耐冷皮壳正青霉一种木聚糖酶的纯化与性质研究

研究了耐冷皮壳正青霉Eupenicillium crustaceum一种木聚糖酶的纯化和酶学性质。采用硫酸铵沉淀和阴离子交换层析的方法,从耐冷皮壳正青霉液体发酵液中分离纯化出一种亚基分子量35kDa的木聚糖酶。酶学性质研究表明,酶的最适pH值为5.5,在pH4.5-6.5范围内具有较高的催化活性。最适温度为50℃,20℃下酶活为最高酶活的40%。Ag+和Fe2+大幅度提高木聚糖酶的酶活,而Mn2+和Hg2+强烈抑制木聚糖酶的活性。同时,该木聚糖酶具有严格的底物特异性。     

运用定点突变提高重组木聚糖酶在毕赤氏酵母中的表达

运用PCR介导的定点突变对米曲霉(Aspergillus　oryzae)来源的木聚糖酶在毕赤酵母中的重组表达进行了研究,获得一表达量远远高于亲本的突变株I156A,对其进行了提纯并研究其酶学特性,除热稳定性外其余与亲本基本一致。突变株I156A所产木聚糖酶XynFl的分子量为35kD,在pH 4～9范围内稳定,最适pH为70,最适温度为45℃,在50℃以下稳定性略高于亲本。     

嗜热拟青霉固体发酵产木聚糖酶的纯化和性质

研究一株新的嗜热拟青霉J18的固体发酵产木聚糖酶的纯化和性质。固体发酵的粗酶液经硫酸铵沉淀、凝胶过滤层析和离子交换层析得到了一种分子量约为26 kDa的电泳纯木聚糖酶,酶活力回收率为33.5%,纯化了5.27倍。该木聚糖酶具有很好的温度和pH稳定性,在pH7.0~pH 9.0下,60℃处理24 h,酶活力能保存80%以上。该酶水解玉米芯木聚糖生成以木二糖、木三糖和木四糖为主的低聚木糖,薄层层析分析表明不含木糖,适合生产低聚木糖。     

信息库

1 米曲霉中的纤维素降解酶 日本清酒是由米曲霉和酿酒酵母用大米酿造的。米曲霉中的纤维素酶和木聚糖降解酶,松解稻米胚乳细胞壁,促进蒸煮米的消化和利用。本研究从米曲霉(Aspergillus oryzae)RIB128的固态培养中分离鉴定了四种纤维素降解酶。提纯了其中三种酶Cel-1,Cel-2和Cel-3,分子量分别为62,120和34kDa。它们的最适活性温度分别为50℃,50℃和60℃。最适pH分别为pH3.5,4.0和4.5;这三种酶分别在pH3.5～5.0,pH3.5～7.0和pH3.0～7.0是稳定的。根据N-端氨基酸序列分析,Cel-1和Cel-3分别相当于以前分离的内-1,4-β-葡聚糖酶[EC3.2.1.4]CelB和CelA。底物特异性分析表明,Cel-2可能是上种β-葡糖苷酶[EC 3.2.1.21]。Cel-1和Cel-2对稻米胚乳细胞壁的浸软活性较高,在清酒发酵中,能显著改善糖化醪中材料的利用。Cel-2的β-葡糖苷酶活性特别高,对酒精发酵,酒精产量和材料利用的作用更大。     

硫色曲霉木聚糖酶基因xynA的克隆、表达及酶学性质分析

目的:分析硫色曲霉产木聚糖酶的酶学性质。方法:利用RT-PCR克隆了硫色曲霉的木聚糖酶基因xynA,构建了该基因的原核表达载体,并获得了诱导表达。结果:纯化的木聚糖酶的最适催化温度为50℃,最适反应pH值为2.4,在30～50℃保温30min对酶活性没有大的影响。结论:木聚糖酶在低pH值下的催化活性使之在饲料工业中具有较好的应用前景。     

烟管菌漆酶的分离纯化及部分酶学性质研究

烟管菌Bjerkandera adusta WZFF．W-Y11漆酶粗酶液经过丙酮分级沉淀、DEAE-Cellulose离子交换层析、Sephadex G-100凝胶过滤,得到了三种电泳纯的漆酶同工酶,总酶活回收率达到65．5％,其中LacA平均纯化了29．2倍,LacB纯化了5．1倍,LacC纯化了18．5倍;三种同工酶的分子量分别为LacA：68．7kDa、LacB：80．2kDa、LacC：77．2kDa。LacA、LacC氧化愈创木酚的Km,大于氧化ABTS的Km,最适作用温度在45．70℃,最适反应pH3．0-5．5,65℃时LacC比LacA稳定,LacC在pH3．5—6．0稳定,LacA在pH5．0-9．0稳定,A1^3对LacA、LacC的酶活有促进作用,C1、Fe^3＋、Hg^2＋抑制LacA、LacC的酶活,Cu^2＋抑制LacC的酶活,而对LacA的活性没有明显影响。     

短小芽孢杆菌2080碱性蛋白酶的纯化与性质

短小芽孢杆菌（Bacillus pumilus）2080碱性蛋白酶的发酵液经超滤、硫酸铵沉淀、CM Sepharose Fast Flow和DEAE Sepharose Fast Flow离子交换层析得到了纯化的组分。SDS-PAGE电泳分析显示其分子量约为61kDa。酶学性质研究表明,该纯化酶的最适pH为10．5,最适温度为50℃。     

里氏木霉GXC木聚糖酶的研究

研究了里氏木霉GXC产木聚糖酶的条件和酶学性质。结果表明,适宜产酶碳源为乳糖、甘露糖、棉子糖、木聚糖和麸皮,氮源为牛肉膏和酵母膏;产酶的最适初始pH为4．0,30℃培养60h。对以麸皮为碳源的培养液进行纯化的酶特性研究表明,木聚糖酶的最适反应温度为50℃,pH为5．5,该酶在pH5．0－7．0和40℃以下相对稳定。Fe^2 和Mn^2 对木聚糖酶有较大的促进作用,Cu^2 、Fe^2 具有抑制作用。     

灰绿曲霉β-葡萄糖苷酶的分离及特性

目的：利用灰绿曲霉EU7-22发酵产纤维素酶,从中分离到β-葡萄糖苷酶,分析其理化特性,确定其最佳活性条件。方法：灰绿曲霉EU7-22发酵液离心后,上清液经硫酸铵沉淀、Phenyl 6 Fast Flow（highsub）疏水层析和Sephacryl S-200凝胶层析,获得纯化的β-葡萄糖苷酶。结果：纯酶的比活性为5.1 IU/mg,得率为13.89%。SDS-PAGE凝胶电泳分析表明该酶是单亚基蛋白,其分子量为56.2 kDa。在pH4.0~6.0范围内,β-葡萄糖苷酶具有较高的稳定性,该酶的最适酶促反应pH为5.0。当β-葡萄糖苷酶在温度低于60℃的缓冲液中温育1 h后,酶活损失不大,表现了较好的稳定性;当该酶在温度高于60℃的缓冲液中温育1 h后,酶活迅速丧失。β-葡萄糖苷酶在70℃时具有最大催化活性。结论：灰绿曲霉EU7-22发酵产生的β-葡萄糖苷酶具有较高活性,具有分子量较小、最佳催化温度较高的特点。     

Bacillus pumilus WL-11木聚糖酶A的纯化、鉴定及其底物降解方式

对一株BacilluspumilusWL_11木聚糖酶的纯化、酶学性质及其底物降解模式进行了研究。经过硫酸铵盐析、CM_Sephadex及SephadexG_75层析分离纯化,获得一种纯化的WL_11木聚糖酶A ,其分子量为2 6 0kD ,pI值9 5 ,以燕麦木聚糖为底物时的表观Km 值为16 6mg mL ,Vmax值为12 6 3μmol (min·mg)。木聚糖酶A的pH稳定范围为6 0至10 4 ,最适作用pH范围则在7 2至8 0之间,是耐碱性木聚糖酶;最适作用温度为4 5℃～5 5℃,在37℃、4 5℃以下时该酶热稳定性均较好;5 0℃保温时,该酶活力的半衰期大约为2h ,在超过5 0℃的环境下,该酶的热稳定较差,5 5℃和6 0℃时的酶活半衰期分别为35min和15min。WL_11木聚糖酶A对来源于燕麦、桦木和榉木的可溶性木聚糖的酶解结果发现,木聚糖酶A对几种不同来源的木聚糖的降解过程并不一致。采用HPLC法分析上述底物的降解产物生成过程发现木聚糖酶A为内切型木聚糖酶,不同底物的降解产物中都无单糖的积累,且三糖的积累量都较高;与禾本科的燕麦木聚糖底物降解不同的是,木聚糖酶A对硬木木聚糖降解形成的五糖的继续降解能力较强。采用TLC法分析了WL_11粗木聚糖酶降解燕麦木聚糖的过程,结果表明燕麦木聚糖能够被WL_11粗木聚糖酶降解生成系列木寡糖,未检出木糖,这说明WL_11主要合成内切型木聚     

绵毛嗜热丝孢菌木聚糖酶的纯化与性质

研究了绵毛嗜热丝孢菌Thermomyces lanuginosus W205胞外木聚糖酶的纯化与性质。粗酶液经硫酸铵沉淀和Q-Sepharose FF离子交换层析即可得到电泳纯木聚糖酶,回收率为46.6%,比酶活为1396.9U/mg。该酶的最适pH和最适温度分别为pH7.0和75℃,pH稳定范围为5.5-10.8,70℃处理30min残存酶活在70%以上。薄层层析结果显示该酶水解桦木木聚糖的主要产物是木二糖和木三糖,并且能够通过转糖苷作用将木三糖转化为木二糖。该木聚糖酶易于纯化并且具有较宽的pH稳定性及良好的热稳定性,具有较大的潜在工业应用价值。     

Effect of cultivation pH and agitation rate on growth and xylanase production by Aspergillus oryzae in spent sulphite liquor

The effects of cultivation pH and agitation rate on growth and extracellular xylanase production by Aspergillus oryzae NRRL 3485 were investigated in bioreactor cultures using spent sulphite liquor (SSL) and oats spelts xylan as respective carbon substrates. Xylanase production by this fungus was greatly affected by the culture pH, with pH 7.5 resulting in a high extracellular xylanase activity in the SSL-based medium as well as in a complex medium with xylan as carbon substrate. This effect, therefore, was not solely due to growth inhibition at the lower pH values by the acetic acid in the SSL. The xylanase activity in the SSL medium peaked at 199 U ml(-1) at pH 7.5 with a corresponding maximum specific growth rate of 0.39 h(-1). By contrast, the maximum extracellular beta-xylosidase activity pf 0.36 U ml(-1) was recorded at pH 4.0. Three low molecular weight xylanase isozymes were secreted at all pH values within the range of pH 4-8, whereas cellulase activity on both carbon substrates was negligible. Impeller tip velocities within the range of 1.56-3.12 m s(-1) had no marked effect, either on the xylanase activity, or on the maximum volumetric rate of xylanase production. These results also demonstrated that SSL constituted a suitable carbon feedstock as well as inducer for xylanase production in aerobic submerged culture by this strain of A. oryzae.     

短小芽胞杆菌产碱性木聚糖酶发酵条件的研究

碱性木聚糖酶在碱性条件下催化水解木聚糖,广泛应用于造纸、纺织等领域.着重对短小芽胞杆菌M-11产碱性木聚糖酶的发酵条件进行初步的探索.研究了菌株的生长曲线、确定最佳接种龄为16 h、最佳接种量为1％;确定最适碳源浓度为7％、最适单一氮源为氯化铵、其浓度为1.0％、最适无机盐为氯化铁、其浓度为3 mmol/L;在此基础之上进行6因素3水平的正交试验,确定最适产酶培养基组成:麸皮5％,接种量3％,氯化铵1.2％,氯化铁3.5 mmol/L,硫酸镁0.03％,氯化钠5 mmol/L,磷酸氢二钾0.4％;最适培养条件:接种龄16 h,初始pH 8.0,温度37℃,300 mL摇瓶装液量50 mL,摇床转速220 r/min,发酵周期48 h.通过对发酵条件的优化使发酵液酶活达613 IU/mL.无机氮源为其最适氮源,因此短小芽胞杆菌M-11在碱性木聚糖酶的产品开发上优于短小芽胞杆菌M -26.     

Optimization of ellagic acid production from ellagitannins by co-culture and correlation between its yield and activities of relevant enzymes

Aspergillus oryzae was co-cultured with Trichoderma reesei using acorn cups extract containing up to 62% ellagitannins as substrate to produce ellagic acid with relatively high levels of ellagitannin acyl hydrolase, cellulase and xylanase. Ellagitannins concentration, initial pH, T. reesei and A. oryzae during the fermentation were identified as important process parameters effecting ellagic acid accumulation and the enzymes syntheses. These parameters were optimized by uniformity design to determine the optimum condition for ellagic acid production. Under optimum operational condition, ellagic acid yield could be arrived at 24%, when the fermentation run lasted 96h with an initial pH of 4.5, an ellagitannins concentration of 4gl(-1), T. reesei of 3ml and A. oryzae of 3ml. Meanwhile, it was found that the three enzymes activities correlated very well with ellagic acid yield, resulting in model with high coefficient of determination (R(2)=0.98). The results indicate that the mixed culture of T. reesei and A. oryzae is an effective approach to produce an enzyme system of degrading ellagitannins for ellagic acid production.     

三相流化床中固定化米根霉萃取发酵生产L-乳酸

以TRPO／磺化煤油为萃取剂,在2L三相流床反应器中进行了固定化米根霉原位萃取和异位萃取发酵生产L-乳酸的实验,结果表明,发酵液中的pH值能被控制在3．5左右．产酸速率高达每小时．每1L固定化颗粒产生11gL-乳酸。提出了一个数学模型用以描述萃取发酵中L-乳酸的积累及在各相的分配情况。模型计算曲线与实验值符合良好。     

微白黄链霉菌G-1发酵液抗真菌特性研究和发酵条件优化

为明确微白黄链霉菌(Streptomyces albidoflavus)G-1发酵液抗真菌特性和较优发酵条件,本研究采用平板对峙法、生长速率法、单因素试验、RDA分析和响应面CCD设计分别对其抗真菌特性、产抗菌物质关键限制因子和发酵条件较优组合进行了探究。结果表明:S.albidoflavus G-1发酵液对马铃薯早疫病菌、西瓜枯萎病菌、小麦赤霉病菌、辣椒枯萎病菌、黄瓜疫霉病菌和桃褐腐病菌具有较好抑菌效果,抑菌率均可达70%;发酵液在≤80℃、紫外照射24 h、pH 3-13和稀释100倍条件下仍可保持70%以上抑菌率;产抗菌物质关键限制因子为初始pH值、温度、麦芽糖和马铃薯;较优发酵条件为8%麦芽糖、马铃薯16.5%、初始pH 6.5、温度30℃、转速160 r/min、发酵5 d,且在该条件下可使抑菌率提高14.46%。说明菌株G-1发酵液具有良好的抑真菌稳定性,且优化后的发酵条件可使菌株G-1在较低成本和较短时间内产生大量抗菌物质,研究结果为其后期田间应用和规模化发酵奠定了理论基础。     

木聚糖酶生产菌株的筛选及产酶条件的优化

以甘蔗渣半纤维素为碳源,从垃圾场土壤中分离到6株分解半纤维素的菌株。通过固态发酵的木聚糖酶活力比较筛选到1株木聚糖酶活力较高的菌株。该菌株18S rDNA序列与曲霉（Aspergillus sp.）的同源性达97%,根据对菌株形态学分析和18S rDNA序列分析的结果,将该菌株鉴定为曲霉HQ3。HQ3的最佳产酶条件为：甘蔗渣:麸皮为7:3（W/W）,固液比为1:4（W/W）,尿素0.4 %,pH7.0,温度30℃,发酵产酶时间4 d。在最佳产酶条件下,其木聚糖酶活最高可达3421U/g干曲。     

土壤拮抗放线菌的分离筛选及其抑菌物质特性的研究

目的从土壤中筛选拮抗能力强且抑菌特性稳定的放线菌菌株。方法采用双层琼脂法筛选出4株拮抗放线菌菌株,然后采用杯碟法测这4株菌株发酵液提取物的抗菌谱、最小抑菌浓度、热稳定性和酸碱稳定性。结果 4株菌株发酵液提取物都能抑制金黄色葡萄球菌、大肠埃希菌、铜绿假单胞菌和白色念珠菌的生长。以金黄色葡萄球菌为指示菌测发酵液提取物的最小抑制浓度,6#和9#拮抗作用较强,发酵液提取物稀释0.125mg/ml仍有抑菌作用。6#菌株在100℃处理30min后仍有40%的抑菌活性。6#菌株发酵液提取物在碱性环境条件下比在酸性环境条件下稳定。结论 4株菌株中6#菌株发酵液提取物具有拮抗能力强、最小抑菌浓度低和在碱性条件下活性较稳定的特点。     

Cloning and enzymatic characterization of a xylanase gene from a soil-derived metagenomic library with an efficient approach

Screening interesting biocatalysts directly from soil samples is a more convenient and applicable approach than conventional cultivation-dependent ones. In our present work, a soil-derived metagenomic library containing 24,000 transformants was constructed with an efficient strategy for cloning xylanase genes. A gene encoding the enzyme (XynH) able to hydrolyze xylan was obtained. Similarity analysis revealed that this enzyme is a new member in the family 10 of xylanases. The molecular mass of XynH purified from Escherichia coli was estimated to be 39 kDa by sodium dodecyl sulfate polyacrylamide gel electrophoresis analysis. It was found to display the maximal activity at lower temperature, under weakly alkaline conditions, different from most of xylanases. The K _m and V_max values of XynH with birchwood xylan as substrate are 7.5 mg/ml and 190 μmol min⁻¹ mg⁻¹, respectively. It is greatly interesting to note that the activity of XynH was not reduced significantly by Mn²⁺, Zn²⁺, Co²⁺, Ag⁺, and Cu²⁺, even at the concentration of 5 mM, which strongly inhibits most of the other xylanases studied previously. Yong Hu and Guimin Zhang contributed equally to this work.     

赤霉素A_4、A_7的发酵研究

初选藤仓赤霉菌(Gibberella fujikuroi)农大17菌株为赤霉素A_4、A_7(GA_4、GA_7)的生产菌,该菌株GA_(4+7)的积累量,除与营养条件有关外,温度和pH是极为重要的因子,随着发酵温度从28℃上升至32℃,GA_(4+7)的产量由21μg/ml增至81μg/ml,GA_3由702μg/ml降至328μg/ml。pH回调至中性,GA_(4+7)的产量由75μg/ml增至180μg/ml,GA_3由322μg/ml降至211μg/ml。此外,设法延长发酵周期也是增加GA_(4+7)的一个因素。综合上述条件,即发酵过程中,发酵液的pH由48h前的4回调并维持在6.7左右,温度由28℃上调并控制在32℃,摇瓶培养12天,GA_(4+7)的产量达890μg/ml,20—600L发酵罐发酵240h,GA_(4+7)产量达680μg/ml左右。GA_(4+7)浓度的测定亦作了简化处理,发酵液不经提取,可直接用硅胶板G薄层层析(TLC)后进行荧光比色,产品测定宜采用高效液相色谱法(HPLC)。按照上述条件培养的农大17菌株,产生GA_3、GA_7和GA_4的比例为23.131:16.105:31.258,GA_4高于有关报道。