不同真菌漆酶的性质研究

为了更好开发利用漆酶,用邻联甲苯胺法比较分析了彩绒革盖菌、毛栓菌和多孔菌在液体培养时的产酶曲线、酶作用的最适pH值、最适酶解温度及无机离子对酶活的影响。结果表明,不同漆酶产酶曲线不同,彩绒革盖菌和多孔菌,第9d达产酶高峰,峰值活力分别达395.6u/ml和412.2u/ml;毛栓菌,第11d达到产酶高峰,峰值本科活较不同真菌漆酶的性质研究高达554.6u/ml。漆酶性质有明显差别,最适酶解温度不同,彩绀革盖菌和多孔菌漆酶最适酶解温度为25℃;毛栓菌为30℃;最适酶解pH值有差异,彩绒革盖菌漆酶最适酶解,pH值为4.5,毛栓菌为4.0,多孔菌为4.2;不同离子对酶活的影响不同;K^、Zn^2 、对彩绒革盖菌所产漆酶有激活作用;K^ 、Zn^2 、Cu^2 对毛栓菌所产漆酶有激活作用;Mn^2 、Mg^2 对多孔菌所产漆酶有激活作用;Ag^ 、Fe^3 对三种菌所产漆本科均有明显抑制作用。     

碳源和氮源对彩绒革盖菌液体发酵合成漆酶的影响

研究了碳源、氮源对彩绒革盖菌液体发酵合成漆酶的影响。结果表明,在所选的几种碳、氮源中,麸皮为试验菌株合成漆酶的较好碳源;酵母浸膏、酒石酸铵、蛋白胨均是比较理想的氮源。不同的碳氮比对彩绒革盖菌漆酶的产量有着显著的影响,高碳高氮是其生产漆酶的最佳条件。在适宜的培养条件下该菌株能合成高活力的漆酶,其酶活力可达298 U/mL以上,产酶周期为6~7 d。     

毛栓菌(Tramets trogii)液体培养产漆酶的研究

实验研究了碳源、氮源和综合因素对毛栓菌(Tramets trogii)液体培养产漆酶和生长情况的影响。碳源为玉米面、氮源为豆饼粉时,菌株的产漆酶酶活最高;碳源为可溶性淀粉,氮源为麦麸时,对菌株的生长有利;在液体条件下,菌株产漆酶的最佳培养基组成为玉米面3.5%,豆饼粉4.0%,KH2PO40.3%,MgSO40.15%,VB10.04%。     

从白腐菌中筛选漆酶高产菌株的初步研究

从中国分离的149株木腐菌中,有30株具有漆酶活性,在添加了阿魏酸的液体培养基中,漆酶产量高（每升培养液中漆酶含量在10000单位以上）的菌株有9个,游离细胞培养的彩绒革盖菌Coriolus versicolor G30,相邻小孔菌Microporus affinis G07,血红密孔菌Pycnoporus sanguineus W006,W006-2,W3008,G05和香菇Lentinus edodes G18,以及固定细胞培养的鲑贝革盖菌Coriolus consors 98563和干酪菌Tyromyces sp.98420。彩绒革盖菌,相邻小孔菌和血红密孔菌具有重要的生物工程研究价值。     

莱氏野村菌产几丁质酶条件及酶学性质研究

对莱氏野村菌(Nomuraea rileyi)菌株CQ031021产几丁质酶条件及酶学性质进行了研究。结果表明:该菌株最适产酶碳源为2.0%(W/V)葡萄糖,氮源为1.2%(W/V)复合氮源(蛋白胨、牛肉膏按1∶1的比例),接种量为孢悬液2mL(1×107个/mL),培养温度28℃,培养液初始pH6.0,培养时间6d;一定浓度的吐温-80对几丁质酶活性有促进作用,而SDS有抑制作用;粗酶液最适反应温度50℃,最适pH6.0,在40℃以下及pH5.5～6.5范围内酶活力较稳定。     

彩绒革盖菌CV-8胞外漆酶的诱导、纯化及部分性质研究

为探讨彩绒革盖菌(Coriolus versicolor)漆酶的生产条件和性质,对其进行了硫酸铵盐析、半透膜透析、DEAE-纤维素离子交换、Sephadex G100柱层析纯化,粗酶液被纯化36.1倍,比活力10180u/mg,回收率44.6%。凝胶过滤法测定酶的分子量为62kDa。研究了漆酶的产酶曲线及酶作用最适条件。结果表明在该培养条件下,彩绒革盖菌第11d达产酶高峰,峰值酶活为398u/ml,酶作用的最适pH值为4.6,最适温度为25℃,Mg2 、Mn2 、Cu2 对漆酶有激活作用,而Ag 、Fe3 和Cl-则抑制漆酶活性。以邻联甲苯胺为底物的表观Km值为892×10-3mol/L。该菌可作为木质素降解和环保工业漆酶生产菌种。     

毛栓菌漆酶诱导及部分特性研究

研究了碳源、氮源、愈创木酚、香兰素及培养条件对漆酶分泌的影响 ;结果表明 ,麦草粉作碳源、(NH4 ) 2 SO4 作氮源有利于漆酶的分泌 ,适宜浓度的愈创木酚和香兰素等对漆酶的产生有一定的作用 ;pH在 3 0 - 8 0的范围内对漆酶的分泌影响差别不大 ,培养温度、接种量、通气量对漆酶的分泌有较大影响。漆酶最适pH值为 4 0 ,最适反应温度为 30℃ ,K+ 、Zn2 + 、Cu2 + 离子可激活漆酶 ;而Ag+ 、Fe3+ 、Cl- 离子可抑制漆酶活性。漆酶的Km值为 1 81× 10 - 3mol L。     

嗜热菌Anoxybacillu sp.产淀粉酶培养基优化及产酶条件研究

目的：对产淀粉酶嗜热菌Anoxybacillu sp.菌株进行培养基优化及产酶条件研究,以便提高菌株的产酶能力,并为下一步菌 株的诱变育种研究提供基础。方法：常规方法液体培养菌株,用平板初筛和DNS法复筛选择产淀粉酶能力较高的菌株;单因素筛 选培养基最适的碳源、氮源、Ca2+浓度和Mg2+浓度,对单因素筛选的最佳碳源、氮源、Ca2+和Mg2+的三个较佳浓度进行四因素三 水平正交试验优化培养基;对培养基不同pH值及不同培养温度进行培养条件研究。结果：产淀粉酶菌株筛选结果显示：六株菌中 淀粉酶酶活力值最大的是菌株Anoxybacillu sp.DL4,差异有统计学意义（P＜0.05）。培养基单因素筛选结果显示：最适碳源为麦芽糖、最适氮源为 硝酸铵、最适Ca2+、Mg2+浓度均为0.02%,差异有统计学意义（P＜0.05）。培养基优化结果显示：C 源0.1 %,N源0.2 %,Mg2+ 0.04%, Ca2+ 0.04 %为最佳的培养基成分组合。产酶条件筛选结果显示：培养基pH 值为6、培养温度为55 ℃时菌株产酶水平最高,差异有 统计学意义（P＜0.05）。结论：培养基的优化及最适的产酶条件能提高嗜热菌Anoxybacillu sp.DL4 产淀粉酶能力,Ca2+、Mg2+离子 对菌株产淀粉酶有促进作用。     

多孔菌Polyporus W38漆酶的纯化及性质研究

对多孔菌 (PolyporusW 38)漆酶进行了硫酸铵盐析、半透膜透析、SephadexG75及SephadexG2 5柱层析纯化 ,并研究了漆酶的产酶曲线及酶作用最适条件。结果表明在该培养条件下 ,多孔菌第 9d达产酶高峰 ,峰值酶活为 412u/mL ,酶作用的最适pH值为 4.2 ,最适酶解温度为 2 5℃ ,Mg2 +,Mn2 +对漆酶有激活作用 ,而Ag+,Fe3 +和Cl-则能明显抑制漆酶活性。     

从白腐菌中筛选漆酶高产菌株的初步研究

从中国分离的149株木腐菌中,有30株具有漆酶活性。在添加了阿魏酸的液体培养基中,漆酶产量高(每升培养液中漆酶含量在10000单位以上)的菌株有9个:游离细胞培养的彩绒革盖菌Coriolus versicolor G30,相邻小孔菌Microporus affinis G07,血红密孔菌Pycnoporus sanguineus W006,W006-2,W3008,G05和香菇Lentinus edodes G18,以及固定细胞培养的鲑贝革盖菌Coriolus consors 98563和干酪菌Tyromyces sp. 98420。彩绒革盖菌、相邻小孔菌和血红密孔菌具有重要的生物工程研究价值。     

Laccase in Anacardiaceae

The presence of a typical laccase is demonstrated in the cavities of the secretory ducts of a number of species of the Anacardiaceae, including Mangifera indica and Schinus molle. In addition mango fruit contains catechol oxidase. The presence of laccase may be of chemotaxonomic value.     

Laccase fromPleurotus ostreatus

Summary Laccase was purified from culture broth ofPleurotus ostreatus mycelium. The enzyme was a single protein of M_r 59000, pI 2.9 and was active on o-diphenyl substrates. Amino acid composition and N-terminal sequence (15 residues) were determined. Polyclonal anti-laccase antibodies were obtained.     

漆酶及其应用

结合当今该领域的最新研究进展,综述了漆酶来源、结构、作用机制、介体系统及其在水相和非水相中的应用,以期为漆酶催化性能的进一步研究提供一定的借鉴和参考.     

真菌漆酶及其应用

漆酶是一种含铜多酚氧化酶,在白腐菌中普遍存在,少数低等真菌和植物中也产生,多为分泌型糖蛋白。至少20种漆酶得到了分离和纯化。该酶是一种氨基酸残基在500个左右的单体酶,一般都为酸性蛋白,含有4个铜离子,形成3个活性区域;表面一些氨基酸被不同程度地糖基化。晶体结构和其它一些波谱学研究解释了其空间结构和可能的电子传递机制。运用PCR技术和cDNA文库技术,越来越多的漆酶基因被克隆,许多来源的基因都是以家族形式存在于染色体上的。已研究的漆酶基因中都含有10个左右的内含子,这些内含子在活性域位置上有比较高的保守性。一些特殊序列的存在与否决定了该酶的表达形式-诱导型或组成型,诱导型菌株的调控序列中含有一段受酚类化合物作用的序列,而不含有该序列的酶基因则都是组成型表达的。漆酶在S.cerevisiae、Trichodermareesei、A.oryzaeTATAamylase和Pichiapasti等异源表达系统中有成功表达的报道。漆酶的应用集中在以下几方面:漆酶参与的有机合成;生物检测;有毒化合物的消除;工业废水处理;纸浆的生物漂白;等等。     

细菌漆酶的生物信息学分析

漆酶是一种含铜的多酚氧化酶。本研究利用生物信息学分析工具对细菌的漆酶蛋白序列的基本性质、保守结构域、系统发育树以及结构等进行了分析。所分析细菌主要分布在变形菌门、放线菌和厚壁菌门。细菌漆酶的物理化学性质相似,但不同细菌来源的漆酶之间序列相似性较低,但其仍然具有容易识别的保守结构域特征。二级结构及三级结构具有明显的相似性。细菌漆酶的生物信息分析为其功能研究及在其他微生物中研究该类酶提供了基础。     

A Novel Lentinula edodes Laccase and Its Comparative Enzymology Suggest Guaiacol-Based Laccase Engineering for Bioremediation

Laccases are versatile biocatalysts for the bioremediation of various xenobiotics, including dyes and polyaromatic hydrocarbons. However, current sources of new enzymes, simple heterologous expression hosts and enzymatic information (such as the appropriateness of common screening substrates on laccase engineering) remain scarce to support efficient engineering of laccase for better “green” applications. To address the issue, this study began with cloning the laccase family of Lentinula edodes. Three laccases perfectio sensu stricto (Lcc4A, Lcc5, and Lcc7) were then expressed from Pichia pastoris, characterized and compared with the previously reported Lcc1A and Lcc1B in terms of kinetics, stability, and degradation of dyes and polyaromatic hydrocarbons. Lcc7 represented a novel laccase, and it exhibited both the highest catalytic efficiency (assayed with 2,2′-azino-bis(3-ethylbenzothiazoline-6-sulfonic acid) [ABTS]) and thermostability. However, its performance on “green” applications surprisingly did not match the activity on the common screening substrates, namely, ABTS and 2,6-dimethoxyphenol. On the other hand, correlation analyses revealed that guaiacol is much better associated with the decolorization of multiple structurally different dyes than are the two common screening substrates. Comparison of the oxidation chemistry of guaiacol and phenolic dyes, such as azo dyes, further showed that they both involve generation of phenoxyl radicals in laccase-catalyzed oxidation. In summary, this study concluded a robust expression platform of L. edodes laccases, novel laccases, and an indicative screening substrate, guaiacol, which are all essential fundamentals for appropriately driving the engineering of laccases towards more efficient “green” applications.     

出芽短梗霉胞外酸性漆酶

通过愈创木酚法平板检测10株出芽短梗霉,发现5株菌能够分泌胞外多酚氧化酶,反应最适pH在2.0左右,均属于酸性多酚氧化酶。菌株NG的酶活最高,达110 U/mL。添加H2O2、EDTA以及过氧化氢酶不显著影响菌株NG胞外酶活,表明NG分泌的多酚氧化酶中不含有锰过氧化物酶（MnP）和不依赖Mn2＋的过氧化物酶（MiP）,属于漆酶（Lac）。     

Laccase and tyrosinase activities in lichens

Phenoloxidase activity was found in lichenized ascomycetes belonging to different taxonomic groups. Most of the epigeic and epilithic lichens of the order Peltigerales were found to possess both laccase and tyrosinase activities; the lichens of the order Lecanorales possessed only laccase activity, which was an order of magnitude lower than that of Peltigerales. Water-soluble phenoloxidases were present only in peltigerous lichens: activity that could be washed out from intact thalli comprised 10% of that released from disrupted thalli. The activity of the peltigerous lichens and the release of soluble phenoloxidases into the medium increased when the thalli were rehydrated quickly. In some of the lichens tested, the phenoloxidase activity was stimulated by desiccation-rehydration cycles. The oxidases discovered may play an important role in the phenolic metabolism of lichens and be involved in the biochemical reaction of humus synthesis during primary soil formation, which may be a previously unknown geochemical function of these symbiotic microorganisms.     

黑木耳漆酶纯化的研究

目的:研究黑木耳(Auricularia auricula)“黑29”的漆酶纯化,为进一步酶学性质的开展、酶应用和酶基因克隆提供理论基础。方法:采用硫酸铵分级沉淀和柱层析技术分离蛋白,通过PAGE和SDS-PAGE电泳检测蛋白。结果:SDS-PAGE电泳检测发现粗酶液含三种漆酶,分子量大小分别为LacA(60kD)、LacB(34kD)、LacC(19kD);纯化后获得纯化的单一漆酶LacA、LacC组分。结论:得漆酶两个单一组分,为进一步漆酶研究奠定基础。     

漆酶及其应用的研究进展

漆酶是一种含铜的多酚氧化酶,白腐真菌普遍能分泌该酶.有氧条件下,漆酶能催化多种高分子化合物降解,利用该性质漆酶已经广泛应用于生物制浆、污染物生物降解、生物漂白等领域.介绍了目前漆酶在农业和工业各个领域中的应用.