白腐真菌漆酶的固定化及其应用研究*

以尼龙网为载体,戊二醛为交联剂,进行固定化真菌漆酶的条件优化和性质研究,优化条件为：尼龙网在5％的戊二醛溶液中交联6h后,加入30U漆酶溶液固定8h,酶活回收率为50．3％。与游离酶相比,固定化漆酶的热稳定性明显提高,最适pH值略有下降。用该固定化漆酶处理低浓度造纸废水,经过8批次连续试验,酶活保留52％。     

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。     

壳聚糖固定化真菌漆酶及其用于处理酚类污染物的研究

Trametessp. AH282在液体培养条件下经邻甲苯胺诱导能有效合成漆酶同工酶A。以壳聚糖为载体,戊二醛为交联剂进行了漆酶A的固定化研究,确定酶固定化适宜条件为：0.1g壳聚糖与15 mL 5%戊二醛交联8 h后,加入30.0U酶固定12h。在此条件下获得的固定化漆酶催化能力为176.4U/g载体,酶活回收率58.5%。与游离酶相比,固定化漆酶与作用底物愈创木酚的亲和力降低,但固定化酶的稳定性有明显改善。固定化漆酶的最适温度为55℃,比游离酶提高5℃;70℃条件下保温8 h,固定化酶保留酶活56.5%,而在相同条件下游离酶酶活明显下降。使用固定化漆酶反应装置进行酚类化合物转化实验,连续进行12批次操作,固定化酶酶活仍保持60%以上,漆酶使用效率明显提高。     

磁性聚乙二醇载体固定化葡萄糖淀粉酶的研究

以磁性聚乙二醇为载体,通过吸附-交联法固定化糖化酶.研究了戊二醛浓度、pH值及加酶量对酶固定化的影响.并对固定化酶的最适温度、最适pH、米氏常数、热稳定性及操作稳定性等进行了探讨.     

蒜氨酸酶的固定化及其酶学性质研究

为了提高蒜氨酸酶的稳定性并实现酶的反复利用,研究了影响蒜氨酸酶固定化的因素及固定化蒜氨酸酶的酶学性质。蒜氨酸酶的固定化以壳聚糖微球为载体,戊二醛为交联剂,固定化的最适条件为：戊二醛浓度4%,给酶量20.2U,交联时间2h。固定化蒜氨酸酶的最适pH值7.0,最适温度35℃,米氏常数Km 7.9 mmol/L,操作稳定性比较好,连续使用10次后酶活力损失低于10%。     

高分子膜载体固定化木瓜蛋白酶

在浸润条件下,以0.5%(v/v)戊二醛交联的高分子膜尼龙载体固定化木瓜蛋白酶。对固定化条件进行了优化,比较了固定化酶与游离酶的酶学参数。结果表明,4℃、pH6.0条件下,将膜载体浸润于2mg/mL酶液中5h,固定化酶活为303.4U/g。固定化酶最适反应pH为6.0～7.0,最适反应温度为65℃。其pH稳定性、热稳定性均比游离酶高。     

米曲霉F-81产中性蛋白酶的固定化条件及其特性

以海藻酸钠为载体,戊二醛为交联剂固定化米曲霉F-81产中性蛋白酶,研究了固定化条件及固定化酶的性质。结果表明,固定化的最佳条件为:固定化时间1 h、海澡酸钠浓度4%、戊二醛浓度9%、CaCl2浓度0.7 mol/L。在此条件下固定化的中性蛋白酶活力为游离酶活力的68%。固定化酶的最适作用温度为65℃,最适作用pH值为7.0。60℃下酶稳定性较好,80℃下处理60 min,粗酶中几乎检测不到酶活力;中性蛋白酶pH稳定范围为6.5-9.5。Km值为24.83 mg/mL,最大反应速率Vmax为0.043 12 mg/min。     

谷胱甘肽硫转移酶(GST)的固定化及酶学特性研究

对谷胱甘肽硫转移酶的固定化、游离酶和固定化酶的酶学特性进行了研究,通过试验,确定谷胱甘肽硫转移酶的最佳固定化条件为先用2％壳聚糖吸附酶,然后再加戊二醛交联,交联用戊二醛浓度为1．2％,交联时间6h;游离酶的最适温度为45—55℃,最适pH值为6．5-7．0：固定化酶的最适温度为45-50℃,最适pH值为7．0;游离酶和固定化酶的最适酶促反应时间为30min。     

氨基末端磁性载体固定化中性蛋白酶的研究

以氨基末端磁微粒为载体,用戊二醛作交联剂,通过共价交联结合法固定化AS1.398中性蛋白酶.可以制备出活力达45 000 U/g磁性固定化酶.探讨了该载体对中性蛋白酶的最适固定化条件,并对磁性固定化酶的热稳定性,储存稳定性、操作稳定性等进行了研究,确定了此载体对酶的固载能力大于200 mg/g（载体）,及固定化磁性酶最适pH为7.5, 最适温度为60℃等催化特性.     

磁性Fe_3O_4/聚苯胺纳米纤维的制备及其固定漆酶研究

合成优良的漆酶固定化载体有利于其进一步应用。通过将磁性纳米颗粒包埋在苯胺的聚合物中形成磁性Fe_3O_4/聚苯胺纳米纤维,作为漆酶固定化载体。透射电镜和红外图谱分别显示了载体的形态结构特征。不同比例的Fe_3O_4与苯胺对载体结构没有明显影响,但会影响酶的负载量。合成载体最大酶负载量为210 mg/g,固定漆酶后的载体导电性能发生变化。固定化漆酶最适pH从4偏移到3.5,在酸性pH范围保持较高的酶活性,最适温度为60℃;在50℃下孵育240 min,能保持约50%的酶活性,于4℃下保存30 d能保持约60%的酶活性;重复使用8次后还能保留70%的酶活性;结果证实了磁性Fe_3O_4/聚苯胺纳米纤维成功合成,对酶有较高的负载量。随着Fe_3O_4的比例增加,载体对漆酶的负载量却减少;漆酶与载体间存在有一定电子交流。固定化漆酶的最适pH向酸性偏移可能和聚苯胺的导电性有关,合成载体显示出良好的热稳定性、储存稳定性和重复使用稳定性,表明磁性Fe_3O_4/聚苯胺纳米纤维是一种优良的酶固定化载体,可以实现酶的高效固定化。     

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.     

Laccase immobilization on the tailored cellulose-based Granocel carriers

Extracellular laccase produced by Cerrena unicolor was immobilized by adsorption or covalent bonds formation on the cellulose-based carrier Granocel. Immobilization was optimized by changing the anchor groups and the methods of activation/immobilization. On the base of measured activity and stability of immobilized preparations, the covalent method was selected. It was shown that coupling of the enzyme to the carrier via divinyl sulfone or glutaraldehyde yielded an enzyme-carrier preparation of high activity and storage stability. Further optimization of the carrier's superstructure consisted in changing pore diameters and amount of functional groups on the carriers surface. Three-fold higher activity was noted when the enzyme was immobilized on NH2-modified Granocel with the highest size exclusion limit and amino group content. Relatively low products sorption was observed on the carrier surface. The effects of protein concentration and pH-value of the coupling mixture on immobilization efficiency were evaluated also.     

桦褶孔菌漆酶固定化及其对染料的降解

采用壳聚糖交联法和海藻酸钠-壳聚糖包埋交联法固定化桦褶孔菌产生的漆酶,探讨最佳固定化条件,固定化漆酶的温度,pH稳定性及操作稳定性,并以两种固定化酶分别对4种染料进行了降解.结果表明:(1)壳聚糖交联法固定化漆酶的最佳条件为:壳聚糖2.5%,戊二醛7%,交联时间2h,固定化时间5h,给酶量1g壳聚糖小球:1mL酶液(1U/mL),固定化效率56%;(2)海藻酸钠-壳聚糖包埋交联法固定化漆酶的最佳条件为:海藻酸钠浓度4%,壳聚糖浓度0.7%,氯化钙浓度5%,戊二醛浓度0.6%,给酶量4mL 4%海藻酸钠:1mL酶液(1U/mL),固定化效率高达86%;(3)固定化的漆酶相比游离漆酶有更好的温度和pH稳定性;(4)比较两种固定化漆酶,海藻酸钠-壳聚糖包埋交联法固定化酶的温度及酸度稳定性要优于壳聚糖固定化酶,但可重复操作性要弱于后者,两者重复使用8次后的剩余酶活比率分别为71%及64%;(5)两种固定化酶对所选的4种不同结构的合成染料均有较好的降解效果,其中壳聚糖固定化酶对茜素红的降解效果及重复使用性极佳,重复降解40mg/L的茜素红10次,降解率仍保持在100%.     

Comparative studies on immobilized laccase behaviour in packed-bed and batch reactors

Extracellular laccase produced by the wood-rotting fungus Cerrena unicolor was immobilized covalently via glutaraldehyde to cellulose-based carrier Granocel. Laccase was partially purified by membrane concentration and diafiltration followed by precipitation with acetone. Five-fold increase in the measured activity of immobilized enzyme was obtained when six times purer laccase was used for immobilization. For the best preparation, with very high activity of 2053 U per 1 mL of the carrier, thermal- and pH-stability, and activity profiles were determined. Experiments carried out in a batch reactor showed that k_cat/K_m for immobilized enzyme (0.65) is three times lower than the value obtained for the native laccase (2.19) whereas k_cat/K_m estimated from continuous reactor (1.50) is notably closer to that for the native enzyme. Continuous process probably reflects more precisely kinetics of the reaction accompanied by simultaneous product precipitation on the carrier’s surface. Operational stability of immobilized laccase was tested in continuous mode operation with ABTS, guaiacol and trichlorophenol as substrates and showed that packed-bed reactor is unprofitable system for laccase immobilized on Granocel carrier due to the high bed compaction. However, excellent stability of the preparation was noted under 20 successive runs in the well mixed tank reactor and better ability towards trichlorophenol biotransformation was observed in the case of immobilized laccase.     

Zinc tetraaminophthalocyanine-Fe3O4 nanoparticle composite for laccase immobilization

Zinc tetraaminophthalocyanine-Fe3O4 nanoparticle composites were prepared by organic-inorganic complex technology and characterized. It has been proved that the ZnTAPc dispersed randomly onto the surface of Fe3O4 nanoparticles to form molecular dispersion layer and there was a relatively strong bond between central zinc cation and oxygen. The nanoparticle composite took the shape of roundish spheres with the mean diameter of about 15 nm. Active amino groups of magnetic carriers could be used to bind laccase via glutaraldehyde. The optimal pH for the activity of the immobilized laccases and free laccase were the same at pH 3.0 and the optimal temperature for laccase immobilization on ZnTAPc-Fe3O4 nanoparticle composite was 45 degrees. The immobilization yields and K(m) value of the laccase immobilized on ZnTAPc-Fe3O4 nanoparticle composite were 25% and 20.1 microM, respectively. This kind of immobilized laccase has good thermal, storage and operation stability, and could be used as the sensing biocomponent for the fiber optic biosensor based on enzyme catalysis.     

Improvement in stability of an immobilized fungal laccase

Summary A laccase of the basidiomyceteTrametes versicolor was immobilized on porous glass beads that were activated with 3-aminopropyltriethoxysilane and glutaraldehyde. The support immobilized 100% of the enzyme, whereupon 90% of the original activity was retained. After immobilization, the enzyme was active in a wider pH and temperature range, and its heat stability and reuse were greatly improved compared to those of the free laccase. The immobilized enzyme was found reusable in treating different substrates, either recycled alone or in a sequential order.     

漆酶固定化及其在小型酶反应器中的应用

以尼龙网为载体,戊二醛为交联剂,固定化真菌漆酶。用固定化酶在自行设计的小反应器中降解低浓度造纸废水,试验结果如下：当废水COD的浓度控制在3000 mg/L左右,降解时间为26h,废水的COD去除率达到35%。     

Laccase immobilization on enzymatically functionalized polyamide 6,6 fibres

Polyamide matrices, such as membranes, gels and non-wovens, have been applied as supports for enzyme immobilization, although in literature the enzyme immobilization on woven nylon matrices is rarely reported. In this work, a protocol for a Trametes hirsuta laccase immobilization using woven polyamide 6,6 (nylon) was developed. A 2⁴ full factorial design was used to study the influence of pH, spacer (1,6-hexanediamine), enzyme and crosslinker concentration on the efficiency of immobilization. The factors enzyme dosage and spacer seem to have played a critical role in the immobilization of laccase onto nylon support. Under optimized working conditions (29 U mL⁻¹ of laccase, 10% of glutaraldehyde, pH = 5.5, with the presence of the spacer), the half-life time attained was about 78 h (18% higher than that of free enzyme), the protein retention was 30% and the immobilization yield was 2%. The immobilized laccase has potential for application in the continuous decolourization of textile effluents, where it can be applied into a membrane reactor.     

氨基树脂固定化L-苏氨酸醛缩酶及其应用*

L-苏氨酸醛缩酶(L-Threonine aldolase,L-TA)可以催化甘氨酸和醛合成β-羟基-α-氨基酸。β-羟基-α-氨基酸具有两个手性中心,是多种手性药物的中间体。但是,游离的L-TA难以重复利用,分离纯化困难,严重阻碍了工业化应用。固定化技术可以有效解决这些问题。利用氨基树脂NAA固定化来源于Bacillus nealsonii的L-苏氨酸醛缩酶,采用戊二醛作为交联剂,经过条件优化确定最佳固定化条件为:加酶量13 U、载体量0.6 g、0.4%(V/V)戊二醛、活化时间2 h、pH 8.5、35℃、固定化5 h。在此条件下,固定化酶酶活回收率为85.7%。在30℃下半衰期可达59天,为游离酶的6.5倍。将其应用于合成L-syn-对甲砜基苯丝氨酸,使用460 h后,残余酶活为79.4%。进一步开发了载体再利用策略,将失活固定化酶表面的氨基用戊二醛活化后,再与新的游离酶进行固定化,实现载体的再利用。利用该方法载体可重复利用两次,制备的固定化酶仍能使用460 h。该方法大大降低了固定化成本,为固定化L-TA的工业化应用打下坚实的基础。