纤维基质对液体培养灵芝产纤维素酶的影响

本研究通过在培养基中添加滤纸、羧甲基纤维素(CMC)、蔗渣和玉米芯等纤维素类基质,观察纤维素基质对液体培养条件下灵芝产纤维素酶和半纤维素酶的影响.结果表明,这些纤维素基质能促进纤维素酶活力的增加,促进作用效果各异,当滤纸的添加量达到1 g/L时,滤纸酶活(FP酶活)达到空白对照的9.04倍,当蔗渣添加量为1 g/L时,灵芝β-1,4-葡聚糖酶酶活(Cx酶活)、FP酶活、半纤维素酶活分别比空白对照样增加了12%、534%、117.3%.     

较高温度对灵芝培养特性及灵芝酸产量的影响

灵芝具有重要的药用价值,培养条件的优化可提高灵芝中各种活性成分的含量。探讨了较高温度对灵芝发酵过程中的生理指标及灵芝酸产量的影响。结果表明,较高的发酵温度虽然降低了灵芝生物量,但提高了淀粉酶﹑漆酶﹑纤维素酶的酶活。发酵第4天,36℃培养条件下淀粉酶酶活达到最大值,比30℃发酵条件下的酶活提高了22.61%。发酵第10天,34℃培养条件下的漆酶酶活﹑纤维素酶酶活﹑可溶性糖含量和灵芝酸产量都达到最大值,相对于30℃的培养条件,分别提高了51.12%、30.41%、13.21%和45.23%。结果表明较高温度发酵有利于酶活和灵芝酸含量的提高,该研究为灵芝的高温发酵提供了新的思路和理论指导。     

里氏木霉液体发酵产纤维素酶的研究

在摇瓶试验基础上,采用里氏木霉(Trichoderma reesei)HC-415菌株进行5L自控罐产纤维素酶深层发酵试验。在通气量为 0.2—0.6vvm、搅拌速度为 400r/min、发酵液pH控制在5.8—6.1的条件下,发酵液的羧甲基纤维素(CMC)酶酶活最高为325.0mg糖/ml,滤纸糖酶(FPA)酶活最高达17.9mg糖/ml。发酵周期为108h。所得冻干纤维素酶粉CMC酶活最高3111IU/g,FPA最高135IU/g ,对发酵液得率平均6.7g/L。酶活总收率CMC酶活平均78.2％,FPA酶活平均73.5％。     

液态发酵条件下拟康宁木霉8985产纤维素酶能力初探

液态发酵条件下,以微晶纤维素为唯一碳源,比较了拟康宁木霉Trichoderma koningiopsis 8985和里氏木霉T.reesei QM9414产纤维素酶的能力。8985发酵12 h开始产生纤维素酶,36 h时酶活达到产酶峰值的50%,此时QM9414尚未诱导产酶。测定8985发酵84 h时上清液中滤纸纤维素酶、羧甲基纤维素酶、β-葡萄糖苷酶和木聚糖酶的酶活分别为1.06、3.62、1.80和6.67 IU/mL,分别是QM9414上述酶活的1.72、1.70、6.35和1.12倍。8985滤纸纤维素酶酶活的最适反应条件为pH 4.5,反应温度50℃,在Fe³⁺(≤4 mmol/L)和Cu²⁺(0–10 mmol/L)存在条件下酶活稳定。     

从海水环境分离筛选甘蔗渣纤维素降解菌

【目的】筛选海水环境高效甘蔗渣纤维素降解菌,并研究不同菌株间的混合发酵对甘蔗渣纤维素酶活力的影响,为纤维素降解菌在海水养殖中的应用提供理论基础。【方法】采用刚果红染色法进行菌株初筛,利用DNS法测定各菌株胞外纤维素酶活力及不同菌株间的混合酶液与混合发酵酶液的纤维素酶活力。【结果】筛选得到两株具有较强纤维素分解能力的细菌菌株Z4和S5,经16S rRNA基因序列分析,初步鉴定为地衣芽孢杆菌(Bacillus licheniformis)。菌株S5具有最高的全酶活和甘蔗渣纤维素酶活,分别为1.16 U/mL和2.80 U/mL。菌株Z4与S5间混合发酵能明显提高菌株的纤维素酶活力,比S5单独发酵时全酶活、甘蔗渣纤维素酶活分别提高40.60%、14.21%。同时菌株S5与芽孢杆菌BZ5混合发酵也能提高其纤维素酶活力,比S5单独发酵时全酶活、甘蔗渣纤维素酶活分别提高6.23%、25.92%。【结论】筛选得到两株酶系较全且酶活较高的纤维素降解菌Z4、S5,适宜的混合发酵可明显提高纤维素降解能力,在海水养殖中有较大的应用前景。     

响应面法优化链霉菌S10A09发酵产纤维素酶条件

在筛选纤维素酶活菌株时,发现一株放线菌链霉菌属S10A09具有较高的纤维素酶活力。为了获得高酶活纤维素酶,将Plackett-Burman(PB)筛选和中心组合设计(CCD)以及响应面分析法相结合,考察影响链霉菌属S10A09发酵生产滤纸酶的发酵条件。Plackett-Burman结果表明,羧甲基纤维素钠(CMC-Na)和(NH_4)_2SO_4是影响S10A09发酵产纤维素酶活高低的主要因素。CCD实验优化后产酶最优发酵培养基(g/L)为CMC-Na 2.57、(NH_4)_2SO_411.31、KH_2PO_4 0.2、MgSO_41、FeSO_40.01。优化后,滤纸酶活(FPA)达到125.96 U/mL,接近优化前的3倍。     

高产纤维素酶枯草芽胞杆菌S-16的筛选及其发酵工艺优化

利用刚果红鉴别培养基及基础液体筛选培养基进行菌种筛选,从新疆盐碱地分离得到的16株菌株中筛选获得一株产纤维素酶活力较高的菌株S-16,对该菌株进行16SrDNA鉴定,确定该菌为枯草芽胞杆菌(Bacillus subtilis)。对S-16发酵产纤维素酶的主要影响因素进行研究,分别考察了碳源、氮源、培养基初始pH和接种量等因素对发酵产纤维素酶的影响。结合单因素影响实验得到优化后的培养基配方为:羧甲基纤维素钠1.5%,酵母粉1%,NaCl 1%,MgSO_4·7H_2O 2‰,KH_2PO_4·3H_2_O 1‰。优化后的发酵条件为:初始pH为8,接种量1%,种龄8h,培养时间48h。经过发酵工艺优化,S-16产生的羧甲基纤维素酶活(CMCase)和滤纸酶活(FPase)分别达到4.64IU/mL和0.46IU/mL,与初始培养条件下的酶活相比分别提高了3.14倍和1.30倍。本研究得到的枯草芽胞杆菌S-16及其优化发酵工艺为秸秆的快速腐熟和高产纤维素酶的应用奠定了基础。     

青霉F10-2固态发酵植物农药残渣产纤维素酶

采用单因素试验观察了不同C、N源、植物提取残渣与麦麸比例、初始pH和水料比对青霉F10-2菌株产纤维素酶的影响;在此基础上根据Box-w ilson的中心组合试验设计原理,选取蛋白胨、初始pH和水料比等影响因素,采用三因素五水平的响应面分析方法,对瓦克青霉F10-2的固态产纤维素酶条件进行了优化。其优化后的产酶条件为m(川楝树皮残渣)∶m(麦麸)∶m(蛋白胨)∶m(KH2PO4)=80∶20∶1.4∶0.4、初始pH 6.2、水料比2∶1、26℃发酵8 d,在此条件下纤维素酶比酶活可达6.47 U/g,较原始培养条件提高了46.38%。     

里氏木霉LW1固态发酵纤维素酶条件的研究

采用里氏木霉LW 1(Trichoderma.Reesei)固体发酵生产纤维素酶,研究了秸杆粉和麦麸用量、料水比、起始pH值、发酵温度和发酵时间对该菌株产纤维素酶活力的影响。试验结果表明,里氏木霉LW 1的适宜发酵条件为:在秸秆∶麦麸=1∶1,料水比为1∶2的前提条件下,培养温度28℃,发酵周期为72h,起始pH5.5时产酶活力最高。浸出液中FPA酶活为119.417u/g干物质,CMC酶活为452.433u/g干物质。     

产纤维素酶菌株的筛选、鉴定及产酶条件的优化

采集新疆吐鲁番地区土样,从中分离筛选1株产纤维素酶菌株C-8;经形态观察、生理生化及16S rRNA序列分析,初步鉴定为芽孢杆菌属(Bacillus sp.)。该菌株所产纤维素酶的最适合作用pH和温度分别为9.0、40℃,且具有良好的pH稳定性和温度稳定性。为了提高C-8菌株产纤维素酶能力,利用响应面法对其发酵产酶条件进行优化。采用Plackett-Burman设计筛选出影响其产酶条件的3个主效应因素,最陡爬坡试验逼近最大响应值区域,利用Box-Behnken响应面分析法优化发酵产酶条件。结果表明,起始pH、CMC-Na%和培养温度为主要影响因素。通过三因素三水平的响应面分析得到最优条件为起始pH8.0、CMCNa%2.5%、培养温度28℃。在此条件下纤维素酶活可达193.89 U/mL,与优化前相比,酶活提高2.35倍。     

稻草秸秆预处理方法对烟曲霉产纤维素酶的影响

采用机械粉碎、高温、酸碱处理等方法对稻草秸秆进行预处理,以烟曲霉为实验菌株,研究预处理方法对菌株产纤维素酶的影响。结果表明,取机械粉碎后的稻草（30~120目）进行121℃高压蒸汽处理20min（即灭菌处理）,有利于菌株的生长与纤维素酶的产生;与未粉碎的稻草秸秆相比,烟曲霉羧甲基纤维素钠（CMC）酶、微晶纤维素酶、β-葡萄糖苷酶和滤纸（FPA）酶的活力分别提高了63.2%、164.0%、10.2%和14.1%。而采用不同种类、不同浓度的酸碱常温处理稻草秸秆4d或100℃高温处理30min,纤维素酶活力均出现了不同程度的下降。     

Enzyme adsorption and recycling during hydrolysis of wheat straw lignocellulose

The objective of this research was to investigate cellulase adsorption and recycling during enzymatic hydrolysis of two differently pretreated wheat straws (WS). Dilute acid treated WS showed lower hydrolysis yield of polysaccharides fraction and adsorbed more cellulase with hydrolyzed residue than dilute alkali treated sample. Four methods capable of recovering and recycling the enzyme bound to the residual substrate and the enzyme free in solution were used for three consecutive rounds of hydrolysis to compare their recycling efficiencies. Compared to the absorption recycling method, ultrafiltration recycling method possessed the capacity to retain β-glucosidase, thereby avoiding the supplementation of fresh β-glucosidase in subsequent rounds of hydrolysis. It was found that whatever recycling method was used, better recycling results were obtained for dilute alkali treated substrate than for dilute acid treated substrate. These results suggested that the great difference in the lignin content between acid treated WS and alkali treated WS would significantly affect enzymatic hydrolysis, cellulase adsorption and cellulase recycling efficiencies.     

Cellulase production from immobilized growing cell composites prepared by radiation polymerization

The cellulase production from immobilized Trichoderma reesei composites prepared by radiation polymerization at low temperature was studied. The production of cellulase from the cells irradiated by radiation was slightly retarded at the initial stage of the culture, but was immediately recovered. The production of cellulase resulting from the growth of the immobilized cells proceeds efficiently in the composite having a porous polymer matrix, in which the productivity of cellulase varied with the hydrophilicity, the shape of the composite, monomer, and cell concentration. It was found that cellulase produced by immobilized growing cell composites effectively hydrolyzed cellulosic wastes such as newspaper and chaff which are pretreated by irradiation and crushing.     

Enhancement of the enzymatic digestibility of sugarcane bagasse by alkali–peracetic acid pretreatment

The enzymatic digestibility of sugarcane bagasse was greatly increased by alkali (NaOH)–peracetic acid (PAA) pretreatment under mild conditions. The effects of several factors affecting the pretreatment were investigated. It was found that when bagasse was pre-pretreated by 10% (based on initial dry materials) NaOH with 3:1 liquid-to-solid ratio at 90 °C for 1.5 h and further delignified by 10% peracetic acid (based on initial dry materials) at 75 °C for 2.5 h, the yield of reducing sugars reached 92.04% by enzymatic hydrolysis for 120 h with cellulase loading of 15 FPU/g solid. Compared with acid and alkali pretreatment, alkali–PAA pretreatment could be conducted under milder conditions and was more effective for delignification with less carbohydrates being degraded in the pretreatment process. Alkaline stage played an important role for partial delignification, swelling fibers and subsequently reducing PAA loading. No loss of cellulase activity (FPA) was observed in the liquid phase for alkali–PAA pretreated bagasse after enzymatic hydrolysis for 120 h.     

超临界CO2流体对纤维素酶催化反应的影响

超临界二氧化碳流体预处理对纤维素超分子结构及纤维素酶催化反应有重要影响。一定含水量的微晶纤维素用SC-CO2在10MPa,50℃处理30min,其结构发生了有利于进一步被酶解的变化。上述超临界条件单独作用于纤维素酶时,并未造成酶催化活力的降低;但与纤维素共同进行SC—CO2处理时,纤维素酶则失去催化活性,但这种处理却能提高纤维素进一步被酶解的效率。一定范围内处理时的酶用量与酶解效率的增加正相关。纤维素的含水量对SC-CO2处理后的酶解效率有显影响。     

The effect of microwave irradiation on enzymatic hydrolysis of rice straw

A series of experiments involving microwave irradiation were carried out to evaluate the effect of microwave irradiation on enzymatic hydrolysis of rice straw. Compared with microwave irradiation free hydrolysis, rice straw pretreated by combining microwave irradiation with alkali could increase the initial hydrolysis rate but the hydrolysis yield remained unchanged. When the enzyme solution was treated by microwave irradiation, the initial hydrolysis rate increased slightly, but the yield was decreased remarkably. Its optimal hydrolysis conditions were temperature (45 degrees C), pH (4.8) and enzyme loading (20 mg g(-1) substrate), which was determined by an orthogonal experiment. When intermittent microwave irradiation was used, initial hydrolysis rate was greatly accelerated but the yield was decreased slightly. Its optimal hydrolysis conditions were temperature (50 degrees C), pH (4.8) and enzyme loading (20 mg g(-1) substrate), which was determined by another orthogonal experiment.     

Enhanced cellulase production from Trichoderma reesei QM 9414 on physically treated wheat straw

Summary Trichoderma reesei QM 9414 was grown on wheat straw as the sole carbon source. The straw was pretreated by physical and chemical methods. The particle size of straw was less than 0.177 mm. Growth of T. reesei QM 9414 was maximal with alkali-pretreated straw whereas cellulase production was optimal when physically pretreated straw was used as substrate. Cellulase yields expressed as IU enzyme activity/g cellulose present in the cultures were considerably higher when alkali pretreatment of wheat straw was omitted. Cellulase yields of 666 IU/g cellulose for filter paper activity (FPA) are the highest described for cultures of T. reesei QM 9414 carried out in analogous conditions. Crystallinity index of the cellulose contained in wheat straw increased slightly after alkali pretreatment. This increase did not decrease cellulose accessibility to the fungus. Delignification of wheat straw was not necessary to achieve the best cellulase production.     

Low temperature alkali pretreatment for improving enzymatic digestibility of sweet sorghum bagasse for ethanol production

A low temperature alkali pretreatment method was proposed for improving the enzymatic hydrolysis efficiency of lignocellulosic biomass for ethanol production. The effects of the pretreatment on the composition, structure and enzymatic digestibility of sweet sorghum bagasse were investigated. The mechanisms involved in the digestibility improvement were discussed with regard to the major factors contributing to the biomass recalcitrance. The pretreatment caused slight glucan loss but significantly reduced the lignin and xylan contents of the bagasse. Changes in cellulose crystal structure occurred under certain treatment conditions. The pretreated bagasse exhibited greatly improved enzymatic digestibility, with 24-h glucan saccharification yield reaching as high as 98% using commercially available cellulase and β-glucosidase. The digestibility improvement was largely attributed to the disruption of the lignin-carbohydrate matrix. The bagasse from a brown midrib (BMR) mutant was more susceptible to the pretreatment than a non-BMR variety tested, and consequently gave higher efficiency of enzymatic hydrolysis.     

Microwave-assisted pretreatment of woody biomass with ammonium molybdate activated by H2O2

Pretreatments for enzymatic saccharification are crucial for the establishment of lignocellulosic biorefineries. In this study, we focused on ammonium ions and peroxometal complexes as potential delignifying agents. We first examined the pretreatment of beech wood with nine different ammonium salts in the presence of H₂O₂. Significant pretreatment effects were found only for ammonium molybdate, which is transformed to a peroxometal complex on reacting with H₂O₂. Since microwave sensitizer effects are expected for (peroxo)molybdate, beech wood was pretreated using external heating and microwave irradiation. As a result, a maximum sugar yield of 59.5% was obtained by microwave irradiation at 140 °C for 30 min, while external heating in an autoclave gave a sugar yield of 41.8%. We also found that an ammonium ion is the key counterion accelerating the pretreatment with molybdate. These results highlight the powerful selective delignifying capability of the H₂O₂-activated ammonium molybdate system energised by microwave radiation.     

Pretreatment of starch raw materials and their enzymatic hydrolysis by immobilized glucoamylase

The pretreatment of starch raw materials such as sweet potato, potato and cassava has been carried out using various types of crusher, viz juice mixer, homogenizer and high-speed planetary mill. The effect of pretreatment of the materials on their enzymatic hydrolysis was studied. High-speed planetary mill treatment was the most effective and comparable with heat treatment (pasting). Various crushing times were used to examine the effect of crushing by mill treatment on the enzymatic hydrolysis. In the enzymatic hydrolysis of cassava, the use of both cellulase [1,4-(1,3; 1,4)-β-d-glucan 4-glucanohydrolase, EC 3.2.1.4] and glucoamylase [1,4-α-d-glucan glucohydrolase, EC 3.2.1.3] enhanced the d-glucose yield. The immobilization of glucoamylase was studied by radiation polymerization of hydrophilic monomers at low temperature, and it was found that enzymatic activity of the immobilized glucoamylase particles varied with monomer concentration and particle size. Starchy raw materials pretreated with the mill can be efficiently hydrolysed by immobilized glucoamylase.