M-26碱性木聚糖酶的分离纯化及酶学性质研究

从Bacillus pumilus M-26发酵液中分离纯化碱性木聚糖酶,进行酶学性质研究,同时制备工业用碱性木聚糖酶制剂。首先将M-26发酵液进行硫酸铵盐析,制备工业用碱性木聚糖酶干品;然后进行sephadexG-25层析脱盐和cellulose DE-52层析得以纯化。硫酸铵的饱和度50%,酶制剂的酶活可达9 000 IU/g,收率为85%;分离纯化使酶的比活为126.32 IU/mg蛋白,纯化倍数为19.89,酶的回收率12.83%;分子量约为20 ku;M-26碱性木聚糖酶的最适温度和pH分别是55℃和pH 8.0,具有一定的耐碱性;该酶无纤维素酶活性,Fe2＋对其有激活作用;Mn2＋、Zn2＋、Fe3＋、Cu2＋对其具有抑制作用。短小芽胞杆菌M-26碱性木聚糖酶具有纸浆生物漂白应用前景。     

黑曲霉产木聚糖酶的分离纯化与鉴定研究

木聚糖酶的分离纯化是对其进行酶学研究和分子改良研究的基础。利用实验室选育的黑曲霉菌株Aspergillus niger SM24/a进行木聚糖酶发酵,粗酶液经过(NH_4)_2SO_4分级沉淀Bio-Gel P6除盐、UNO sphere Q阴离子交换和Enrich SEC70凝胶色谱层析四个步骤的分离纯化,成功获得了3种木聚糖酶蛋白定义为X-Ⅰ、X-Ⅱ和X-Ⅲ。随着纯化步骤的增加,各组分酶比活力得到显著提高,其数值分别为37.41、34.56和53.96 U/mg,纯化倍数分别为3.96、3.66和5.72。经质谱分析和蛋白氨基酸序列比对,初步认定X-Ⅰ属于糖基水解酶第十家族内切-β-1,4-木聚糖酶,X-Ⅱ和X-Ⅲ均属于糖基水解酶第十一家族木聚糖酶。     

基因工程菌1020耐热木聚糖酶的纯化

目的：提纯基因工程菌1020耐热木聚糖酶。方法：超声破碎细胞,而后经过热变性处理和Ni—NTA亲和层析分离纯化。结果：根据pET System Manual的方法分析木聚糖酶主要分布在可溶性细胞质中;超声破壁功率400W,破碎15min时效果最佳;粗酶液经过70℃,热变性30min处理后,纯化倍数达到4．9;采用Ni—NTA Sephrose F．F一步层析可以得到电泳纯的木聚糖酶,纯化倍数13．4,得率29．4％。结论：热变性处理是一种有效的提纯手段,合理的条件可以使纯化倍数提高;Ni—NTA亲和层析是纯化含His标签的目的酶的特异高效纯化方法。     

柞蚕微孢子虫孢子分离纯化方法

柞蚕微粒子病是柞蚕Antheraea pernyi(Guérin-Méneville)的主要胚胎传染性病害,病原为柞蚕微孢子虫Nosema pernyi(Wenet Ding),其病原分离提纯技术研究对于柞蚕微粒子病的防治具有重要意义。本文利用差速离心和Percoll密度梯度离心法研究了柞蚕微孢子虫孢子的分离纯化方法,结果表明,采用不连续密度梯度分离纯化柞蚕微孢子虫孢子的效果比单一浓度的效果好,以浓度为25%、50%、75%、100%不连续梯度,15000r/min离心30min分离纯化得到的柞蚕微孢子虫孢子纯净度高。     

疫苗分离纯化研究进展

综述了国内外关于疫苗分离纯化的研究进展,系统介绍了目前可用作各类疫苗(尤其是基因工程疫苗)分离纯化的方法。沉淀和离心等传统分离技术在各类疫苗的分离纯化中应用广泛,层析技术和其它分离技术的结合已成为疫苗分离纯化的主流,新型膜技术和亲和层析在基因工程亚单位疫苗分离纯化中的作用引人注目。     

溶菌酶分离纯化方法的研究进展

对近年来溶菌酶分离纯化的方法,如离子交换法、色谱法、膜处理技术、反胶团萃取法、亲和层析等进行了综述,并讨论了分离纯化方法的应用前景。     

离子交换色谱在细菌素分离纯化中的应用

近年来,乳酸菌细菌素在食品防腐剂和医药领域有着广泛的应用前景,而细菌素的分离纯化是其分子结构及遗传学特性等相关研究的重要基础。离子交换色谱是细菌素分离纯化的主要手段之一。本文阐述了离子交换色谱原理,分析了影响离子交换色谱分离纯化细菌素的各种因素,探讨了细菌素分离纯化中离子交换色谱条件的选择。     

现有溶酶体分离纯化技术的对比、分析和应用

溶酶体作为真核细胞中重要的细胞器,不仅是降解内外源物质的场所,也是细胞能量感知和调节的中心,能够协调细胞物质的转运、代谢和分泌。溶酶体稳态失衡会导致许多疾病,如溶酶体贮积症、肿瘤、免疫缺陷和神经退行性疾病。获得完整、高纯度的溶酶体是研究其微观结构、稳态调控和相关分子功能的重要前提。目前常用的溶酶体分离纯化技术包括离心分离纯化、荧光辅助细胞器分选、亲和免疫分离纯化、磁性纳米颗粒分离纯化和Lyso-IP等。该文综述现有溶酶体分离纯化技术的原理、特点和应用,并对它们进行对比分析。     

果胶酶分离纯化及分析方法的研究进展

果胶酶能降解果胶质,在果汁制造、果酒酿造等方面有着广泛应用。果胶酶分子生物学的迅速发展极大地促进了分离纯化与分析方法的研究。由于不同菌种产生的果胶酶成分复杂程度不同,分离纯化手段和分析方法也不相同。本文对果胶酶分离纯化手段及其分析方法进行了综述。     

人凝血酶原复合物离子交换树脂的筛选及吸附性能研究

采用若干种人工合成的大孔阴离子交换树脂,对人血浆中凝血酶原复合物(PCC)的分离纯化性能进行了研究.同时.将DEAE-Sephadex A50时PCC的分离纯化性能与该类人工合成分离纯化材料进行了对比.研究结果表明,在各种人工合成大孔阴离子交换树脂中,CG-6对PCC具有较优的分离纯化性能;并系统研究了CG-6树脂对PCC分离纯化性能.     

A new look at xylanases: an overview of purification strategies

Interest in xylanases from different sources has increased markedly in the past decade, in part because of the application of these enzymes in the pulp and paper industry. Purity and purification costs are becoming important issues in modern biotechnology as the industry matures and competitive products reach the marketplace. Thus, new paths for successful and efficient xylanase recovery have to be followed. This article reviews the isolation and purification methods used for the recovery of microbial xylanases. Origins and applications of xylanases are described, highlighting the special features of this class of enzymes, such as the carbohydrate-binding domains (CBDs) and their importance in the development of affinity methodologies to increase and facilitate xylanase purification. Implications of recombinant DNA technology for the isolation and purification of xylanases are evaluated. Several purification procedures are analyzed, taking into consideration the sequence of the methods used in each and the number of times each method is used. New directions to improve xylanase separation and purification from fermentation media are described.     

Engineering Thermostable Microbial Xylanases Toward its Industrial Applications

Xylanases are one of the important hydrolytic enzymes which hydrolyze the β-1, 4 xylosidic linkage of the backbone of the xylan polymeric chain which consists of xylose subunits. Xylanases are mainly found in plant cell walls and are produced by several kinds of microorganisms such as fungi, bacteria, yeast, and some protozoans. The fungi are considered as most potent xylanase producers than that of yeast and bacteria. There is a broad series of industrial applications for the thermostable xylanase as an industrial enzyme. Thermostable xylanases have been used in a number of industries such as paper and pulp industry, biofuel industry, food and feed industry, textile industry, etc. The present review explores xylanase–substrate interactions using gene-editing tools toward the comprehension in improvement in industrial stability of xylanases. The various protein-engineering and metabolic-engineering methods have also been explored to improve operational stability of xylanase. Thermostable xylanases have also been used for improvement in animal feed nutritional value. Furthermore, they have been used directly in bakery and breweries, including a major use in paper and pulp industry as a biobleaching agent. This present review envisages some of such applications of thermostable xylanases for their bioengineering.     

黑曲霉木聚糖酶的底物特异性和低聚木糖生产

对黑曲霉（Ａｓｐｅｒｇｉｌｌｕｓ ｎｉｇｅｒ）木聚糖酶进行了纯化研究,结果表明,经Ｓｅｐｈａｄｅｘ Ｇ－１００和ＤＥＡＥ－ＳｅｐｈａｄｅｘＡ－５０分离后,获得三个组分,称为Ｘ１、Ｘ２、Ｘ３。它们经ＰＡＧＥ电泳分析均为单一组分。对Ｘ１、Ｘ２、Ｘ３的相关性质,特别是底物特异性也作了研究,纯酶Ｘ３组分或部分纯化的酶可用于生产低聚木糖,产品得率为１０％。     

酸性木聚糖酶的研究进展

综述了酸性木聚糖酶的产生、纯化和性质、结构基础及应用。发酵底物和pH对酸性木聚糖酶的产生影响很大。酸性木聚糖酶在pH4．0以下是稳定的,在酿酒工业和饲料工业有潜在的广泛用途。     

Engineering of xylanases for the development of biotechnologically important characteristics

Xylanases are the main biocatalysts used for the reduction of the xylan backbone from hemicellulose, randomly splitting off β-1,4-glycosidic linkages between xylopyranosyl residues. Xylanase market has been annually estimated at 500 million US Dollars and they are potentially used in broad industrial process ranges such as paper pulp biobleaching, xylo-oligosaccharide production, and biofuel manufacture from lignocellulose. The highly stable xylanases are preferred in the downstream procedure of industrial processes because they can tolerate severe conditions. Almost all native xylanases can not endure adverse conditions thus they are industrially not proper to be utilized. Protein engineering is a powerful technology for developing xylanases, which can effectively work in adverse conditions and can meet requirements for industrial processes. This study considered state-of-the-art strategies of protein engineering for creating the xylanase gene diversity, high-throughput screening systems toward upgraded traits of the xylanases, and the prediction and comprehensive analysis of the target mutations in xylanases by in silico methods. Also, key molecular factors have been elucidated for industrial characteristics (alkaliphilic enhancement, thermal stability, and catalytic performance) of GH11 family xylanases. The present review explores industrial characteristics improved by directed evolution, rational design, and semi-rational design as protein engineering approaches for pulp bleaching process, xylooligosaccharides production, and biorefinery & bioenergy production.     

Purification and properties of the xylanases from the termite Macrotermes bellicosus and its symbiotic fungus Termitomyces sp.

Four xylanases were purified, two from the termite Macrotermes bellicosus workers (X1T and X2T) and two from its symbiotic fungus Termitomyces sp. (X1Mc and X2Mc). The analysis of the step required for the purification of X1T and X1Mc and the comparison of their different properties suggested that xylanases X1T and X1Mc were the same enzyme, X1. The determination of the reducing sugars by TLC revealed that X1 was an endoxylanase (EC 3.2.1.8) and X2T and X2Mc were exoxylanases (EC 3.2.1.37). The apparent molecular weights of the three xylanases, determined by SDS-polyacrylamide gel electrophoresis, were 36 kDa for X1, 56 kDa for X2T and 22.5 kDa for X2Mc. The optimal pH of the three xylanases was 5.5, and K_m values determined with birchwood xylan as substrate were 0.2% for X1, 0.1% for X2T and 0.3% for X2Mc, showing a high affinity for this substrate. The three enzymes differed also by their thermal stability.     

Application of the affinity binding of xylanases to oat-spelt xylan in the purification of endoxylanase CM-2 from Streptomyces chattanoogensis CECT 3336

bstract The use of the insoluble polysaccharides Avicel and oat-spelt xylan for the binding and subsequent purification of active xylanases from Streptomyces chattanoogensis was investigated. Maximum recovery of xylanases was achieved with oat-spelt xylan, using NaCl (2 M) to remove active protein. The application of this technique to the purification of xylanases resulted in the purification of an endoxylanase (CM-2) with high specific activity (729.5 U mg⁻¹). The properties of the purified enzyme, exhibiting activity and stability between 40 °C and 60 °C and between pH 5 and 8, suggest a potential role for both the enzyme and the rapid purification protocol in the removal of hemicelluloses from kraft pulp prior to bleaching. Received: 6 April 1998 / Accepted: 8 May 1998     

Trichoderma Xylanases,Their Properties and Application

Abstract

Trichoderma spp. are known to produce enzymes with high xylanolytic activity. Different xylanases and various components of their xylanolytic system have been identified and purified. Some of the xylanases have been characterized extensively with respect to their physicochemical, hydrolytic, and molecular properties. Cellulase-free xylanase preparations have been tested successfully in industrial applications such as the prebleaching of kraft pulps in the pulp and paper industry. Future work on understanding the functional significance of xylanase multiplicity, the mechanisms of xylanase prebleaching, and the structural conformation of xylanases could lead to improved or alternative applications of Trichoderma xylanases.     

Sequence and Structural Features of Subsite Residues in GH10 and GH11 Xylanases

Xylanases are the enzymes that breakdown complex plant cell wall polysaccharide xylan into xylose by hydrolysing the β-(1→4) glycosidic linkage between xylosides. They mainly belong to the families GH10 and GH11 of the glycoside hydrolase claβs of enzymes. GH10 xylanases have (α/β)₈-barrel type of fold whereas GH11 xylanases have β-jelly roll type of fold. Both enzymes have several substrate binding subsites. This study analysed in detail the sequence and structural conservation of subsites residues by examining their 3D structures crystallized with homoxylan or its non-hydrolysable form as substrate. A total of 19 structures from GH10 and 6 structures from GH11 were analysed. It was found that in GH10 the subsites -3 to -1 consisted of conserved residues, whereas in GH11 subsites -1, -3 and +1 were found to be conserved. The substrate and subsite interaction analysed based on the presence of h-bonds and CH-π interactions showed that Face-to-Face or Edge-to-Face CH-π interactions are formed in the subsites of GH10, whereas such specific CH-π interactions were no at all observed in case of GH11 xylanases. The spatial conservation of subsite residues was also analysed using a distance matrix based approach. It was found that in GH10 xylanases conserved residues have conserved spatial position of those residues as opposed to GH11 enzymes where in subsites -2 and +2 conserved residues showed non-conservation in their spatial positions. The results presented in this study can be used in discovering new xylanases and in the engineering highly efficient xylanases.     

Xylanases from marine microorganisms: A brief overview on scope,sources, features and potential applications

Global economic growth often leads to depletion of raw materials and generation of greenhouse gases, as industry manufactures goods at ever increasing levels to keep up with the demand. The currently implemented production processes mostly rely on non-renewable resources, they suffer from high energy consumption, and generate waste that often has a negative environmental impact. Eco-friendly production methods are therefore intensely searched for. Among them, enzyme-based processes are appealing, because of their high substrate and reaction specificity and the relatively mild operation conditions required by these catalysts. In addition, renewable raw materials that allow sustainable production processes are also widely explored. Marine xylanases, which catalyze the hydrolysis of xylan, the major component of lignocellulose, are promising biocatalysts. Since they are produced by microorganisms that thrive in a wide variety of environmental conditions, the enzymes may be active at widely different ranges of pH, temperature, and salt concentrations. These properties are important for their successful application in various industrial processes, such as production of bioethanol, bleaching of paper and pulp, and in the food and feed sector. The present work gives a brief overview of marine sources of xylanases, their classification and features, and of the potential applications of these marine enzymes, especially in sustainable processes in the scope of circular economy.