Effect of surfactants on phenol removal by the method of polymerization and precipitation catalysed by Coprinus cinereus peroxidase

The removal of phenol by peroxidase‐catalysed polymerization was examined using Coprinus cinereus peroxidase in the presence of surfactants. The non‐ionic surfactants with poly(oxyethene) residues, Triton X‐100, Triton X‐405 and Tween 20, enhanced the phenol removal efficiency at a level similar to high relative molecular mass poly(ethylene glycol) (relative molecular mass 3000). Although the improvement in the removal efficiency was less than that of Triton X‐100, Span 20, sodium lauryl sulfate (SDS) and lauryl trimethylammonium bromide (DTAB) also enhanced the removal efficiency. The requirement of the enzyme for almost 100% removal of 100 mg dm^?3 phenol decreased to one‐fourth by the addition of 30 mg dm^?3 Triton X‐100. Triton X‐100, Triton X‐405, Tween 20 and DTAB could reactivate the enzyme precipitated with the phenol polymer, leading to the restarting of the phenol removal reaction. Copyright © 2003 Society of Chemical Industry     

Entrapment of porous and stable concanavalin A–peroxidase complex into hybrid calcium alginate–pectin gel

Ammonium sulfate‐fractionated proteins of turnip (Brassica rapa) were used for the simultaneous purification and immobilization of peroxidase by using crude jack bean extract. The concanavalin A–turnip peroxidase complex retained nearly 70% of the original activity. Calcium alginate–pectin‐entrapped soluble turnip peroxidase and the concanavalin A complex of peroxidase retained 63% and 52% of the original activity, respectively. The concanavalin A–peroxidase complex, the alginate–pectin‐entrapped soluble peroxidase and the alginate–pectin‐entrapped concanavalin A–peroxidase complex showed very high stability against denaturation mediated by heat, pH, urea, organic solvents and detergents. The exposure of soluble and immobilized turnip peroxidase to trypsin resulted in an enhancement of the peroxidase activity. The concanavalin A–peroxidase complex entrapped preparation was markedly more stable as compared with the directly entrapped soluble enzyme preparation. The results suggested that such preparations have great potential in the construction of bioreactors to be used for the remediation of aromatic compounds present in polluted wastewater/industrial effluents. Copyright © 2006 Society of Chemical Industry     

壳聚糖载体柔性固定化木瓜蛋白酶

用酶柔性固定化模型,以壳聚糖为载体,双醛淀粉为柔性链,对木瓜蛋白酶进行柔性固定化. 通过对固定化条件的优化,得出选用壳聚糖、双醛淀粉制得的柔性载体(Chitosan-DAS50)在酶用量为14.4 mg/g(酶/干球)、pH 8的条件下,固定木瓜蛋白酶18 h,所得的固定化酶活力回收率达72%,相当于采用壳聚糖-戊二醛(Chitosan-GA)手臂载体的3倍. 结果表明,酶的柔性固定化模型可以改善传统共价结合法固定化及手臂固定化酶活力回收率不高的缺陷.     

Retention and reusability of trypsin activity by covalent immobilization onto grafted polyethylene plates

This study investigated the activity of trypsin that had been covalently immobilized onto acrylic acid (AA)– and methacrylic acid (MAA)–grafted polyethylene (PE) plates—PE–g–PAA and PE–g–PMAA—using a water‐soluble carbodiimide as a coupling agent, as a function of the immobilized amount, the grafted amount, the pH value on immobilization, and the pH value and temperature at the activity measurement. The activity of trypsin immobilized on the PE–g–PAA plates at pH 6.0 decreased with an increase in the immobilized amount because of the crowding of trypsin molecules in the vicinity of the surfaces of the grafted PAA layers. The increase in the grafted amount resulted in a decrease in the activity of immobilized trypsin because of a decrease in the diffusivity of BANA molecules caused by the formation of dense grafted PAA layers for the PE–g–PAA plates and led to the increased activity because of the increase in the hydrophilicity of the whole grafted layers for the PE–g–PMAA plates. The activity of trypsin immobilized on the PE–g–PAA and PE–g–PMAA plates at pH 6 increased with an increase in the pH value, probably because of the expansion of trypsin‐carrying grafted PAA and PMAA chains and the increased diffusivity of Nα‐benzoyl‐DL ‐arginine‐nitroanilide hydrochloride molecules in the grafted layers. The optimum temperature of the activity of immobilized trypsin shifted to 50°C from 30°C for native trypsin. Immobilized trypsin was reusable without any denaturation and isolation at temperatures ranging from 20°C to 60°C and pH values ranging from 6 to 10. Trypsin immobilized on a PE–g–PAA plate had 95% of the remaining activity in relation to native trypsin at 30°C after preservation in a pH 7.8 buffer at 4°C over 6 months. These results made clear that alkaline and thermal stability, reusability, and storage stability can be much improved by the covalent coupling of trypsin on PE–g–PAA and PE–g–PMAA plates. © 2003 Wiley Periodicals, Inc. J Appl Polym Sci 89: 3574–3581, 2003     

Adsorption of lipase from Candida rugosa on multi walled carbon nanotubes

In this work lipase from Candida rugosa was adsorbed on unmodified surface of multi walled carbon nanotubes (raw-MWCNT). The effects of immobilization time, initial enzyme concentration and buffer ionic strength on enzyme loading and activity of immobilized preparations were tested. High loadings are attained. The immobilized enzyme obtained at lowest initial enzyme concentration and high ionic strength retained 85% of initial enzyme activity. It is assumed that immobilization on hydrophobic surface led to conformational changes that resulted in the adsorption of lipase in active conformation. Immobilized preparations were characterized, with FT-IR spectroscopy, AFM, and cyclic voltammetry.     

纤维素酶固定化载体的研究进展

重点介绍了可溶性载体、不溶性载体以及可溶-不可溶性载体固定化纤维素酶的研究进展,3种载体都能不同程度地提高纤维素酶的稳定性与重复使用性。可溶性载体能提高纤维素酶的操作稳定性,有利于水解不溶性的纤维素,但回收不方便。不溶性载体固定化纤维素酶,回收方便,操作稳定性提高,但即使是提高了比表面积和减少了酶与底物的传质阻力的不溶性磁性纳米材料与膜材料固定化纤维素酶,也大多停留在水解可溶的羧甲基纤维素(CMC)阶段,不能高效率地水解不溶的纤维素底物。可溶-不可溶性载体固定纤维素酶,既能方便回收,又能水解不溶性的纤维素底物,但存在难固定,沉淀-溶解过程酶活损失大的缺点,期待开发新的固定方法与新的可溶-不可溶性载体。     

Acid activated montmorillonite: an efficient immobilization support for improving reusability,storage stability and operational stability of enzymes

Three enzymes, α-amylase, glucoamylase and invertase, were immobilized on acid activated montmorillonite K 10 via two independent techniques, adsorption and covalent binding. The immobilized enzymes were characterized by XRD, N₂ adsorption measurements and ²⁷Al MAS-NMR spectroscopy. The XRD patterns showed that all enzymes were intercalated into the clay inter-layer space. The entire protein backbone was situated at the periphery of the clay matrix. Intercalation occurred through the side chains of the amino acid residues. A decrease in surface area and pore volume upon immobilization supported this observation. The extent of intercalation was greater for the covalently bound systems. NMR data showed that tetrahedral Al species were involved during enzyme adsorption whereas octahedral Al was involved during covalent binding. The immobilized enzymes demonstrated enhanced storage stability. While the free enzymes lost all activity within a period of 10 days, the immobilized forms retained appreciable activity even after 30 days of storage. Reusability also improved upon immobilization. Here again, covalently bound enzymes exhibited better characteristics than their adsorbed counterparts. The immobilized enzymes could be successfully used continuously in the packed bed reactor for about 96 hours without much loss in activity. Immobilized glucoamylase demonstrated the best results.     

An Synthesepulp immobilisierte Enzyme,I.

Synthetic pulp—a polyethylene fibrid which contains poly(vinyl alcohol)—was reacted with 2-(3-aminophenyl)-1,3-dioxolane. The amino derivative was transferred into the reactive diazonium compound. The content of reactive diazonium groups was determined by reaction with tyrosine. The diazonium derivatives of synthetic pulp were used for the immobilization of the hydrolases trypsin, chymotrypsin, papain, aminoacrylase, esterase and urease of the oxidoreductases glucose oxidase, catalase, peroxidase, and glucose-6-phosphate-dehydrogenase, and of the transferase hexokinase. Furthermore soybean trypsin inhibitor was immobilized on synthetic pulp via azo coupling. The protein binding ability of the reactive carriers and the enzymatic properties of the immobilization products were investigated. The thermostability of immobilized trypsin and immobilized urease, as well as the dependence of the immobilized tryptic activity on the temperature were studied. The activities of immobilized trypsin were assayed with low molecular weight substrates as well as with high molecular weight substates. The pH-optima of immobilized chymotrypsin, papain and urease were studied and the influence of buffers on the pH-activity profiles was investigated. Hexokinase and glucose-6-phosphatedehydrogenase were co-immobilized on synthetic pulp as an example for a two enzyme system and the properties of the immobilization products were investigate.     

Glucoamylase immobilized on montmorillonite: influence of nature of binding on surface properties of clay-support and activity of enzyme

Glucoamylase was immobilized on acid activated montmorillonite clay via two different procedures namely adsorption and covalent binding. The immobilized enzymes were characterized by XRD, NMR and N₂ adsorption measurements and the activity of immobilized glucoamylase for starch hydrolysis was determined in a batch reactor. XRD shows intercalation of enzyme into the clay matrix during both immobilization procedures. Intercalation occurs via the side chains of the amino acid residues, the entire polypeptide backbone being situated at the periphery of the clay matrix. ²⁷Al NMR studies revealed the different nature of interaction of enzyme with the support for both immobilization techniques. N₂ adsorption measurements indicated a sharp drop in surface area and pore volume for the covalently bound glucoamylase that suggested severe pore blockage. Activity studies were performed in a batch reactor. The adsorbed and covalently bound glucoamylase retained 49% and 66% activity of the free enzyme respectively. They showed enhanced pH and thermal stabilities. The immobilized enzymes also followed Michaelis–Menten kinetics. K _m was greater than the free enzyme that was attributed to an effect of immobilization. The immobilized preparations demonstrated increased reusability as well as storage stability.     

Bisacryloylpiperazine as vinylating agent for enzyme immobilization by graft-copolymerization onto polysaccharides

A method of enzyme immobilization by graft-copolymerization onto polysaccharides is reported. Bisacryloylpiperazine has been used as a vinylating reagent and the reaction product with several enzymes (HRP, GOD, Am, ChT, Cel) was copolymerized onto different matrices (cellulose, Sepharose, Sephadex, starch). Immobilization parameters which influence the copolymer activity have been studied for the insolubilization of horseradish peroxidase onto cellulose. These parameters are pH, time, and temperature of bisacryloylpiperazine enzyme activation reaction. Under the best immobilization conditions copolymer activity linearly depends on enzyme concentration. Enzyme coupling efficiency depends on the type of enzyme and it ranges from 7 to 20%. The most important characteristics of these immobilized enzyme systems were tested and compared with those of similar systems obtained by glycidylmethacrylate enzyme activation (stability in continuous washing, kinetic characteristics, and storage, thermal, and operational stability). Immobilized enzyme graft copolymers have kinetic behaviour very close to that of the free enzymes. Diffusion is not seriously limited because immobilization reaction does not alter the enzymatic activity. By means of bisacryloylpiperazine it was possible to immobilize chymotrypsin with better results than those previously obtained, particularly coupling efficiency and long term continuous working.     

Synthesis and characterization of PMMA composites activated with starch for immobilization of L‐asparaginase

Poly (methyl methacrylate) (PMMA)–starch composites were prepared by emulsion polymerization technique for L‐asparaginase (L‐ASNase) immobilization as highly activated support. The hydroxide groups on the prepared composites offer a very simple, mild and firm combination for enzyme immobilization. The pure PMMA and PMMA‐starch composites were characterized as structural, thermal and morphological. PMMA‐starch composites were found to have better thermal stability and more hydrophilic character than pure PMMA. L‐ASNase was immobilized onto PMMA‐starch composites contained the different ratio of starch (1, 3, 5, and 10 wt %). Immobilized L‐ASNase showed better performance as compared to the native enzyme in terms of thermal stability and pH. K_m value of immobilized enzyme decreased approximately eightfold compared with the native enzyme. In addition to, immobilized L‐ASNase was found to retain 60% of activity after 1‐month storage period at 4 °C. Therefore, PMMA‐starch composites can be provided more advantageous in terms of enzymatic affinity, thermal, pH and storage stability as L‐ASNase immobilization matrix. © 2016 Wiley Periodicals, Inc. J. Appl. Polym. Sci. 2016 , 133, 43421.     

Tyramine modified alginates via periodate oxidation for peroxidase induced hydrogel formation and immobilization

Phenol and amino groups were introduced into alginate to different degrees via oxidation with 2.5, 5, 10, 15 and 20 mol% of periodate and reductive amination by tyramine. Modification of alginate with tyramine was confirmed by FTIR spectroscopy and UV–VIS spectroscopy, while concentration of phenol and ionizable groups was determined using absorbance at 275 nm and acid–base titration. All tyramine-alginates were able to form hydrogels after cross-linking with horse radish peroxidase (HRP) and hydrogen peroxide. Tyramine-alginates oxidized with up to 10 mol% of periodate were also capable of forming hydrogels with calcium ions. Tyramine-alginates were tested for HRP immobilization within micro-beads obtained by peroxidase catalyzed droplet polymerization using internal delivery of hydrogen peroxide via glucose oxidase and glucose. Highest activity of immobilized peroxidase was obtained with 20% (w/v) tyramine-alginate obtained via 20 mol% periodate oxidation. Immobilized enzyme was not leaking from the micro-beads and was further kinetically characterized for pyrogallol oxidation. K_m for pyrogallol was increased after immobilization from 1.93 mM for soluble HRP to 7.34 mM for immobilized HRP. The optimum pH was also increased from pH 7.0 to 8.0. Temperature and organic solvent stability improved significantly after immobilization, so that half-life at 70 °C increased around four times, while half-life in 80% (v/v) dioxane increased 22 times. After repeated use of 6 times in batch reactor for pyrogallol oxidation immobilized HRP retained 45% of original activity.     

Stability of horseradish peroxidase immobilized on different cinnamic carbohydrate esters

Four types of organic polymer were used to cover 3 mm diameter glass beads for subsequent use in immobilizing horseradish peroxidase (HRP). These supports were the totally cinnamoylated derivatives of D ‐glucosone (GSOCN), D ‐sorbitol (SOTCN), ethyl‐D ‐glucopyranoside (EGSCN) or inuline (INCN). In some assays, a partially cinnamoylated derivative, 2,3,4,6‐tetracinnamoyl‐D ‐glucopyranoside (GPSTCN) (obtained from the EGSCN derivative by hydrolysis in acidic medium) was used. Polymerization and cross‐linking of the derivatives obtained initially was carried out by irradiation in the ultraviolet region, where these polymers show the greatest degree of sensitivity. The enzyme was immobilized by adsorption to the support. Immobilized enzymatic activity varied with the incubation time used (2–21 h), depending on the chemical nature of the immobilization support. The affinity of HRP for H₂O₂ and 2,2′‐azinobis(3‐ethylbenzothiazolinesulfonic acid) (ABTS) was slightly lower in the case of the enzyme immobilized on the GSOCN, SOTCN and EGSCN derivatives than in the case of the soluble enzyme, as can be seen from the corresponding apparent kinetic constants ( and ). However, the affinity of HRP immobilized on the INCN derivative for these substrates was higher than that shown by the enzyme in solution. In turn, the enzyme immobilized on all the supports was more resistant than the soluble form to inactivation by H₂O₂ and by heat at neutral pH. When the stability and durability of the immobilized HRP were analysed, the cinnamoylated derivatives prepared were seen to function as suitable supports for immobilizing peroxidase and to be suitable for industrial application of the enzyme. Copyright © 2004 Society of Chemical Industry     

Removal of aqueous phenol and 2‐chlorophenol with purified soybean peroxidase and raw soybean hulls

In this study, the removal of phenol and 2‐chlorophenol using soybean seed‐hulls in the presence of hydrogen peroxide is demonstrated. The performance of a stirred membrane reactor containing soluble purified SBP was compared with a batch stirred reactor containing raw soybean seed‐hulls. The purified enzyme reactor proved to be ineffective while excellent results were obtained with the crude seed‐hulls for the removal of phenol and 2‐chlorophenol. Four sequential batch reactors containing raw seed‐hulls achieved greater than 96% removal of phenol with a retention time of 20 min in each reactor. A single batch reactor containing raw seed‐hulls was effective in removing greater than 98.5% of 2‐chlorophenol (initially at 1000 ppm) in less than 15 min. The performance of these reactors is comparable to existing HRP‐based technology. The stability of the soybean peroxidase (SBP) enzyme was also examined in the presence of detergents (SDS, Tween 20 and Triton X‐100). Low concentrations of the detergents significantly increased the enzyme activity and higher concentrations of detergents (up to 20% w/v) did not inactivate the SBP enzyme. These results demonstrate that SBP has good potential for the treatment of phenol contaminated solutions. © 1999 Society of Chemical Industry     

Immobilization of peroxidase enzyme onto the porous silicon structure for enhancing its activity and stability

In this work, a commercial peroxidase was immobilized onto porous silicon (PS) support functionalized with 3-aminopropyldiethoxysilane (APDES) and the performance of the obtained catalytic microreactor was studied. The immobilization steps were monitored and the activity of the immobilized enzyme in the PS pores was spectrophotometrically determined. The enzyme immobilization in porous silicon has demonstrated its potential as highly efficient enzymatic reactor. The effect of a polar organic solvent (acetonitrile) and the temperature (up to 50°C) on the activity and stability of the biocatalytic microreactor were studied. After 2-h incubation in organic solvent, the microreactor retained 80% of its initial activity in contrast to the system with free soluble peroxidase that lost 95% of its activity in the same period of time. Peroxidase immobilized into the spaces of the porous silicon support would be perspective for applications in treatments for environmental security such as removal of leached dye in textile industry or in treatment of different industrial effluents. The system can be also applied in the field of biomedicine.     

表面活性剂对木薯秆酶水解的影响

采用纤维素酶促水解的方法,以木薯秆为底物,研究了5种表面活性剂(SDS、Tween 20、Tween 80、Triton x-100、Triton x-114)及其用量对木薯秆酶水解得率的影响。结果表明,除SDS外,其他4种表面活性剂对木薯秆酶水解有不同程度的促进作用,Tween 20的效果最为显著。添加2.5 g/L的Tween 20水解72 h和5.0 g/L的Triton x-114水解60 h,酶水解得率分别达到了49.23%、49.48%,比空白样提高了33.45%和34.13%。     

Immobilization of horseradish peroxidase on chitosan for use in nonaqueous media

Chitosan, a natural polysaccharide, was used for the covalent immobilization of horseradish peroxidase, an enzyme of high synthetic utility, with the carbodiimide method. Of the enzyme, 62% was immobilized on chitosan when 1‐ethyl‐3‐(3‐dimethylaminopropyl carbodiimide) was used as the peptide coupling agent. The influence of different parameters, such as the enzyme concentration, carbodiimide concentration, and incubation period, on the activity retention of the immobilized enzyme was investigated. Kinetic studies using horseradish peroxidase immobilized on chitosan revealed the effects of several parameters, such as the substrate hydrophilicity and hydrophobicity, the solubility of substrates in the medium, the solvent hydrophobicity, and the support aquaphilicity, on the catalytic activity of the immobilized enzyme in nonaqueous media. General rules for the optimization of solvents for nonaqueous enzymology based on the partitioning of the solvent were not applicable for the immobilized horseradish peroxidase. The catalytic efficiency was greatest when o‐phenylene diamine was used as the substrate and least when guaiacol was used. The aquaphilicity of the support played an important role in the kinetics of the immobilized horseradish peroxidase in water‐miscible solvents. The results were promising for the future development of chitosan‐immobilized enzymes for use in organic media. © 2003 Wiley Periodicals, Inc. J Appl Polym Sci 88: 1456–1464, 2003     

Immobilization strategy of accessible transmission for trypsin to catalyze synthesis of dipeptide in mesoporous support

Immobilized trypsin in mesoporous silica foams was used to catalyze dipeptide synthesis in hydrophilic organic solvent instead of soluble form. The area surface of nano support was measured. The catalytic activity, coupled yield and kinetic characterization of immobilized trypsin were examined. Bz-Arg-OEt was chosen as the acyl donor with Lys-OH as the nucleophile. The trypsin-catalyzed synthesis condition was optimized, such as catalytic temperature, pH, reaction time, physical properties and content of organic solvents, together with the added enzyme amount. The immobilized trypsin showed 112.8% of residual activity with 91.9% of coupled yield, and the kinetic parameters exhibited accessibility for transmission. The product yield of 5.8% was reached at the optimum conditions for enzymatic synthesis of dipeptide: 800 mg of wet immobilized trypsin (200 mg/g support) was used in Tris-HCl buffer (0.1 mol/L, pH 8.0) containing 80% (v/v) ethanol solvents for 6 h of reaction time at 35 °C. This attempt of immobilized strategy for trypsin in nanopores renders the possibility of wide application of inorganic nano-sized support in catalytic synthesis process, which can avoid usage of large amounts of organic solvents in washing steps by chemical methods and reduce the tedious purification process of its soluble form.     

Immobilization of Pycnoporus sanguineus laccase by metal affinity adsorption on magnetic chelator particles

BACKGROUND: Immobilized enzymes provide many advantages over free enzymes including repeated or continuous reuse, easy separation of the product from reaction media, easy recovery of the enzyme, and improvement in enzyme stability. In order to improve catalytic activity of laccase and increase its industrial application, there is great interest in developing novel technologies on laccase immobilization. RESULTS: Magnetic Cu²⁺‐chelated particles, prepared by cerium‐initiated graft polymerization of tentacle‐type polymer chains with iminodiacetic acid (IDA) as chelating ligand, were employed for Pycnoporus sanguineus laccase immobilization. The particles showed an obvious high adsorption capacity of laccase (94.1 mg g^?1 support) with an activity recovery of 68.0% after immobilization. The laccase exhibited improved stability in reaction conditions over a broad temperature range between 45 °C and 70 °C and an optimal pH value of 3.0 after being adsorbed on the magnetic metal‐chelated particles. The value of the Michaelis constant (K_m) of the immobilized laccase (1.597 mmol L^?1) was higher than that of the free one (0.761 mmol L^?1), whereas the maximum velocity (V_max) was lower for the adsorbed laccase. Storage stability and temperature endurance of the immobilized laccase were found to increase greatly, and the immobilized laccase retained 87.8% of its initial activity after 10 successive batch reactions. CONCLUSION: The immobilized laccase not only can be operated magnetically, but also exhibits remarkably improved catalytic capacity and stability properties for various parameters, such as pH, temperature, reuse, and storage time, which can provide economic advantages for large‐scale biotechnological applications of laccase. Copyright © 2007 Society of Chemical Industry     

Detoxification of mercury by immobilized mercuric reductase

Mercuric reductase which originated from a recombinant Escherichia coli PWS1 was purified and immobilized on a chemically modified diatomaceous earth support. The mercury reduction kinetics, pH dependence, storage stability, and reusability of the immobilized enzyme were investigated. Four dyes were examined for their electron transfer efficiency with the soluble and bound mercuric reductase. Continuous mercury detoxification by the immobilized mercuric reductase was also performed in fixed‐bed processes. The effects of bed‐length, mercury loading rate, and electron donor on the performance of the fixed beds were assessed. Immobilized mercuric reductase exhibited substrate‐inhibition‐type kinetics with a maximal activity (1.2 nmol Hg mg⁻¹ protein s⁻¹) occurring at an initial Hg²⁺ concentration of 50 µmol dm⁻³. The optimal pH was 7.0 for the soluble and immobilized mercuric reductase, but the immobilized enzyme maintained higher relative activity for less favorable pH values. Immobilization of the enzyme appeared to significantly enhance its storage stability and reusability. Of four artificial electron donors tested, azure A (5 mmol dm⁻³) demonstrated the highest relative activity (78%) for soluble mercuric reductase. For the immobilized enzyme, neutral red (5 mmol dm⁻³) gave a relative activity of nearly 82%. With a fixed‐bed, the mercury‐reducing efficiency of using neutral red was only 30–40% of that obtained using NADPH. Fixed‐bed operations also showed that increased bed length facilitated mercury reduction rate, and the optimal performance of the beds was achieved at a flow rate of approximately 100–200 cm³ h⁻¹. © 1999 Society of Chemical Industry