甘蔗渣固态发酵产纤维素酶

以甘蔗渣和麸皮混合作为固态发酵产酶培养基,采用单因素优化实验对里氏木霉固态发酵产纤维素酶进行优化。结果表明,在50 m L体系培养基中,在底物绝干原料5.2 g、甘蔗渣与麸皮质量比7∶3、氮源((NH4)2SO4)7.5 g/L、产酶诱导物1.6 g/L、表面活性剂(聚乙二醇PEG6000)0.1 g、发酵起始p H 4.4、培养基中里氏木霉孢子接入量5×105个的条件下,温度30℃时发酵120 h,里氏木霉固态发酵产纤维素酶的酶活达76.39 IU/g,是起始优化前20.29 IU/g的3.76倍。     

海洋真菌岩藻多糖酶的固态发酵条件研究*

本文对海洋真菌Dendryphiella arenaria(TM94)岩藻多糖酶的固态发酵条件进行了研究,主要内容包括碳源、氮源、添加物、起始pH、接种量及温度等.固态发酵最佳培养基组成麸皮7.5g,葡萄糖0.5g,海带粉0.6g,NaNO3为4g/L最佳培养条件为培养温度28℃,起始pH6,接种量3ml(孢子浓度为106个/ml).在28℃培养24h,酶活力可达35.5IU/g干培养基,比活力为1.39IU/mg蛋白质.对岩藻多糖酶酶学性质也进行了研究.     

粗糙脉孢菌(Neurospora crassa)纤维素酶液体发酵培养基的优化

粗糙脉孢菌是天然纤维素降解真菌,具有产纤维素酶能力,国内外对其纤维素降解机理和发酵产酶有一定的研究,但对其产酶的条件优化研究得不多,其产酶潜力需要进一步挖掘。以粗糙脉孢菌基因组测序菌株FGSC 2489为对象,采用响应面分析法对Neurospora crassa摇瓶发酵产纤维素酶进行培养基优化。采用Plackett-Burman(PB)实验设计考察发酵培养基中关键参数对产酶条件的影响,进而采用最陡爬坡实验逼近最大响应区域,并结合中心组合实验(central composite design,CCD)和响应面分析法对两个显著因素进行分析。PB实验结果显示:Peptone、Yeast extract对产纤维素酶有显著影响。通过响应面分析得到一元二次方程,对方程求解得到Peptone 7.27g/L、Yeast extract 5.51g/L。采用该优化培养基,最大纤维素酶活可达1.27FPU/ml,较优化前提高了2.03倍;CMC酶活14.15IU/ml,比优化前提高1.88倍;木聚糖酶活24.13IU/ml,比优化前提高1.86倍;葡萄糖苷酶酶活1.22IU/ml比优化前提高2.08倍。     

青霉PT95菌株固态发酵产生类胡萝卜素的研究

本文对青霉Penicillium sp. PT95菌株在固态发酵条件下菌核内产生类胡萝卜素进行了初步研究。结果表明,在3种固态发酵培养基中,玉米粉培养基(SMA)比麸皮培养基和棉籽壳培养基更适合于PT95菌株固态发酵产生类胡萝卜素。为了增加菌核干重和提高类胡萝卜素产率,SMA中需要添加氮源、碳源和植物油。在所试的各种氮、碳源中,以硝酸钠和麦芽糖效果最佳。通过正交试验确定了在培养基盐溶液中添加硝酸钠3g/L,麦芽糖10g/L,豆油2.5g/L能使菌核干重由536g/100g提高到970g/100g(干料);类胡萝卜素产率由2149μg/100g提高到5260μg/100g(干料);β-胡萝卜素在类胡萝卜素中的含量由614%提高到71.3%。     

地衣芽孢杆菌固态发酵麻疯树饼粕产蛋白酶及其酶学性质

利用地衣芽孢杆菌作为出发菌株,以提油后的麻疯树饼粕作为培养基,采用固态发酵方式生产蛋白酶。控制培养基湿度为125%,添加10%的乳糖和5%的蛋白胨,30°C条件下发酵3d,蛋白酶产量达到最大值(7465U/g)。酶学性质研究表明,蛋白酶最适作用pH为5?6,最适催化温度为55°C,最大催化速度Vmax为0.0324μmol/(s·mg),Km值为0.0531mmol/L。有机溶剂对酶活力有明显促进作用,10%(V/V)甲醇和5%(V/V)乙醇可以使酶活力分别提高13.55%和70.9%。Mg2+可以使蛋白酶活力提高42.54%,而Hg2+却使酶彻底失活。     

拟康氏木霉(Trichoderma psudodoningii)UV III产纤维素酶液体发酵研究

以拟康氏木霉(Trichoderma psudodoningii)TH为出发菌株,经紫外诱变荻得一抗高浓度葡萄糖阻遏突变株uV III,其液体发酵最适产酶培养基为(w/V)豆皮粉3%,硝酸铵0.6%,磷酸二氢钠0.65%,硫酸镁0.25%,氯化钙0.15%,pH5.0;最佳发酵条件为30℃,125r/min发酵7d CMCase活力可达103.55 IU/mL,滤纸酶活可达5.51 IU/mL,β一葡萄糖苷酶活可达0 96IU/mL,分别比出发菌株TH提高了1.40、2.34、0.60倍.     

黑曲霉产木聚糖酶固态发酵条件及部分酶学性质的研究

实验以棉粕和玉米秆为主要原料,采用单因素和正交实验方法对黑曲霉固态发酵产木聚糖酶的培养条件进行了优化,为了获得高酶活产品的发酵条件。结果表明,最适培养基组分为棉粕和玉米秆的比例为3∶2,固水比为1∶1.2,尿素的最适添加量为2%(以干重计),KH2PO4的最适添加量为0.2%。在此条件下,菌株产酶活性可达6 529U/g干曲。该酶的最适反应温度为55℃,最适pH为5.0,pH稳定范围较宽,在30℃、pH 3.5~6.0范围内处理100min,酶活保持在85%以上,但耐热性不是很理想,在60℃保温30min残余酶活只有17%。     

里氏木霉与米根霉混合固态发酵产纤维素酶

以里氏木霉及米根霉单菌固态发酵为对象,考察不同混合发酵形式对里氏木霉与米根霉混合固态发酵产纤维素酶的影响。结果表明:同时接种里氏木霉与米根霉,试验考察的两菌种接种量比1∶1(以孢子个数计)及5∶1条件下,两菌未产生明显协同产酶作用。米根霉延时(24 h)接种且菌种量比5∶1以及米根霉延时(48 h)接种且菌种量比1∶1,2种发酵形式产酶情况类似,滤纸酶活(FPA)及羧甲基纤维素酶(CMCase)酶活相对米根霉单菌发酵有所提高,而β-葡萄糖苷酶(β-GA)酶活相对里氏木霉单菌固态发酵结束时分别增加4.66及4.40倍,可以发现两菌产生一定协同作用。在米根霉延时(48 h)接种且菌种量比5∶1的发酵形式下,FPA及CMCase在发酵第7天酶活分别达到44.04 IU/g、627.14 U/g(以1 g干曲计),分别是里氏木霉固态单菌发酵产酶达到稳定期时酶活的1.36和1.63倍,两菌产生了有效的协同作用。     

利用黑曲霉固态发酵啤酒糟生产饲料复合酶的研究

以啤酒糟为主要基质,利用黑曲霉固态发酵生产酸性蛋白酶、木聚糖酶和纤维素酶等多种饲料复合酶,研究了黑曲霉固态发酵培养基组成对复合酶酶活的影响,确定最优培养基配方为:啤酒糟75%,麸皮25%,硫酸铵1%,KH_2PO_4 0.2%,MnSO_4 0.1%、ZnSO_4 0.2%,料水比1:2。在适宜的发酵条件下,经30℃发酵5 d,烘干后得到的复合酶制剂中,具有多种酶活性(以干基计)。其中酸性蛋白酶活力3 800 U/g,木聚糖酶活力12 00 U/g和纤维素酶活力18 U/g。     

高产碱性果胶酶菌株的育种及其发酵条件的研究

以克劳氏芽孢杆茵(Bacillus clausii)S-4为出发菌株,经紫外诱变育种和固态发酵条件的选育,得到产碱性果胶酶较高的新茵株N-10,并研究了其固态发酵条件和部分酶学性质.结果表明,以甜菜渣为碳源和酶的诱导物以及棉粕作为氮源较适宜.较优的固态发酵条件为:甜菜渣5g,棉粕0.125 g,麦芽糖0.1 g,KH2PO40.0075 g,Na2CO30.15 g,水12.5 mL,种龄24 h,接种量2mL,发酵温度40℃,发酵时间84 h;酶产率可达4780 u/g(干甜菜渣),较菌株S-4提高108%.该酶的最适pH 10,最适温度55℃;分别在pH 7.5～9.5和30～40℃范围内较稳定;Ca2 、Mg2 、Fe2 对酶活有明显激活作用,Cu2 、Zn2 对酶活有强烈抑制活作用.     

Xylanase production in solid state fermentation by Aspergillus niger mutant using statistical experimental designs

The initial moisture content, cultivation time, inoculum size and concentration of basal medium were optimized in solid state fermentation (SSF) for the production of xylanase by an Aspergillus niger mutant using statistical experimental designs. The cultivation time and concentration of basal medium were the most important factors affecting xylanase activity. An inoculum size of 5 x 10(5) spores/g, initial moisture content of 65%, cultivation time of 5 days and 10 times concentration of basal medium containing 50 times concentration of corn steep liquor were optimum for xylanase production in SSF. Under the optimized conditions, the activity and productivity of xylanase obtained after 5 days of fermentation were 5,071 IU/g of rice straw and 14,790 IU l(-1) h(-1), respectively. The xylanase activity predicted by a polynomial model was 5,484 IU/g of rice straw.     

Rhizopus delemar菌固态发酵生物量测定及其脂肪酶合成特征

研究了Rhizopus delemar菌固态发酵曲中麦角固醇的提取及其高效液相色谱（HPLC）测定方法。结果表明,固态曲中麦角固醇分离提取以1：25（w/v)的丙酮回流浸提2.0h为最佳,HPLC测定麦角固醇的条件为：HypersilC-8柱。甲醇/水（85/15,v/v)为流动相,流速为1.0mL/min,紫外检测波长为282nm。柱温为30℃。依据HPLC的分析测定,确定了麦角固醇与菌丝体间的定量关系,并以此为基础。测定了Rhizopus delemar菌固态发酵过程中的生物量变化。得到了生长曲线,发现当发酵培养至60h时固态曲中的生物量达到最大值为0.18g菌丝体/g干曲,而该菌所合成的脂肪酶的活力在48h达到最大值。     

Statistical optimization of medium components for the production of xylanase byAspergillus niger KK2 in submerged cultivation

Medium composition was optimized for the production of xylanase byAspergillus niger KK2 using statistical experimental designs. Corn steep liquor (CSL) and industrial yeast extract (IYE) were the most important factors affecting xylanase activity. The medium that produced the optimum conditions for the production of xylanase contained 3% rice straw, 1% wheat bran, 6.3% CSL, 0.15% IYE, and 0.5% KH₂PO₄. After 4 days of cultivation under optimized conditions in a 2.5-L stirred tank reactor the activity and productivity of xylanase were 620 IU/mL and 6,458 IU/L.h, respectively. The highest xylanase activity obtained using the optimized medium was 80% greater than the activity obtained using basal medium. The xylanase activity predicted by a polynomial model was 670 IU/ml.     

Optimization of Non-Nutritional Factors for a Cost-Effective Enhancement of Nisin Production Using Orthogonal Array Method

In order to increase nisin production in a cost-effective manner, non-nutritional factors as well as nutritional parameters must be optimized. In this study, optimization of the most important non-nutritional factors for nisin production using orthogonal array method was performed. Optimization of temperature, agitation, age and size of inoculum, medium initial pH value and flask volume/medium volume ratio in de Man, Rogosa and Sharpe (MRS) medium in batch fermentation was accomplished. Nisin was produced by Lactococcus lactis subsp. lactis PTCC 1336 and measured by bioassay method using Micrococcus luteus PTCC 1169 as the nisin-sensitive strain. The optimum levels of non-nutritional factors for maximum nisin production and productivity were obtained as: flask volume/medium volume ratio: 5.00, medium initial pH value: 8.00, inoculum size: 1%, inoculum age: 24 h old (A = 1.7), agitation: 100 rpm and temperature: 27 °C. Under the optimized conditions, maximum nisin production and maximum nisin productivity were 599.70 IU/mL and 37.48 IU/mL/h, respectively.     

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。     

产环己酰亚胺菌株YIM41004T发酵条件的研究

以产环已酰亚胺菌株链霉菌(Streptomyces yunnanensis)YIM41004T为研究对象,对其发酵培养基和发酵条件进行了优化研究,得到的最佳培养基组成为葡萄糖6%,大豆粉1%,硫酸铵0.5%,蛋白胨0.2%,碳酸钙0.6%,硫酸镁0.05%,磷酸二氢钾O.02%;优化后的培养条件为以4%接种量接种至500mL三角瓶中,装液量为75 mL,初始pH值6.5,发酵温度为28℃,摇床培养96 h.优化后环己酰亚胺产量平均达到445.19 ug/mL,比初始的环己酰亚胺产量提高了422%(p＜0.01).     

黑曲霉与里氏木霉固态混合发酵产β-葡萄糖苷酶

对黑曲霉NL02与里氏木霉RUT-C30固态混合发酵产β-葡萄糖苷酶的发酵培养基进行优化,研究培养基含水率、C源、N源、接种量、温度和2种菌种不同延长接种时间与接种比例对β-葡萄糖苷酶活力的影响。研究表明：麸皮17.5 g、玉米芯7.5 g、（NH4）2SO4 0.40 g、尿素0.37 g、黑曲霉孢子接入量为107个接种到250 mL三角瓶中,温度30 ℃、摇床转速100 r/min时,里氏木霉以105个孢子与黑曲霉同时接入,每克干曲所得β-葡萄糖苷酶的活力为132.45 IU,较黑曲霉单独培养时的104.35 IU提高了26.94%。     

出芽短梗霉产聚苹果酸发酵条件的优化

【背景】出芽短梗霉可发酵葡萄糖生成聚苹果酸,但存在转化率和转化效率低等瓶颈,阻碍其实现商业化生产。【目的】通过优化发酵培养条件,提高出芽短梗霉的聚苹果酸产量、糖酸转化率和生产强度。【方法】采用单因素试验优化适宜出芽短梗霉BK-10菌株产生聚苹果酸的培养条件,通过Plackett-Burman法对培养基组分筛选显著性影响因素,并对其培养基中无机盐进行正交试验优化,最后进行5 L发酵罐验证。【结果】最优培养基配方和培养条件:100 g/L葡萄糖,1.5 g/L尿素,0.20 g/L KH_2PO_4,0.20 g/L ZnSO_4,0.05 g/L MgSO_4,0.75 g/L KCl,30 g/L CaCO_3,0.01%吐温-80,发酵温度26°C,250 mL摇瓶装液量50 mL。【结论】通过优化,聚苹果酸的糖酸转化率达到0.71 g/g,生产强度达到0.89 g/(L·h),较优化前分别提高了18.33%和71.15%,为发酵葡萄糖合成聚苹果酸进而生产L-苹果酸工艺的工业化生产奠定经济性基础。     

赭曲霉的高密度培养对坎利酮转化的影响

目的:研究赭曲霉高密度培养的发酵培养基及条件,实现坎利酮的高转化.方法:选取廉价易得的培养基成分并进行优化,同时对发酵条件进行优化,得到了最优发酵培养基配方及培养条件.结果:发酵培养基最优配方为:葡萄糖20g/L,玉米浆20g/L,酵母膏20g/L,K2HPO4 2.5g/L.种子液最佳培养时间为24h,发酵培养基初始pH 5.8,接种量为8%,装液量200mL/1000mL,摇床转速为180 r/min,28℃,底物投料时间24h,发酵结束时间72 h.结论:将该工艺在7L发酵罐中放大,菌体密度达到25.36g/L,11α羟基坎利酮的转化率为86.1%.     

Response surface optimization of fermentation conditions for producing xylanase by <Emphasis Type="Italic">Aspergillus</Emphasis><Emphasis Type="Italic">niger</Emphasis> SL-05

Fermentation conditions were statistically optimized for producing extracellular xylanase by Aspergillus niger SL-05 using apple pomace and cotton seed meal. The primary study shows that culture medium with a 1:1 ratio of apple pomace and cotton seed meal (carbon and nitrogen sources) yielded maximal xylanase activity. Three significant factors influencing xylanase production were identified as urea, KH(2)PO(4), and initial moisture content using Plackett-Burman design study. The effects of these three factors were further investigated using a design of rotation-regression-orthogonal combination. The optimized conditions by response surface analysis were 2.5% Urea, 0.09% KH(2)PO(4), and 62% initial moisture content. The analysis of variance indicated that the established model was significant (P < 0.05), "while" or "and" the lack of fit was not significant. Under the optimized conditions, the model predicted 4,998 IU/g dry content, whereas validation experiments produced an enzymatic activity of xylanase at 5,662 IU/g dry content after 60 h fermentation. This study innovatively developed a fermentation medium and process to utilize inexpensive agro-industrial wastes to produce a high yield of xylanase.