly fouled. Immobilized enzyme activity was found to be inversely proportional to particle diameter for nonporous rock magnetic particles. Immobilization by adsorption and then glutaraldehyde crosslinking was used to produce controlled amounts of chymotrypsin on the particles. Esterolytic activity increased with enzyme loading but caseinolytic activity did not increase. Chymotrypsin is inhibited by metal ions from the magnetic supports. It is partially protected by use of a preliminary protein coating and may be reactivated by incubation with EDTA or BSA.     

Combined strategy for preparation of a bioimprinted Geotrichum sp. lipase biocatalyst effective in non-aqueous media

Geotrichum sp. lipase with enhanced activity and operational stability was prepared for use in non-aqueous media. A combined strategy comprising bioimprinting with dual imprint molecules and a co-solvent coupled to pH tuning, KCl salt activation, lecithin coating and immobilization on macroporous resin effectively enhanced the activity and operational stability of Geotrichum sp. lipase. The modified lipase exhibited 18.4-fold enhanced esterification activity towards methyl oleate synthesis, and retained 90% activity following repeated use in 10 cycles. The combined strategy exhibited a significant synergistic effect and was suitable for lipase modification, dramatically enhancing the enzyme activity and operational stability. This approach is applicable to the preparation of other enzyme biocatalysts, since the methods are effective for upgrading crude enzyme to a refined product with high activity and stability for use in non-aqueous media.     

Comparative study of the properties of preparations of native and modified collagenase

Collagenase was gradually modified by aldehyde dextran and hyaluronidase. The modification increased enzyme stability and widened pH-optimum of its activity against specific and biological substrates. The modified complex with collagenolytic and hyaluronidase activity accumulated in the lungs of mice after intravenous injection. These results demonstrate its possible use for the treatment of lung disorders.     

Purine salvage enzymes of parasites as targets for structure-based inhibitor design

Nearly 30 years have passed since purine salvage enzymes were first proposed as targets of drugs in the chemotherapeutic treatment of diseases caused by parasites. The rationale behind a structure-based approach to the design of chemotherapeutic agents involves the use of information about substrate preference and the three-dimensional structure of a target enzyme to design potent selective inhibitors of that enzyme. This approach is outlined here by Syd Craig and Ann Eakin, as it applies to the possible design of inhibitors of a purine salvage enzyme, the hypoxanthine phosphoribosyltransferase.     

Studies on Cellulose Synthesis by a Cell-free Oat Coleoptile Enzyme System: Inactivation by Airborne Oxidants

Particulate cell wall polysaccharide synthetase from oat coleoptiles could use either guanosine diphosphate glucose or uridine diphosphate glucose; the latter was a much more effective glucose donor. The neutral polymer derived from uridine diphosphate glucose utilization yielded, after cellulase digestion, mostly cellobiose and to a lesser extent a substance tentatively identified as a mixed-linkage β1,4 = β1,3-trisaccharide; only cellobiose was found after guanosine diphosphate glucose utilization. The uridine diphosphate glucose utilizing system was inactivated by peroxyacetyl nitrate treatment of intact tissue and to a lesser extent by ozone treatment suggesting that this system is a possible site of interference with cellulose and non-cellulosic glucan biosynthesis in vivo. Direct treatment of the enzyme in vitro by peroxyacetyl nitrate, iodoacetamide or p-chloromercuribenzoate also inactivated the enzyme, indicating that the mechanism of inactivation possibly involves reaction with sulfhydryl groups.     

The use of chitosan solutions for defatting and clarification of protein hydrolysates]

The possibility of the use of small amounts of chitosan for defatting and clarification of protein solutions prepared by enzymatic hydrolysis was tested. The following treatment conditions were shown to be optimal: chitosan concentration range, from 1.0 to 1.5 g per kg raw weight; pH of precipitation medium, from 8.0 to 8.5; and duration of incubation of protein hydrolysate solution with chitosan, less than 1 h. The hydrolysate defatting grade was found to depend on the degree of chitosan deacetylation. A possible mechanism of the chitosan-induced effects was suggested. The use of chitosan allows the mass fraction of enzyme protein hydrolysates to be reduced fourfold to fivefold.     

Properties and repeated use of a reversibly soluble-insoluble yeast lytic enzyme

Summary A yeast lytic enzyme was covalently immobilized on an enteric coating polymer, Eudragit S, that is reversibly soluble and insoluble (S-IS) depending on the pH of the reaction medium. The yeast lytic enzyme immobilized on Eudragit S (Y-E) showed a sharp response of solubility to slight changes in pH without decrease in enzymatic activity. The specific activity per amount of enzyme protein of Y-E for dry yeast cells was about two-thirds that of the native enzyme. In both lysis reactions of dry and pressed baker's yeast cells, changing the pH of the reaction medium from 7.0 to 4.8 at an appropriate interval allows the insoluble Y-E and the reaction products (soluble protein for dry yeast cells and invertase and soluble protein for pressed baker's yeast cells) to be repeatedly separated. The reaction method using a reversible S-IS enzyme is a promising procedure for repeated use of the enzyme in a heterogeneous reaction system containing yeast cells as a substrate.     

An enzyme electrode for acetylcholine.

A new enzyme electrode is described to measure continuously acetylcholine concentration. A coating containing active acetylcholinesterase is produced on a pH-glass electrode. The mean thickness of the coating is 50 micrometer. Optimal operational conditions with respect to buffer concentration, ionic strength, linearity, stability, sensitivity, pH of the bulk solution, and response time are studied and discussed. The use of acetylcholinesterase-containing membranes as sensors could offer several novel advantages.     

A comparison of enzyme immunoassay and bioassay for the quantitative determination of antibodies to tetanus toxin

Antibodies to tetanus toxin were induced in sheep by hyperimmunization over 24 weeks. Bleeds taken at weeks 4, 8, 20 and 30 were assayed for antibody titre by both an enzyme immunoassay (EIA) using a newly-described urease enzyme/substrate system and by bioassay in mice. There was a very good correlation between the two assay systems and, with the exception of the week 4 Bleeds, the relationship was the same at all stages of hyperimmunization regardless of titre, adjuvant, or whether toxin or toxoid was used as immunogen or for coating the plates. The results establish that the EIA can replace the bioassay for the determination of tetanus antitoxin in ovine sera.