亲水梳状环氧聚合物载体柔性固定化脂肪酶

以氯乙酰化聚苯乙烯微球载体为大分子引发剂,以甲基丙烯酸缩水甘油酯和亲水性丙烯酰胺为共聚接枝单体,以氯化亚铜及2,2'-联吡啶为催化体系,采用原子转移自由基聚合法接枝合成了具有柔性链的亲水梳状环氧聚合物载体PS-acyl-P(AM-co-GMA),并将其用于耐有机溶剂YCJ01脂肪酶的共价柔性固定化.结果表明,固定化酶催...     

Adsorption and activity of lipase from Candida rugosa on the chitosan-modified poly(acrylonitrile-co-maleic acid) membrane surface

Efforts have recently been made to improve the biocompatibility of support surface for enzyme immobilization, which could create a specific microenvironment for the enzymes and thus benefit the enzyme activity. In this work, one natural macromolecule, chitosan, was tethered on the surface of poly(acrylonitrile-co-maleic acid) (PANCMA) membrane to prepare a dual-layer biomimetic support for enzyme immobilization. Lipase from Candida rugosa was immobilized on this dual-layer biomimetic support by adsorption. The properties of the immobilized enzyme were assayed and compared with those of the free one. It was found that the adsorption capacity of lipase on the chitosan-tethered PANCMA membrane increases with the decrease of ionic strength and there is an optimum pH value for the adsorption. The activity retention of the immobilized lipase on the chitosan-tethered membrane by adsorption (54.1%) is higher than that by chemical bonding (44.5%). In comparison with the immobilized lipase by chemical bonding, there is a decrease of the K(m) value and an increase of the V(max) value for the immobilized lipase by adsorption. Additionally, the experimental results of thermal stabilities indicate that the residual activity of the immobilized lipase at 50 degrees C is 38% by adsorption and 65% by chemical bonding.     

Effect of Candida antarctica lipase B immobilization on the porous structure of the carrier

A series of poly(GMA-co-EGDMA) resins with identical composition but varying particle sizes, pore radii, specific surface areas and specific volumes are studied to assess how Candida antarctica lipase B immobilization affects the porosity of the copolymer particles. Mercury porosimetry reveals a significant change in the average pore size (up to 6.1-fold), the specific surface area (up to 3.2-fold) and the specific volume (up to 2.1-fold) of the epoxy resin. A similar behaviour is observed for glutaraldehyde-modified epoxy resins. The influences of the resin porosity properties on the loading of Candida antarctica lipase B during immobilization and on the hydrolytic activity (hydrolysis of p-nitrophenyl acetate) of the immobilized lipase are studied.     

Immobilization of Yarrowia lipolytica Lipase—a Comparison of Stability of Physical Adsorption and Covalent Attachment Techniques

Lipase immobilization offers unique advantages in terms of better process control, enhanced stability, predictable decay rates and improved economics. This work evaluated the immobilization of a highly active Yarrowia lipolytica lipase (YLL) by physical adsorption and covalent attachment. The enzyme was adsorbed on octyl–agarose and octadecyl–sepabeads supports by hydrophobic adsorption at low ionic strength and on MANAE–agarose support by ionic adsorption. CNBr–agarose was used as support for the covalent attachment immobilization. Immobilization yields of 71, 90 and 97% were obtained when Y. lipolytica lipase was immobilized into octyl–agarose, octadecyl–sepabeads and MANAE–agarose, respectively. However, the activity retention was lower (34% for octyl–agarose, 50% for octadecyl–sepabeads and 61% for MANAE–agarose), indicating that the immobilized lipase lost activity during immobilization procedures. Furthermore, immobilization by covalent attachment led to complete enzyme inactivation. Thermal deactivation was studied at a temperature range from 25 to 45°C and pH varying from 5.0 to 9.0 and revealed that the hydrophobic adsorption on octadecyl–sepabeads produced an appreciable stabilization of the biocatalyst. The octadecyl–sepabeads biocatalyst was almost tenfold more stable than free lipase, and its thermal deactivation profile was also modified. On the other hand, the Y. lipolytica lipase immobilized on octyl–agarose and MANAE–agarose supports presented low stability, even less than the free enzyme.     

Hydrogels préparés par le greffage radiochimique pour l'immobilisation des enzymes

The direct method of radiation grafting was used to cover poly(methyl methacrylate) tubes and rings with a thin layer of poly(acrylic acid) hydrogel. The copolymer formed is used as a support for covalent immobilization of enzymes. The enzyme support coupling was realized with carbodimide or glutaraldehyde. The activity of the immobilized chymotrypsin and peroxidase was determined and the stability of the enzyme-linked copolymers was tested.     

Preparation, characterization and performance of surface-loaded chelating resins for ion-chromatography

A procedure has been developed for the surface immobilization of 8-hydroxyquinoline on a gel-type poly(styrene-divinylbenzene) copolymer matrix. The exchange rates are shown to be favourable for ion-chromatography, and some rapid separations have been achieved.     

Chemical activation of egg shell membrane for covalent immobilization of enzymes and its evaluation as inert support in urinary oxalate determination

Egg shell membrane is a novel, robust, microporous, cost effective, easily available organic support material. In recent studies egg shell membranes were utilized as organic support for enzyme immobilization. But low conjugation yield limits its application as good support for biotechnological industries. In present study egg shell membrane was chemically treated to introduce free functional groups for covalent linkage of proteins to increase its conjugation yield and stability of conjugate complex. Many enzymes were tested for immobilization on modified egg shell membrane like oxalate oxidase, glucose oxidase, peroxidase and lipase. A fifteen to sixteen fold increase in conjugation yield was observed when immobilization was performed after chemical treatment in comparison to immobilization on native membrane with slight change in specific activity of immobilized enzyme which ranges from 5% to 15%. Egg shell membrane bound enzymes showed slight changes in their kinetic properties after immobilization. Egg shell membrane bound oxalate oxidase shows detection limit of 1.5 μM when used for urinary oxalate determination. Egg shell membrane support shows no interference to enzyme activity and a good correlation of 0.99 was observed with the values estimated using commercially available Sigma kit. The immobilized oxalate oxidase, glucose oxidase, peroxidase and lipase were stable up to duration of 180 days and there is respective loss of 10%, 13%, 24%, and 33% of initial activity. Overall result strengthens our view of using chemically modified egg shell membrane as solid support for better immobilization of enzymes and can be used in various biotechnological applications.     

Immobilized Lipase from Candida sp. 99–125 on Hydrophobic Silicate: Characterization and Applications

Lipase Candida sp. 99–125 has been proved to be quite effective in catalyzing organic synthesis reactions and is much cheaper than commercial lipases. Mesoporous silicates are attractive materials for the immobilization of enzymes due to their unique structures. The present research designed a hydrophobic silicate with uniform pore size suitable for the comfort of lipase Candida sp. 99–125 for improving its activity and stability. The resulting immobilized lipase (LP@PMO) by adsorption was employed to catalyze hydrolysis, esterification, and transesterification reactions, and the performances were compared with the lipase immobilized on hydrophilic silicate (LP@PMS) and native lipase. The LP@PMO showed as high activity as that of native lipase in hydrolysis and much increased catalytic activity and reusability in the reactions for biodiesel production. Besides, LP@PMO also possessed better organic stability. Such results demonstrate that immobilization of lipase onto hydrophobic supports is a promising strategy to fabricate highly active and stable biocatalysts for applications.     

Kinetic properties of soluble and immobilizedCandida rugosa lipase

Immobilized lipase (triacylglycerol ester hydrolase, EC 3.1.1.3) fromCandida rugosa has been immobilized on commercially available microporous polypropylene and used for the batch hydrolysis of different animal fats. The effect of the reaction products at concentrations similar to those obtained at 90% hydrolysis, both on soluble and immobilized lipase, was studied. Glycerol showed low inhibitory effect but oleic acid caused 50% inhibition. A mixture of free fatty acids present in the complete hydrolysis of beef tallow inhibited lipase activity more than 70%. The stability of the enzyme (both soluble and immobilized) was highest in the presence of 20% isooctane. The apparent Michaelis constant for each substrate for the soluble enzyme did not change on immobilization.     

Catalytic activity of lipase immobilized onto ultrathin films of cellulose esters

Ultrathin (approximately 2.0 nm) films of cellulose acetate (CA), cellulose acetate propionate (CAP), and cellulose acetate butyrate (CAB) supported on Si wafers have been prepared by adsorption and characterized by means of ellipsometry, atomic force microscopy (AFM), and contact angle measurements. CA, CAP, and CAB ultrathin films were characterized in air just after their formation and after annealing under reduced pressure at temperature higher than the corresponding melt temperature. Upon annealing, CA, CAP, and CAB ultrathin films became smoother and more hydrophobic, evidencing molecular reorientation at the solid-air interface. CA, CAP, and CAB films were used as supports for the immobilization of lipase. The adsorption of lipase onto annealed films was more pronounced than that onto untreated films, showing the strong affinity of lipase for the more hydrophobic substrates. Enzymatic activity was evaluated by a standard procedure, namely, (spectrophotometric) measurement of p-nitrophenol, the product formed from the hydrolysis of p-nitrophenyl dodecanoate (p-NPD). Lipase immobilized onto hydrophobic films exhibited higher activity than that of free lipase and could be recycled three times while retaining relatively high activity (loss of ca. 30% of original enzymatic activity). The effect of storing time on the activity of immobilized lipase was studied. Compared with free lipase, that immobilized onto more hydrophobic films retained 70% activity after 1 month. More importantly, the latter level of activity is similar to that of free lipase. However, lipase immobilized onto more hydrophilic films retained 50% and 30% activity after 20 and 30 days, respectively. These results are explained in terms of surface wettability and the contribution of the interactions between the polar residues of lipase and the glucopyranosyl moieties of cellulose ester to maintain the natural conformation of immobilized enzyme.     

Preparation and characterization of polyethylene based graft copolymers. Applications in the immobilization of enzymes

In the last few years new copolymeric supports for the immobilization of biological compounds have been developed. The graft copolymer polyethylene-g.co-hydroxyethyl methacrylate, partially hydrolyzed, has shown to be a very promising support for this purpose.

The more recent work in the preparation and characterization of this copolymer, as well as the immobilization of a lipase, is reported in this paper. Branches of poly(hydroxyethyl methacrylate) were grafted onto low density polyethylene by using gamma radiation. The influence of the presence and absence of air, as well as the monomer concentration on the yield of grafting were evaluated.

The obtained copolymers were characterized by DSC and FTIR. The influence of the support properties on the synthesis biocatalytic activity was detected.     

Lipase Immobilized on the Hydrophobic Polytetrafluoroethene Membrane with Nonwoven Fabric and Its Application in Intensifying Synthesis of Butyl Oleate

The synthesis of butyl oleate was studied in this paper with immobilized lipase. Five types of membrane were used as support to immobilize Rhizopus arrhizus lipase by following a procedure combining filtration and protein cross-linking. Results showed that hydrophobic polytetrafluoroethene membrane with nonwoven fabric (HO-PTFE-NF) was the favorite choice in terms of higher protein loading, activity, and specific activity of immobilized lipase. The factors including solvent polarity, lipase dosage, concentration, and molar ratio of substrate and temperature were found to have significant influence on conversion. Results showed that hexane (logP = 3.53) was a favorable solvent for the biosynthesis of butyl oleate in our studies. The optimal conditions were experimentally determined of 50 U immobilized lipase, molar ratio of oleic acid to butanol of 1.0, substrate concentration of 0.12 mol/L, temperature of 37 °C, and reaction time of 2 h. The conversion was beyond 91% and decreased slightly after 18 cycles. Lipase immobilization can improve the conversion and the repeated use of immobilized lipase relative to free lipase.     

Immobilization and Properties of Lipase from Candida rugosa on Electrospun Nanofibrous Membranes with Biomimetic Phospholipid Moities

Reported here is a protocol to fabricate a biocatalyst with high enzyme loading and activity retention, from the conjugation of electrospun nanofibrous membrane having biomimetic phospholipid moiety and lipase. To improve the catalytic efficiency and activity of the immobilized enzyme, poly（acrylonitrile-co-2-methacryloyloxyethyl phosphorylcholine）s（PANCMPCs） were, respectively, electrospun into nanofibrous membranes with a mean diameter of 90 nm, as a support for enzyme immobilization. Lipase from Candida rugosa was immobilized on these nanofibrous membranes by adsorption. Properties of immobilized lipase on PANCMPC nanofibrous membranes were compared with those of the lipase immobilized on the polyacrylonitrile（PAN） nanofibrous and sheet membranes, respectively. Effective enzyme loading on the nanofibrous membranes was achieved up to 22.0 mg/g, which was over 10 times that on the sheet membrane. The activity retention of immobilized lipase increased from 56.4% to 76.8% with an increase in phospholipid moiety from 0 to 9.6%（molar fraction） in the nanofibrous membrane. Kinetic parameter Km was also determined for free and immobilized lipase. The Km value of the immobilized lipase on the nanofibrous membrane was obviously lower than that on the sheet membrane. The optimum pH was 7.7 for free lipase, but shifted to 8.3-8.5 for immobilized lipases. The optimum temperature was determined to be 35 ℃ for the free enzyme, but 42-44℃ for the immobilized ones, respectively. In addition, the thermal stability, reusability, and storage stability of the immobilized lipase were obviously improved compared to the free one.     

Superparamagnetic Polymer Emulsion Particles from a Soap-Free Seeded Emulsion Polymerization and their Application for Lipase Immobilization

Using emulsion copolymer of styrene (St), glycidyl methacrylate (GMA) and 2-hydroxyethyl methacrylate (HEMA) as seed latexes, the superparamagnetic polymer emulsion particles were prepared by seeded emulsion copolymerization of butyl methacrylate (BMA), vinyl acetate (VAc) and ethylene glycol dimethacrylate in the presence of the seed latexes and superparamagnetic Fe₃O₄/SiOx nanoparticles (or Fe₃O₄-APTS nanoparticles) through a two-step process, without addition of any emulsifier. The magnetic emulsion particles named P(St-GMA-HEMA)/P(BMA-VAc) were characterized by transmission electron microscope and vibrating sample magnetometry. The results showed that the magnetic emulsion particles held a structure with a thinner shell (around 100 nm) and a bigger cavity (around 200 nm), and possessed a certain level of magnetic response. The resulting magnetic emulsion particles were employed in the immobilization of lipase by two strategies to immobilized lipase onto the resulting magnetic composites directly (S-1) or using glutaraldehyde as a coupling agent (S-2), thus, experimental data showed that the thermal stability and reusability of immobilized lipase based on S-2 were higher than that of S-1.     

Collagen-Immobilized Lipases Show Good Activity and Reusability for Butyl Butyrate Synthesis

Candida rugosa lipases were immobilized onto collagen fibers through glutaraldehyde cross-linking method. The immobilization process has been optimized. Under the optimal immobilization conditions, the activity of the collagen-immobilized lipase reached 340 U/g. The activity was recovered of 28.3 % by immobilization. The operational stability of the obtained collagen-immobilized lipase for hydrolysis of olive oil emulsion was determined. The collagen-immobilized lipase showed good tolerance to temperature and pH variations in comparison to free lipase. The collagen-immobilized lipase was also applied as biocatalyst for synthesis of butyl butyrate from butyric acid and 1-butanol in n-hexane. The conversion yield was 94 % at the optimal conditions. Of its initial activity, 64 % was retained after 5 cycles for synthesizing butyl butyrate in n-hexane.     

Enzyme-functionalized polymer brush films on the inner wall of silicon-glass microreactors with tunable biocatalytic activity

The lipase from Candida Rugosa was immobilized to a poly(methacrylic acid) polymer brush layer, grown on the inner wall of silicon-glass microreactors. The hydrolysis of 4-nitrophenyl acetate was used as a model reaction to study the activity of this biocatalytic system. The amount of bound lipase could be tuned by changing the polymerization time of the brush formation. The Michaelis-Menten constants and V(max) values, determined for immobilized and free lipase, are similar, demonstrating that the lipase's substrate affinity and its activity remain unchanged upon immobilization to the microchannel wall.     

脂肪酶的固定化及其在有机酶促反应中稳定性研究

利用吸附法,将圆柱状假丝酵母脂肪酶固定于４种疏水性不同的载体上,固定化酶的活性及稳定性随载休疏水性的增大而增大。用ＹＧＷ－Ｃ６Ｈ５作为载体,在有机溶剂－水双液相体系中催化萘普生甲酯的不对称水解,反应１２０ｈ转化率为２４．７２％,产品的对映体过量值为９４．８２％。     

Immobilization of Candida cylindracea Lipase by Covalent Attachment on Glu-Modified Bentonite

Alkaline Ca-bentonite, obtained upon acid activation and base load of natural bentonite, has a good anion exchange capability. Glu-modified alkaline Ca-bentonites were further prepared by covalent binding with glutamic acid for the immobilization of lipase OF from Candida cylindracea. The obtained immobilized lipase demonstrated a significantly higher catalytic activity than that of unmodified alkaline Ca-bentonite, giving a specific activity of 62.1 U mg⁻¹ protein, twice that of the unmodified carrier, and a total activity of 391.2 U g⁻¹ support, retaining ~ 82.3% of the activity after being reused five times for olive oil emulsion hydrolysis. X-ray diffraction and Fourier transform infrared spectroscopy assays demonstrated the successful immobilization of the lipase on the surface of the bentonite. Upon immobilization, the thermostability of the lipase improved remarkably. At 50 °C, free lipase retained only 6.0% of its initial activity at 6 h, in comparison with 15% for Ca-Bent-lipase and 50% for Glu-Ca-Bent-lipase after 8 h. The Glu-Ca-Bent-lipase is proved as an effective biocatalyst for the biodiesel preparation, improving the transesterification reaction conversion from 52.8% in the condition of free lipase to 99.9% and keeping at 56.2% after being reused five times, while the free lipase was inactive upon two reuses. The above results provide a new route in the use of inexpensive bentonite for the enzyme immobilization.

     

云芝漆酶在N,N'-亚甲基双丙烯酰胺（BIS）交联聚甲基丙烯酸基元上的固定及其修饰玻碳电极电化学行为

以N,N′-亚甲基双丙烯酰胺（BIS）交联聚甲基丙烯酸作为固定漆酶的载体,以共价偶联法固定云芝漆酶并测定了固定基元的酶固定量和固定漆酶的比活力。 还研究了固定漆酶热稳定性、重复使用性以及固定漆酶催化2,6-二甲氧基苯酚（DMP）氧化的酶动力学参数。 实验结果表明,这种交联聚合物基元通过共价偶联法固定漆酶的量和固定漆酶的比活力分别可达26.37 mg/g和1.202 U/mg;在交联聚合物基元上固定的漆酶在50 ℃下放置2 h后仍然保持初始活力的83％,重复使用10次后仍保持初始活力的80％以上;交联聚合物固定漆酶催化DMP氧化的表观速率常数k_cat可达1090 min^-1,以固定漆酶的BIS交联聚甲基丙烯酸功能化碳纳米管修饰的玻碳电极在pH=4.4磷酸盐缓冲液中氧还原发生在+724 mV(vs.SCE)。     

环氧基修饰周期性介孔有机氧化硅对漆酶的固定化作用

以三嵌段共聚物P123为模板剂, 在酸性条件下通过1,2-三乙氧基硅基乙烷(BTESE)和3-含氧缩水甘油基-丙基-三甲氧基硅烷(GPTMS)共水解缩聚合成环氧基修饰的周期性介孔氧化硅(PMOs), 以修饰后的PMOs为载体对漆酶进行固定化, 研究了环氧基修饰对固定化酶稳定性的影响. 通过XRD、TEM、固态NMR和N₂吸附等手段表征材料的修饰效果、孔结构以及漆酶的固定化. 结果表明, 修饰后的材料保持良好的孔结构, 环氧基的修饰有利于提高固定化酶的活力, 基于环氧基修饰PMOs的固定化酶具有较高稳定性.