Stenotrophomonas maltophilia产角蛋白酶对羊毛的作用机理探讨

采用Stenotrophomonas maltophilia产角蛋白酶降解羊毛角朊蛋白,通过测定反应前后残液中巯基和肽键的变化探讨角蛋白酶作用机理。结果表明,角蛋白酶主要作用是断裂角蛋白中的二硫键,也能降解大分子蛋白质,但作用效果不强。羊毛胱氨酸分析结果进一步证明角蛋白酶能断裂羊毛鳞片层中胱氨酸二硫键。SEM结果显示单独使用角蛋白酶对羊毛鳞片去除效果不佳,但角蛋白酶和蛋白酶二浴法工艺能有效降解、剥离羊毛鳞片。     

角质酶及其在纺织工业中的应用

详细综述了国内外对角质酶的研究概况,包括角质酶的主要来源,角质酶基因的克隆与表达,以及关于角质酶的发酵研究。着重阐述了目前角质酶在棉纤维的生物精炼,羊毛的防毡缩整理,以及合成纤维的生物改性等方面的应用进展。另外,作为推动纺织工业清洁生产的关键酶制剂,笔者对未来角质酶在纺织工业中的应用前景作了简要展望。     

产小檗碱内生真菌的诱变

以产小檗碱的内生真菌S6为出发菌株,采用多种单一或复合诱变措施对其菌丝体进行诱变处理,最终筛选得到高产菌株S-NU-302。其小檗碱产量比出发菌株提高170%,达到12.28 mg/L;生长速率提高81.7%,达到5.72 g/L;经10次传代显示该菌株具有良好的遗传稳定性。     

盐酸青藤碱诱导黏连性膝关节强直家兔成纤维细胞凋亡的机制研究

目的 观察盐酸青藤碱对膝关节黏连强直的家兔成纤维细胞增殖和相关基因表达的影响,并进一步尝试探讨其对抗膝关节黏连强直的作用机制。方法 以体外培养法培养成纤维细胞,并设对照组、盐酸青藤碱低中高浓度实验组。CCK-8法检测成纤维细胞增殖的情况;实时荧光定量聚合酶链反应（real-time quantitative PCR,RT-qPCR）法检测经过盐酸青藤碱处理后,成纤维细胞相关基因mRNA表达的改变,用ELISA法检测药物的作用对血清中炎症因子等水平的影响,蛋白质印迹法（Western blot）检测相关蛋白质的表达。结果 盐酸青藤碱能降低成纤维细胞存活率,且随浓度升高存活率逐渐降低。盐酸青藤碱中各个组的效果均十分明显（P<0.05）。在相关基因的mRNA表达层面,与对照组比较,盐酸青藤碱各组炎症因子均显著下调（P<0.05）,凋亡蛋白的表达量显著上升、Bcl-2的mRNA表达量下降（P<0.05）,而PI3K/mTOR/AKT3信号通路分子的mRNA表达量均下降（P<0.05）。在蛋白质表达层面,与对照组相比较,中、高剂量盐酸青藤碱组血清中炎症因子IL-6、IL-...     

水稻矮缩病毒非结构蛋白Pns6的表达及其单克隆抗体的特异性分析

水稻矮缩病毒（RDV）的基因组包含12条双链RNA,其中基因组片段S6编码的非结构蛋白Pns6为该病毒的运动蛋白.在本研究中,在大肠杆菌中表达了N端融合His-tag的重组Pns6蛋白.在低温和低IPTG浓度的诱导后,通过Ni螯合亲和层析进行纯化获得了HisPns6蛋白.稳定性分析表明,HisPns6是一个稳定的蛋白,可耐受37℃下长达24h的处理.纯化的蛋白后续用于单克隆抗体的制备并得到18个杂交瘤细胞株系.使用从感染RDV的水稻叶片中提取的Pns6为样品,以健康水稻总蛋白为对照,通过Western blot法对抗体进行特异性分析,获得了15个阳性抗体.对其进行抗原决定簇分析表明,最敏感的抗原决定簇位于Pns6的C端区域（296~509位氨基酸）.该结果与生物信息学预测分析相吻合.     

酮戊二酸改性壳聚糖微球的制备及其对来氟米特的缓释

采用反相悬浮法制备交联壳聚糖微球,再与α-酮戊二酸反应生成Schiff碱,以NaBH_4还原制得改性壳聚糖微球.用FT-IR,SEM和XRD进行表征.并以来氟米特(LEF)为模型药物,考察了其缓释效果.结果显示:微球对药物的最大包封率为94%,载药量为62%,在缓释初期2 h内微球平均释放药量的16%,后期则呈现缓慢释放的趋势.本论文采用的微粒的药物承载量和释放速度既保证了药物的药效又降低了药物释放速率过快引起的对人体的不良反应.     

土壤中产木聚糖酶菌株的筛选及发酵条件优化

【背景】木聚糖广泛存在于木质纤维类生物质中,是世界上含量最丰富的半纤维素,利用产酶微生物对木质纤维类生物质进行发酵处理是木质纤维类生物质资源化和能源化的有效手段。【目的】通过产木聚糖酶菌株的筛选鉴定、酶学特性分析和发酵条件优化,获得开发多纤维农林废弃物生产新型多元化饲料添加剂的材料。【方法】利用青藏高原土壤筛选产木聚糖酶菌株,通过形态学观察和rDNAITS区域序列分析鉴定菌株XC70种属,对其所产酶的酶学特性及该菌的生长规律和产酶规律进行分析,并利用单因素法和正交试验法优化其发酵条件。【结果】菌株XC70经形态学和分子生物学方法鉴定为草酸青霉(Penicillium oxalicum)。菌株XC70所产木聚糖酶的最适反应条件为:pH 5.0,70°C,温度低于50°C时稳定性较好,具备一定的耐酸性,Na+和K+对木聚糖酶活力具有促进作用(P0.05),在发酵54 h后菌体量和上清液酶活力大小均达到高峰。经过单因素法和正交试验法优化后确定了该菌的最优发酵条件为:蛋白胨7 g/L,玉米秸秆50 g/L,KCl 4 g/L,培养基初始pH 4.0,28°C,摇床转速200r/min,接种量2%。在此发酵条件下,木聚糖酶活力可达到1 489.33U/mL,与优化前相比提高了3倍多。【结论】从青藏高原土壤中筛选获得的菌株XC70具有一定的产木聚糖酶能力,其所产生的酸性木聚糖酶可用于降解多纤维物质开发新型饲料添加剂,具有一定的应用潜力和开发价值。     

盐地碱蓬(Suaeda salsa)中SsINPS基因的分子克隆及表达特性分析

肌醇 1 磷酸 (I 1 P)合成酶 (EC5 .5 .1 .4,INPS)是肌醇生物合成中的关键酶 ,催化葡萄糖 6 磷酸 (G 6 P)到I 1 P的反应。从该实验室已构建的NaCl40 0mmol/L处理的盐地碱蓬 (Suaedasal sa)cDNA文库中克隆了肌醇 1 磷酸合成酶的全长cDNA (S .salsamyo inositol 1 phosphatesynthase,SsINPS) ,基因注册号为AF43 3 879。SsINPS全长约 1 986bp ,含有开放式阅读框架 1 5 3 0bp ,3′和 5′的非翻译区分别为 1 3 9bp和 3 1 7bp ;推导的氨基酸序列全长 5 1 0个氨基酸残基 ,分子量约为 5 6 .7kD ,pI值为 5 .3 5。BLAST同源性分析表明 ,该cDNA与已报告的冰叶日中花 (Mesembryanthemumcrys tallinum)的INPS基因同源性最高 ,其中 ,核苷酸水平的同源性为 91 % ,氨基酸水平上的同源性为84%。以SsINPS全长cDNA为探针进行的South ern杂交结果表明 ,SsINPS基因在盐地碱蓬基因组中只有一个拷贝 ;Northern结果表明 ,在盐处理(40 0mmol/L的NaCl)下 ,SsINPS在叶中的表达量有显著的增加。从而说明SsINPS在盐胁迫下是上升调节的     

小麦秸秆高效腐解菌复合系WSS-1的选育及其菌群分析

采用限制性培养技术和温度梯度诱导法,从四川成都平原多年还田的土壤中筛选得到了常温条件下对小麦秸秆具有高效腐解功能的复合菌系WSS-1。该复合菌系在28℃、4d可完全崩解滤纸,进一步的腐解麦秆的试验效果表明:接种WSS-1处理在第6天左右达到CMC酶活最高值,这比目前广泛使用的菌剂A提前了4d;经WSS-1腐解20d后的麦秆断裂拉力值下降了73.66%,降低幅度分别比空白对照和菌剂A处理多出33.7%和8.9%。采用16S rDNA克隆文库法对其细菌组成进行解析,结果表明WSS-1的优势菌群为枯草芽孢杆菌(Bacillus subtilis)、球形芽孢杆菌(Bacillus sphaericus)、粪产碱菌(Alcaligenes faecalis)双酶梭菌(Clostridium bifermentans)和粪肠球菌(Enterococcus faecalis)。     

木糖发酵产氢菌的筛选及其生长产氢特性研究

利用改进的Hungate厌氧技术, 从牛粪堆肥中分离出一株能有效利用木糖发酵产氢的中温菌HR-1。通过16S rRNA系统发育树分析表明, 菌株 HR-1 与丙酮丁醇梭菌Clostridium acetobutylicum ATCC 824 相似性最高为96%, 结合生理生化和生长特性分析表明, HR-1是梭菌属Clostridium的一个新种, 命名为Clostridium sp. HR-1。菌株HR-1为单胞生长的规则杆状菌(0.3 mm ~0.6 mm)×(1.4 mm~2.3 mm), 革兰氏染色为阴性, 无荚膜、无鞭毛、表面光滑、无明显凸起, 专性厌氧菌。HR-1可在10°C~45°C, pH 4.0~10.0条件下生长; 37°C和pH 8.0分别为其最适生长条件。发酵PYG的主要发酵产物有氢气、二氧化碳、乙酸、丁酸及少量乙醇。HR-1可以利用有机氮源和无机氮源生长并产氢, 酵母提取物是其最佳产氢氮源。HR-1在木糖浓度为3 g/L和初始pH 6.5条件下, 其比产氢量为1.84 mol-H2/mol-木糖, 最大比产氢速率为10.52 mmol H2/h·g-细胞干重。HR-1可以亦利用葡萄糖、半乳糖、纤维二糖、甘露糖和果糖等碳源生长并发酵产氢, 发酵葡萄糖时比产氢量为2.36 mol-H2/mol-葡萄糖。     

Combined use of mild oxidation and cutinase/lipase pretreatments for enzymatic processing of wool fabrics

A cutinase from Thermobifida fusca WSH04 and two lipases, L3126 and Lipex 100L, were applied to the enzymatic pretreatment of wool fabrics followed by protease treatment, aiming at hydrolyzing the outmost bound lipids on the wool surface. A mild oxidation with 2 g/L hydrogen peroxide (30%) was selectively carried out before the enzymatic treatments. The cooperative actions of mild oxidation, cutinase and lipase pretreatments during wool processing were investigated. The results showed that lipase pretreatment alone had less impact on the wettability and anti‐felting ability of wool fabrics than cutinase treatment. Combined use of cutinase and lipase pretreatments did not evidently improve the properties of the wool fabric compared with the individual cutinase pretreatment. By contrast, mild oxidation slightly enhanced the activity of cutinase toward the wool surface and promoted the subsequent proteolytic reactions. The wetting time and contact angle of the protease‐treated fabric deceased to 1.2 min and 55°, respectively; the area shrinkage decreased to 3.1%, with an acceptable strength loss from 489 to 418 N. The changes in the cuticle scales of the wool fibers, confirmed by scanning electron microscopy, further proved the cooperative actions of mild oxidation and cutinase pretreatment during enzymatic wool processing.     

Effects of cutinase on the enzymatic shrink-resist finishing of wool fabrics

A novel microbial cutinase from Thermobifida fusca WSH04 was applied in the pretreatment of wool fabrics followed by protease treatment, aiming at improving the wettability of the samples by hydrolyzing the outmost bound lipids in the wool surface. Cutinase pretreatment could increase the efficacy of the subsequent protease treatment by improving the wettability, dyeability, and shrink-resistance of the wool fabrics. The data obtained by the XPS method showed the changes of elemental concentration in the wool surface after cutinase pretreatment. Compared with the fabrics treated with hydrogen peroxide and protease, the combination of cutinase and protease treatments produced better results in terms of wettability and shrink-resistance with less strength loss. The anti-felting property of the fabrics treated with the enzymatic resist-shrink technique is very promising to meet the commercial standard.     

Improvement of shrink-resistance and tensile strength of wool fabric treated with a novel microbial transglutaminase from Streptomyces hygroscopicus

In this study, a novel microbial transglutaminase (MTG) from Streptomyces hygroscopicus WSH03-13 was applied in the processing of wool fabrics. The results indicated that MTG treatment could improve felting properties and decrease tensile strength loss of wool fabrics. For the wool fabrics used in this study, MTG treatment following chemical and protease pretreatment led to a 2.32% of area shrinkage and about 16% recovery in tensile strength based on the samples without MTG treatment. Moreover, a traditional resin treatment was compared with the role of MTG. Although the tensile strength of wool fabrics treated by MTG was lower than that treated by resin treatment, the fabrics had similar anti-felting properties, and the chemical oxygen demand of wastewater was only half of the latter.     

Bio‐antifelting of wool based on mild methanolic potassium hydroxide pretreatment

Covalently bound lipids cover the wool surface and make enzymatic degradation of wool scales very difficult. In this paper, methanolic potassium hydroxide (MPH) pretreatment was used prior to enzymatic treatment of wool with protease, aiming at hydrolyzing the outmost lipids on the wool surface and promoting the subsequent proteolytic reaction. The efficacy of lipid removal from the fiber surface and the properties of the protease‐treated wool were evaluated. The results indicated that mild MPH pretreatment with 0.10 mol/L MPH for 10 min improved the wettability of the wool without adverse impacts on its mechanical properties. The wetting time and area shrinkage of the wool fabric reached 0.5 s and 5.6%, respectively, and the strength loss was within the acceptable range. Pretreatment with high concentrations of MPH for longer times led to significant damage to the wool fibers and caused heavy strength loss, without improving the antifelting properties after protease treatment. Thus, the combination of mild MPH and protease treatments endowed the wool with desirable properties in contrast to the treatment with protease alone.     

Industrial production of enzyme-modified wool fibers for machine-washable bed coverings

Enzyme technology is explored on wool fibers to prevent shrinkage and consolidation behavior during washing of woolen bed coverings using normal household machine conditions. Enzyme modification of wool fibers after two different pretreatments has been realized on industrial scale. Enlarged proteolytic enzyme by chemical modification was applied successfully to prevent substantial fiber strength loss. Felt-ball analysis of the fibers as obtained from this industrial process showed substantial improvement in felting resistance. Further processing of these enzyme-modified fibers and finally integration in bed covering quilts have been executed successfully on industrial production lines. The observed fiber losses during processing were in the range of 4.5–6% which is comparable with that of nonmodified fibers. The machine-washability of these produced bed covering quilts was tested in a household washing machine using both wool and normal wash programs applied at different temperatures. It appeared that, contrary to the good washing results in terms of shrinkage and consolidation resistance using the wool program at moderate temperatures, this resistance is marginal when washed with the normal washing program with higher mechanical agitation level or with the wool program at elevated temperature. This result was different from that obtained with woolen fabrics and explained by the less-structured organisation of fibers within a fleece.     

Modification of wool surface by liposomes for dyeing with weld

In this research work, wool surface has been modified by liposome to investigate its effects on dyeing with weld, a yellow natural dye. To do this, samples were first treated with aluminium sulphate and afterward with different concentrations of liposomes at various temperatures for 30?minutes and, finally, dyed with weld at 75, 85, and 95°C for 30, 45, and 60?minutes. K/S values of fabric samples were calculated and washing, light and rub fastness properties of the samples were indicated. The results proposed that the sample treated with 1% liposomes and dyed at 75°C for 60?min has the highest K/S value. The central composite design (CCD) used for the experimental plan with three variables on the results of color strength and statistical analysis confirms the optimum conditions obtained by the experimental results. It was also found that washing, light, wet, and dry rub fastness properties of samples dyed with weld, including liposomes, have not significantly changed. The results of water drop absorption indicated that the hydrophobicity is higher for the samples pretreated with liposomes. The SEM picture of wool sample treated with mordant and liposomes and finally dyed with weld shows a coated layer on the fiber surface.     

Similarities and specificities of fungal keratinolytic proteases: comparison of keratinases of Paecilomyces marquandii and Doratomyces microsporus to some known proteases

Based on previous screening for keratinolytic nonpathogenic fungi, Paecilomyces marquandii and Doratomyces microsporus were selected for production of potent keratinases. The enzymes were purified and their main biochemical characteristics were determined (molecular masses, optimal temperature and pH for keratinolytic activity, N-terminal amino acid sequences). Studies of substrate specificity revealed that skin constituents, such as the stratum corneum, and appendages such as nail but not hair, feather, and wool were efficiently hydrolyzed by the P. marquandii keratinase and about 40% less by the D. microsporus keratinase. Hydrolysis of keratin could be increased by the presence of reducing agents. The catalytic properties of the keratinases were studied and compared to those of some known commercial proteases. The profile of the oxidized insulin B-chain digestion revealed that both keratinases, like proteinase K but not subtilisin, trypsin, or elastase, possess broad cleavage specificity with a preference for aromatic and nonpolar amino acid residues at the P-1 position. Kinetic studies were performed on a synthetic substrate, succinyl-Ala-Ala-Pro-Phe-p-nitroanilide. The keratinase of P. marquandii exhibited the lowest Km among microbial keratinases reported in the literature, and its catalytic efficiency was high in comparison to that of D. microsporus keratinase and proteinase K. All three keratinolytic enzymes, the keratinases of P. marquandii and D. microsporus as well as proteinase K, were significantly more active on keratin than subtilisin, trypsin, elastase, chymotrypsin, or collagenase.     

重组角质酶的发酵制备及其对涤纶纤维的表面改性

对大肠杆菌表达嗜热子囊菌Thermobifida fusca角质酶的摇瓶诱导条件及3 L发酵罐扩大培养进行了研究,并探讨了角质酶对涤纶纤维的改性作用。结果表明,在摇瓶培养中,采用工业级TB培养基,用2 g/L乳糖诱导,菌体培养至对数生长前期添加0.5％甘氨酸,角质酶产量可达到128 U/mL。在3 L发酵罐扩大培养中,补料培养生物量 (OD600) 最大达到35,角质酶酶活最高达506 U/mL,是迄今国内外报道细菌来源角质酶的最高水平。紫外分光光度法分析初步表明涤纶纤维经角质酶水解产生了对苯二甲酸类物质     

Isolation and partial characterisation of extracellular keratinase from a wool degrading thermophilic actinomycete strain Thermoactinomyces candidus.

The keratinase production by the thermophilic actinomycete strain Thermoactinomyces candidus was induced by sheep wool as the sole source of carbon and nitrogen in the cultivation medium. For complete digestion of wool by the above strain, both keratinolytic serine proteinase and cellular reduction of disulfide bonds were involved. Evidence was presented that substrate induction was a major regulatory mechanism and the keratinase biosynthesis was not completely repressed by addition of other carbon (glucose) and nitrogen (NH4C1) sources. The enzyme was purified 62-fold by diethylaminoethyl-anion exchange and Sephadex G-75 gel permeation chromatographies. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis indicated that the purified keratinase is a monomeric enzyme with a molecular mass of 30 kDa. The pH and temperature optima were determined to be 8.6 and 70 degrees C, respectively. The purified thermophilic keratinase catalyses the hydrolysis of a broad range of substrates and displays higher proteolytic activity against native keratins than other proteinases. Ca2+ was found to have a stabilizing effect on the enzyme activity at elevated temperatures.