The treatment of chlorophenols with laccase immobilized on sol–gel-derived silica

Laccase, a so-called “blue-copper” oxidase, is able to oxidize a variety of organic compounds. Sol–gel derived silica glasses are frequently adopted as an immobilization method to improve the stability of enzymes and make them reusable. In this study, immobilization conditions were optimized to achieve improved embedding results. The thermal stability, reaction stability and storage stability were improved with the immobilized enzyme when compared to the free enzyme. 2,4-Dichlorophenol (DCP) and 2,4,6-trichlorophenol (TCP) were chosen as model compounds. The treatment of chlorophenols (CPs) by immobilized laccase demonstrated excellent removal and response stability. The affinity of TCP for immobilized laccase was higher than that of DCP. This finding leads to different removal efficiencies under variable conditions (reaction time, initial concentration, dosage of immobilized laccase and removal rate in mixed solution). By fitting the experimental data with the diffusion model of the degradation process, the degradation of CPs by immobilized laccase matches an intraparticle diffusion-controlled model.     

Immobilization of Laccase by Alginate–Chitosan Microcapsules and its Use in Dye Decolorization

Laccase is a ligninolytic enzyme that is widespread in white-rot fungi. Alginate–chitosan microcapsules prepared by an emulsification–internal gelation technique were used to immobilize laccase. Parameters of the immobilization process were optimized. Under the optimal immobilization conditions (2% sodium alginate, 2% CaCl₂, 0.3% chitosan and 1:8 ratio by volume of enzyme to alginate), the loading efficiency and immobilized yield of immobilized laccase were 88.12% and 46.93%, respectively. Laccase stability was increased after immobilization. Both the free and immobilized laccase alone showed a very low decolorization efficiency when Alizarin Red was selected for dye decolorization test. When 0.1 mM 2,2′-azino-bis-(3-ethylbenzothiazoline-6-sulfonic acid) (ABTS) was added into the decolorization system, the decolorization efficiency increased significantly. Immobilized laccase retained 35.73% activity after three reaction cycles. The result demonstrated that immobilized laccase has potential application in dyestuff treatment.     

Immobilized laccase of Cerrena unicolor for elimination of endocrine disruptor micropollutants

The white-rot fungus Cerrena unicolor C-139 produced 450?000 U l⁻¹ of laccase when cultivated in submerged (50 ml) fermentation of wheat bran. Laccase (benzenediol: oxygen oxidoreductase, EC 1.10.3.2.), from C. unicolor C-139 was immobilized covalently on control porosity carrier silica beads. The activity of the immobilized laccase was approximately 15.8 units per gram of silica beads. The pH optimum was between 2.5 and 3.0 for free and immobilized laccase. The immobilization of enzyme appeared to be the main factor for retention of laccase activity at high temperature of 80 °C. The apparent K_m value (100 μmol) of immobilized laccase from C. unicolor C-139 was 6.7 times higher than free laccase (15 μmol) using 2,2-azino-bis-[3-ethylthiazoline-6-sulfonate] (ABTS) as the substrate. Immobilized laccase was able to eliminate 80 % of Bisphenol A, 40 % of Nonylphenol, and 60 % of Triclosan from solutions containing 50 μmol of each micropollutant separately. The experiments were run three times consecutively with the same immobilized laccase without loss of enzyme activity.     

Immobilization of Candida antarctica Lipase B on fumed silica

Enzymes are usually immobilized on solid supports or solubilized when they are to be used in organic solvents with poor enzyme solubility. We have reported previously on a novel immobilization method for subtilisin Carlsberg on fumed silica with results that reached some of the best previously reported catalytic activities in hexane for this enzyme. Here we extend our method to Candida antarctica Lipase B (CALB) as an attractive target due to many potential applications of this enzyme in solvents. Our CALB/fumed silica preparations approached the catalytic activity of commercial Novozym 435 for a model esterification in hexane at 90 wt.% fumed silica (relative to the mass of the preparation). An intriguing observation was that the catalytic activity at first increases as more fumed silica was made available to the enzyme but then decreased precipitously when fumed silica exceeded 90 wt.%. This was not the case for s. Carlsberg where the catalytic activity leveled off at high relative amounts of fumed silica. We determined adsorption kinetics, performed variations of the pre-immobilization aqueous pH, determined the stability, and applied fluorescence microscopy to the preparations. A comparison with recent concepts by Gross et al. may point towards a rationale for an optimum intermediate surface coverage for some enzymes on solid supports.     

Stability and kinetic behavior of immobilized laccase from Myceliophthora thermophila in the presence of the ionic liquid 1‐ethyl‐3‐methylimidazolium ethylsulfate

The use of ionic liquids (ILs) as reaction media for enzymatic reactions has increased their potential because they can improve enzyme activity and stability. Kinetic and stability properties of immobilized commercial laccase from Myceliophthora thermophila in the water‐soluble IL 1‐ethyl‐3‐methylimidazolium ethylsulfate ([emim][EtSO₄]) have been studied and compared with free laccase. Laccase immobilization was carried out by covalent binding on glyoxyl–agarose beads. The immobilization yield was 100%, and the activity was totally recovered. The Michaelis‐Menten model fitted well to the kinetic data of enzymatic oxidation of a model substrate in the presence of the IL [emim][EtSO₄]. When concentration of the IL was augmented, the values of V_max for free and immobilized laccases showed an increase and slight decrease, respectively. The laccase–glyoxyl–agarose derivative improved the laccase stability in comparison with the free laccase regarding the enzymatic inactivation in [emim][EtSO₄]. The stability of both free and immobilized laccase was slightly affected by small amounts of IL (<50%). A high concentration of the IL (75%) produced a large inactivation of free laccase. However, immobilization prevented deactivation beyond 50%. Free and immobilized laccase showed a first‐order thermal inactivation profile between 55 and 70°C in the presence of the IL [emim][EtSO₄]. Finally, thermal stability was scarcely affected by the presence of the IL. © 2014 American Institute of Chemical Engineers Biotechnol. Prog., 30:790–796, 2014     

漆酶在磁性壳聚糖微球上的固定及其酶学性质研究

以磁性壳聚糖微球为载体,戊二醛为交联剂,共价结合制备固定化漆酶。探讨了漆酶固定化的影响因素,并对固定化漆酶的性质进行了研究。确定漆酶固定化适宜条件为：50 mg磁性壳聚糖微球,加入10mL 0.8mg/mL 漆酶磷酸盐缓冲液（0.1mol/L,pH 7.0）,在4℃固定2h。固定化酶最适pH为3.0, 最适温度分别为10℃和55℃,均比游离酶降低5℃。在pH 3.0,温度37℃时,固定化酶对ABTS的表观米氏常数为171.1μmol/L。与游离酶相比,该固定化漆酶热稳定性明显提高,并具有良好的操作和存储稳定性。     

Immobilization of Mucor javanicus lipase on effectively functionalized silica nanoparticles

Mucor javanicus lipase was effectively immobilized on silica nanoparticles which were prepared by Stöber method. Glycidyl methacrylate (GMA), which bears a reactive epoxide group, was incorporated onto the surface of the nanoparticles and the epoxide groups were directly used for multipoint coupling of the enzyme. We also introduced amine residues by coupling ethylene diamine (EDA) to the epoxide group of GMA. M. javanicus lipase was covalently immobilized onto the amine-activated silica nanoparticles by using glutaraldehyde (GA) or 1,4 phenylene diisothiocyanate (NCS) as a coupling agent. The lipase loading capacities of the EDA-GA and EDA-NCS nanoparticles (81.3 and 60.9 mg g⁻¹, respectively) were much higher than that of the unmodified GMA nanoparticles (18.9 mg g⁻¹). The relative hydrolytic activities in an aqueous medium of the lipases immobilized on EDA-GA and EDA-NCS attached silica nanoparticles (115% and 107%, respectively) were significantly high and almost in the same range with the free enzyme. This may be due to the improvement of the enzyme–substrate interaction by avoiding the potential aggregation of free lipase molecules. The immobilized lipases were also more resistant to temperature inactivation than the free form. This work demonstrates that the size-controlled silica nanoparticles can be efficiently employed as host materials for enzyme immobilization leading to high activity and stability of the immobilized enzymes.     

Reactive blue 19 decolouration by laccase immobilized on silica beads

Laccase (31.5 U of activity/g or 4.39 μg of protein/m²) from Trametes versicolor was immobilized on controlled-porosity-carrier silica beads and evaluated for the decolouration of Reactive blue 19, an anthraquinone dye. Although there was an initial, rapid adsorption of the dye to the packed bed in a recirculating reactor, about 97.5% of Reactive blue 19 removal was due to enzymatic degradation. The free enzyme lost 52% of its activity in 48 h. However, the activity of the immobilized laccase was unchanged after 4 months of storage in phosphate buffer under ambient conditions followed by three successive decolourations over 120 h. Treating the laccase immobilized beads with ethanolamine reduced dye adsorption by 40%.     

Recent developments and applications of immobilized laccase

Laccase is a promising biocatalyst with many possible applications, including bioremediation, chemical synthesis, biobleaching of paper pulp, biosensing, textile finishing and wine stabilization. The immobilization of enzymes offers several improvements for enzyme applications because the storage and operational stabilities are frequently enhanced. Moreover, the reusability of immobilized enzymes represents a great advantage compared with free enzymes. In this work, we discuss the different methodologies of enzyme immobilization that have been reported for laccases, such as adsorption, entrapment, encapsulation, covalent binding and self-immobilization. The applications of laccase immobilized by the aforementioned methodologies are presented, paying special attention to recent approaches regarding environmental applications and electrobiochemistry.     

Stability of immobilized laccase on Luffa Cylindrica fibers and assessment of synthetic hormone degradation

In this work were studied the pH, thermal, and storage stability of free and immobilized laccases. Enzymes were produced by Pleurotus ostreatus on potato dextrose (PD) broth and potato dextrose modified (PDM) broth, and immobilized using Luffa cylindrica fibers as support. Both free and immobilized enzymes were assessed on their respective enzymatic activities and for 17α-ethinylestradiol (EE2) degradation. The optimum pH conditions concerning laccase activity ranged from 3.6 to 4.6, while temperature ranged between 30?°C and 50?°C for both free and immobilized enzyme. Laccase produced using PD broth presented greater storage stability and thermal stability than that of PDM. Best EE2 removals were of 79.22% and 75.00% for the free and immobilized enzymes, respectively. Removal rates were assessed during 8?h at pH 5. The removal of 17α-ethinylestradiol was stabilized in the fourth cycle of use. Results imply that immobilization promoted stability towards pH and temperature variations, although media played a decisive role in the enzymatic activity. Both free and immobilized laccases of P. ostreatus were able to degrade EE2, whereas immobilized laccase in PDM medium presented possible reuse applicability, albeit removal was not optimal when compared to other reports.     

Ceramic honeycomb as support for covalent immobilization of laccase from Trametes versicolor and transformation of nuclear fast red

The covalent immobilization of laccase on an inorganic ceramic support was investigated. The intention was to find a system of enzyme and reactor for a universal immobilization procedure. Laccase from Trametes versicolor as model enzyme was chosen. The special honeycomb structure of the monolith can be applied for intensive mixing of the reaction compounds. An appropriate reactor with ceramic material was constructed allowing different setup for enzyme immobilization and its application. To test the success of the immobilization, 2,2-azino-bis (3-ethylbenzothiazoline-6-sulfonic acid) was used. The immobilized laccase was found to be stable over a time period of over 3 months. As an example for possible application for treatment of wastewater containing dyes, the conversion of nuclear fast red as model substrate was tested.     

Improved activity and stability of an immobilized recombinant laccase in organic solvents

Laccase (E.C. 1.10.3.2) from Trametes versicolor was immobilized (adsorbed) by drying on various supports (glass, glass powder, silica gel, and Nylon 66 membrane). The enzyme activity and stability were determined in diethyl ether, ethyl acetate, and methylene chloride. The initial rate for the oxidation of syringaldazine varied up to 245-fold depending on the solvent and support, the best results being obtained with Nylon 66 membrane. No inactivation of immobilized laccase over 72 h was observed in diethyl ether and ethyl acetate, while exposure to methylene chloride resulted in significant activity decreases regardless of the support material.     

Magnetically recyclable, antimicrobial, and catalytically enhanced polymer-assisted “green” nanosystem-immobilized Aspergillus niger amyloglucosidase

The present work reports the integration of polymer matrix-supported nanomaterial and enzyme biotechnology for development of industrially feasible biocatalysts. Aqueous leaf extract of Mesua ferrea L. was used to prepare silver nanoparticles distributed within a narrow size range (1–12 nm). In situ oxidative technique was used to obtain poly(ethylene glycol)-supported iron oxide nanoparticles (3–5 nm). Sonication-mediated mixing of above nanoparticles generated the immobilization system comprising of polymer-supported silver–iron oxide nanoparticles (20–30 nm). A commercially important enzyme, Aspergillus niger amyloglucosidase was coupled onto the immobilization system through sonication. The immobilization enzyme registered a multi-fold increment in the specific activity (807 U/mg) over the free counterpart (69 U/mg). Considerable initial activity of the immobilized enzyme was retained even after storing the system at room temperature as well as post-repeated magnetic recycling. Evaluation of the commendable starch saccharification rate, washing performance synergy with a panel of commercial detergents, and antibacterial potency strongly forwards the immobilized enzyme as a multi-functional industrially feasible system.     

Advanced enzymatic elimination of phenolic contaminants in wastewater: a nano approach at field scale

The removal of recalcitrant chemicals in wastewater treatment systems is an increasingly relevant issue in industrialized countries. The elimination of persistent xenobiotics such as endocrine-disrupting chemicals (EDCs) emitted by municipal and industrial sewage treatment plants remains an unsolved challenge. The existing efficacious physico-chemical methods, such as advanced oxidation processes, are resource-intensive technologies. In this work, we investigated the possibility to remove phenolic EDCs [i.e., bisphenol A (BPA)] by means of a less energy and chemical consuming technology. To that end, cheap and resistant oxidative enzymes, i.e., laccases, were immobilized onto silica nanoparticles. The resulting nanobiocatalyst produced at kilogram scale was demonstrated to possess a broad substrate spectrum regarding the degradation of recalcitrant pollutants. This nanobiocatalyst was applied in a membrane reactor at technical scale for tertiary wastewater treatment. The system efficiently removed BPA and the results of long-term field tests illustrated the potential of fumed silica nanoparticles/laccase composites for advanced biological wastewater treatment.     

Immobilization of laccase from Streptomyces psammoticus and its application in phenol removal using packed bed reactor

Laccase was produced from Streptomyces psammoticus under solid-state fermentation. The enzyme was partially purified by ammonium sulphate precipitation and was immobilized in alginate beads by entrapment method. Calcium alginate beads retained 42.5% laccase activity, while copper alginate beads proved a better support for laccase immobilization by retaining 61% of the activity. Phenol and colour removal from a phenol model solution was carried out using immobilized laccase. Batch experiments were performed using packed bed bioreactor, containing immobilized beads. Reusability of the immobilized matrix was studied for up to 8 successive runs, each run with duration of 6 h. The system removed 72% of the colour and 69.9% of total phenolics from the phenol model solution after the initial run. The immobilized system maintained 50% of its efficiency after eight successive runs. The degradation of phenolic compounds by immobilized laccase was evaluated and confirmed by Thin layer chromatography and nuclear magnetic resonance spectroscopy.     

Study on Remediation-improvement of 2,4-Dichlorophenol Contaminated Soil by Organic Fertilizer Immobilized Laccase

ABSTRACT

In this paper, laccase is immobilized by the cross-linking method, using organic fertilizer as a carrier and glutaraldehyde as a cross-linking agent. Here, the optimal conditions of laccase immobilization were explored and the optimal operating conditions and stabilities of free laccase and immobilized laccase were also studied. Then, free laccase and immobilized laccase were applied to the soil remediation. Meanwhile, the effect of soil improvement treated with immobilized laccase was studied through ecological evaluation. The results showed that the optimal conditions for laccase immobilization were: the volume fraction of glutaraldehyde was 5%, the amount of enzyme added was 15 mL, and the immobilization time was 6 h. Under the same conditions, thermal stability and acid-base stability of immobilized laccase were better than free laccase. Under the optimal conditions, using laccase to treat 2,4-dichlorophenol in the soil, it was found that the free laccase group degraded 44.4% within 5 days, while the immobilized laccase group degraded 58.6%. Although both the degradation trends and route are the same, the degradation effect of the latter is obviously better. Ecological evaluation showed that organic fertilizer carrier had an impact on soil physical and chemical properties and soil enzymes, playing a positive role in soil ecological security and improving the soil.     

Toward cell‐free biofuel production: Stable immobilization of oligomeric enzymes

To overcome the main challenges facing alcohol‐based biofuel production, we propose an alternate simplified biofuel production scheme based on a cell‐free immobilized enzyme system. In this paper, we measured the activity of two tetrameric enzymes, a control enzyme with a colorimetric assay, β‐galactosidase, and an alcohol‐producing enzyme, alcohol dehydrogenase, immobilized on multiple surface curvatures and chemistries. Several solid supports including silica nanoparticles (convex), mesopourous silica (concave), diatomaceous earth (concave), and methacrylate (concave) were examined. High conversion rates and low protein leaching was achieved by covalent immobilization of both enzymes on methacrylate resin. Alcohol dehydrogenase (ADH) exhibited long‐term stability and over 80% conversion of aldehyde to alcohol over 16 days of batch cycles. The complete reaction scheme for the conversion of acid to aldehyde to alcohol was demonstrated in vitro by immobilizing ADH with keto‐acid decarboxylase free in solution. © 2014 American Institute of Chemical Engineers Biotechnol. Prog., 30:324–331, 2014     

Enhanced immobilization of hexa-arginine-tagged esterase on gold nanoparticles using mixed self-assembled monolayers

Mixed self-assembled monolayers (MSAMs) composed of diverse ligands offer a mechanism for the specific binding of biomolecules onto solid surfaces. In this study, we examined the formation of MSAMs on gold nanoparticles (AuNPs) and the immobilization of hexa-arginine-tagged esterase (Arg₆-esterase) on the surfaces of the resulting particles. The functionalization of AuNPs with MSAMs was achieved by introducing a mixture of tethering and shielding ligands into an AuNP solution. The formation of self-assembled monolayers (SAMs) on the AuNP surface was characterized by UV/visible spectroscopy, transmission electron microscopy, and Fourier-transform infrared spectroscopy. Arg₆-esterase was immobilized in a highly specific manner onto AuNPs treated with mixed SAMs (MSAM–AuNPs) by providing a shielding ligand which reduce the non-specific adsorption of enzymes caused by hydrophobic interaction compared to AuNPs treated with single-component SAMs (SSAM–AuNPs). Moreover, Arg₆-esterase immobilized on MSAM–AuNPs showed substantially enhanced catalytic activity up to an original activity compared to that on SSAM–AuNPs (58%).     

Immobilized trypsin on hydrophobic cellulose decorated nanoparticles shows good stability and reusability for protein digestion

The preparation of biocatalysts based on immobilized trypsin is of great importance for both proteomic research and industrial applications. Here, we have developed a facile method to immobilize trypsin on hydrophobic cellulose-coated silica nanoparticles by surface adsorption. The immobilization conditions for the trypsin enzyme were optimized. The as-prepared biocatalyst was characterized by Fourier transform infrared spectroscopy, transmission electron microscopy, and elemental analysis. In comparison with free enzyme, the immobilized trypsin exhibited greater resistances against thermal inactivation and denaturants. In addition, the immobilized trypsin showed good durability for multiple recycling. The general applicability of the immobilized trypsin for proteomic studies was confirmed by enzymatic digestion of two widely used protein substrates: bovine serum albumin (BSA) and cytochrome c. The surface adsorption protocols for trypsin immobilization may provide a promising strategy for enzyme immobilization in general, with great potential for a range of applications in proteomic studies.     

Potential applications of enzymes immobilized on/in nano materials: A review

Several new types of carriers and technologies have been implemented in the recent past to improve traditional enzyme immobilization which aimed to enhance enzyme loading, activity and stability to decrease the enzyme biocatalyst cost in industrial biotechnology. These include cross-linked enzyme aggregates, microwave-assisted immobilization, click chemistry technology, mesoporous supports and most recently nanoparticle-based immobilization of enzymes. The union of the specific physical, chemical, optical and electrical properties of nanoparticles with the specific recognition or catalytic properties of biomolecules has led to their appearance in myriad novel biotechnological applications. They have been applied time and again for immobilization of industrially important enzymes with improved characteristics. The high surface-to-volume ratio offered by nanoparticles resulted in the concentration of the immobilized entity being considerably higher than that afforded by experimental protocols based on immobilization on planar 2-D surfaces. Enzymes immobilized on nanoparticles showed a broader working pH and temperature range and higher thermal stability than the native enzymes. Compared with the conventional immobilization methods, nanoparticle based immobilization served three important features; (i) nano-enzyme particles are easy to synthesize in high solid content without using surfactants and toxic reagents, (ii) homogeneous and well defined core-shell nanoparticles with a thick enzyme shell can be obtained, and (iii) particle size can be conveniently tailored within utility limits. In addition, with the growing attention paid to cascade enzymatic reaction and in vitro synthetic biology, it is possible that co-immobilization of multi-enzymes could be achieved on these nanoparticles.