CpG基序重组菌发酵培养基的优化

目的:为提高CpG基序重组菌的发酵水平,降低CpG重组质粒的生产成本,运用响应面法优化CpG重组菌发酵培养基。方法:利用Plackett-Burman试验筛选出影响发酵水平的3个最显著因素:糖蜜、玉米浆和工业蛋白胨。然后用响应面设计试验并优化得到最显著因素的最佳浓度,并进一步通过发酵试验验证优化后的培养基。结果:得到一组具有较高菌浓及质粒产量且价格低廉的发酵用培养基:糖蜜4.5g/L,玉米浆8.5g/L,工业蛋白胨8.5g/L,甘油10mL/L,KH2PO41.5g/L,K2HPO42.3g/L,MgSO4.7H2O 0.25g/L,在此培养条件下,OD600实测值为0.6771,理论值为0.6643,两者接近,与标准LB培养基相比,质粒产量提高了15%左右。结论:最终筛选到的培养基具有较高的性价比。     

重组谷氨酸棒杆菌发酵L-苯丙氨酸培养基的优化

【目的】提高重组谷氨酸棒杆菌发酵L-苯丙氨酸(L-phenylalanine,L-Phe)的产量。【方法】使用正交试验设计以及响应面优化法分别对种子培养基及发酵培养基进行优化,确定了重组谷氨酸棒杆菌发酵L-Phe的最佳种子培养基及最佳发酵培养基。【结果】重组谷氨酸棒杆菌发酵L-Phe最佳种子培养基(g/L):葡萄糖25.0,玉米浆25.0,硫酸铵15.0,硫酸镁1.0,磷酸二氢钾2.0,尿素2.0,p H 6.8-7.0;最佳发酵培养基(g/L):葡萄糖110.0,玉米浆7.0,硫酸铵25.0,硫酸镁1.0,磷酸二氢钾1.0,柠檬酸钠2.0,谷氨酸1.0,碳酸钙25.0,p H 6.8-7.0;在最佳培养基条件下L-Phe产量最高达到9.14 g/L,较优化前的7.46 g/L提高了22.5%。【结论】通过正交试验和响应面分析对重组谷氨酸棒杆菌发酵L-Phe培养基进行优化,明显提高了L-Phe的产量,并确定了葡萄糖、玉米浆和硫酸铵为发酵培养基中影响L-Phe产量的3个关键因子。研究结果为L-Phe的发酵放大提供了依据。     

Optimization of fermentation medium for amidase production by response surface methodology

采用响应面分析方法,对阿萨希丝孢酵母(Trichosporon asahii)ZZB-1产酰胺酶的发酵培养基进行了优化.运用单因子试验筛选出麦芽糖和酵母浸膏为最适碳源、氮源,金属离子Ca2+、Mn2+可提高发酵酰胺酶产量;通过最陡爬坡实验逼近以上4个因子的最大响应区域后,采用Box-Behnken响应面分析法,确定产酰胺酶最佳发酵培养基为麦芽糖18.84 g/L、酵母浸膏9.55 g/L、NaCl 5g/L、KH2 PO41g/L、MgSO4·7H2O 0.2 g/L、FeSO40.001g/L、CaCO370.84 μmol/L、MnSO4 65.39 μmol/L(1％丙烯酸诱导),NH4·H2O调节pH至7.0.培养基优化后酰胺酶产量由初始2554U/L提高到4156 U/L,为原始发酵培养基配方酶活产量的1.63倍.     

营养因子对苏云金芽胞杆菌4.0718 产杀虫蛋白Cry1和Cry2的影响

为了提高杀虫蛋白Cry1和Cry2产量,首先采用Plackett-Burman设计筛选出发酵培养基中影响苏云金芽胞杆菌4.0718表达毒蛋白Cry1的显著性因子为黄豆饼粉和MnSO4·H2O,Cry2的产量在该配方中无显著性影响因子.然后利用最速上升实验逼近Cry1最大产出区域,找到后续试验中心点.最后通过响应面优化得到黄豆饼粉和MnSO4·H2O的最佳浓度为11.5 g/L和0.02 g/L,使Cry1和Cry2产量分别达到0.32 mg/mL和0.11 mg/mL,比原优选配方产量提高了两倍多.该优化配方发酵液对棉铃虫的半致死浓度(LC50)为1.09 μL/mL,杀虫活性比原优化配方显著提高.     

响应面法优化L-谷氨酰胺发酵培养基的研究

目的:采用响应面法对L-谷氨酰胺发酵培养基成分进行优化,以提高L-谷氨酰胺发酵产量。方法:首先利用Plackett-Burman试验设计筛选出影响L-谷氨酰胺产量的主要因素葡萄糖、玉米浆和(NH4)2SO4,在此基础上采用最陡爬坡实验逼近最大响应区域,并利用中心组合设计及响应面分析法进行回归分析。结果:通过求解回归方程得到L-谷氨酰胺发酵培养基最佳浓度为葡萄糖100 g/L、玉米浆4.5 ml/L、(NH4)2SO437.2 g/L,L-谷氨酰胺产量理论最大值达41.0 g/L。结论:经模型验证,预测值与验证试验平均值接近,在优化条件下谷氨酰胺产量提高了37.6%。     

响应面法优化杀鱼假交替单胞菌2515发酵培养基

杀鱼假交替单胞菌(Pseudoalteromonas piscicida)2515是一株具有广谱抗弧菌性能的菌株，为提升菌株2515的培养生物量，通过单因素优化方法，研究碳源、氮源、无机盐等营养成分对菌株2515的发酵产量的影响，确定关键营养因子，利用响应面分析法对影响菌株2515生物量的关键营养因子进行优化。结果显示，菌株2515的最佳发酵培养基配方为麦芽糖2.85 g/L、CaCl₂ 0.65 g/L、MnCl₂ 0.10 g/L、酵母膏3.85 g/L、胰蛋白胨10 g/L、NaCl 10 g/L。优化后的培养基使菌株2515在锥形瓶和发酵罐中发酵的OD₆₀₀值分别为1.416和1.866,生物量分别提高了36.4%和40.4%,其发酵上清液和细胞内容物的抑菌活性分别提高了28.2%和27.2%。表明响应面法优化后的培养基有利于提高菌株2515的发酵生物量及抗菌效果，研究结果为菌株2515的后续开发应用提供了参考。     

高效杀蚊苏云金芽孢杆菌BRC-LLP29的发酵优化

苏云金芽孢杆菌BRC-LLP29为新型高效杀蚊菌株,应用快速有效的数学统计方法对其杀蚊毒力的发酵培养进行优化.通过单因素筛选确定最佳碳源为葡萄糖、麦芽糖、可溶性淀粉,氮源为typetone、大豆蛋白胨、干酪素;最佳金属离子为Mg²⁺、Al³⁺.采用二水平Placlkett-Burman设计对影响毒力的8因素进行显著性筛选,获得培养基成分中3个重要影响因子:葡萄糖、干酪素和Al₂（SO₄）₃;运用爬坡路径法对这3种因子进行试验,获得3种重要因子的最适浓度范围;通过响应面分析法得到3个重要因子的交互作用和最佳条件,确定BRC-LLP29菌株最佳毒力水平的发酵培养基为:葡萄糖19.8g/L、干酪素28.4g/L、Al₂（SO₄）₃1.2g/L、MgSO₄ 2g/L、K₂HPO₄ 3g/L、CaCO₃ 0.5g/L,优化后毒力水平达到致死率61.11%,与响应面数学模型的预测值只有5.91%的误差.发酵条件优化结果表明:发酵温度为31°,发酵初始pH为7.0,摇瓶装量为40mL/250mL三角瓶,每瓶的接种量为3.5%,发酵72h,对致倦库蚊最终致死率达到最高为83.33%.     

响应面法优化多杀菌素发酵培养基的研究

采用响应面分析方法,对刺糖多孢茵（Saccharopolyspora spinosa）H-2产多杀菌素的发酵培养基进行优化研究。运用单因子试验筛选出葡萄糖和棉籽粉为最适碳源和氮源,通过Plack—ett—Burman设计试验,对影响发酵培养基的8个相关因子进行评估并筛选出具有显著效应的4个因子：葡萄糖、棉籽粉、黄豆饼粉及玉米浆。通过最陡爬坡实验逼近以上4个因子的最大响应区域后,采用Box-Behnken响应面分析法,确定发酵产多杀菌素最佳培养基为葡萄糖64．5g,麦芽糖20g,玉米浆2g,大豆油40g,棉籽粉25g,黄豆饼粉2．4g,蛋白胨25g,CaCO35g,定容至1L,pH7．0。培养基优化后多杀菌素产量由278．1mg／L提高到508．7mg／L,比初始多杀茵素产量提高了1．83倍。     

丝状真菌Glarea lozoyensis SIIA-F1108产纽莫康定B0发酵条件的研究

【目的】采用响应面法优化丝状真菌Glarea lozoyensis SIIA-F1108发酵生产纽莫康定B_0培养基,提高发酵产量;通过氮源优化,降低发酵液菌体浓度,改善发酵过程的溶氧水平。【方法】采用Plackett-Burman设计和响应面法进行培养基优化,筛选出对纽莫康定B_0产量具有显著影响的因素;通过最陡爬坡实验及Box-Behnken设计,并利用Design-Expert软件对实验数据进行回归分析,得到优化的发酵培养基配方;通过对优化培养基中氮源组分进行全因子实验,最终得到高产量和低菌体浓度发酵培养基。【结果】实验数据表明:甘露醇、脯氨酸和葡萄糖对纽莫康定B_0产量影响最大;最佳浓度分别为甘露醇167.3 g/L、脯氨酸26.1 g/L、葡萄糖28.5 g/L。采用优化后的培养基进行摇瓶发酵,纽莫康定B_0产量达到了1 840 mg/L,较优化前提高了42%,与预测结果一致。用硫酸铵部分替换棉籽饼粉后,发酵液菌体浓度降低,在100 L发酵罐上对优化后的结果做了进一步的验证,纽莫康定B_0产量达到1 980 mg/L。【结论】模型预测值与实验值有较高吻合度,具备较高可信度和显著性,发酵产量提高了42%,响应面实验设计和分析方法能够有效地用于丝状真菌Glarea lozoyensis SIIA-F1108产纽莫康定B_0发酵培养基进行优化。通过调整培养基中的氮源组成,降低了发酵液菌体浓度,改善了发酵过程的溶氧水平。     

猪源屎肠球菌WEI-9的高密度培养

目的对分离自健康仔猪肠道的屎肠球菌(Enterococcus faecium)WEI-9的高密度发酵培养基进行响应面优化,为菌株WEI-9的工业化生产奠定基础。方法首先采用单因素试验确定最适高密度发酵培养基的碳源和氮源,随后采用Plackett-Burman设计筛选出影响菌株WEI-9发酵活菌数的显著因素,利用最陡爬坡试验得出显著因素逼近最大活菌数产量的响应区域,最后应用Box-Behnken设计和响应面分析法确定显著影响因子的最佳浓度。结果优化后的最适高密度发酵培养基成分和配比为:乳清粉21.34 g/L,蛋白胨21.94 g/L,Na AC·3H2O 5 g/L,柠檬酸铵2 g/L,K2HPO4·3H2O 2 g/L,Mg SO4·7H2O 0.2 g/L,Mn SO4·H2O 0.05 g/L,吐温-80 1 g/L,发酵液最高活菌数达到1.6×109CFU/m L,是相同条件下MRS培养基中活菌数的1.98倍。结论本研究实现了猪源屎肠球菌(Enterococcus faecium)WEI-9的高密度培养。     

人铜锌超氧化物歧化酶基因改良及在聚球藻中表达

应用PCR定点突变技术把质粒pESOD中人铜锌超氧化物歧化酶基因(hCu,Zn-SOD)的Cys111密码子突变为Ala111密码子,再构建重组子,通过随机同源重组将突变后的hCu,Zn-SOD整合入聚球藻Synechococcussp.PCC7942,并实现表达。表达产物用SDS-PAGE、Western blot、酶活等方法测定均为阳性反应;热稳定性测定显示,hCu,Zn-SOD在80℃保温30min后仍具有95%的活力,耐热能力比天然hCu,Zn-SOD有了较大的提高。蛋白扫描结果显示目的蛋白占可溶性蛋白的3.61%。     

人超氧化物歧化酶分子生物学研究进展

人超氧化物歧化酶是一类极有开发前景的药用蛋白。hCu/Zn-SOD为二聚体,主要存在于细胞质,hMn-SOD为四聚体,主要存在于线粒体基质,hEC-SOD也为四聚体,主要存在于分泌液。各种同工酶的分子量、氨基酸序列、基因结构已经研究清楚,并进行了基因克隆和表达。细菌表达产物以包含体形式存在。复性工作复杂而困难。利用真核细胞进行克隆和表达是该酶今后的发展方向。     

Optimization of culture medium and growth conditions for production of L-arabinose isomerase and D-xylose isomerase by <Emphasis Type="Italic">Lactobacillus bifermentans</Emphasis>

Lactobacillus bifermentans was used to produce the intracellular enzymes L-arabinose isomerase and D-xylose isomerase. Various factors of cultivation (temperature, pH, and incubation period) and culture medium composition (mineral salts, carbon source, and nitrogen source) were studied to select the conditions that maximize production of these enzymes. Arabinose isomerase and xylose isomerase activities were 9.4 and 7.24 U/ml, respectively. They were highest at 9 h of cultivation in the optimized medium, 1.6 times higher than that in the basic MRS broth. The optimal medium composition and cultivation conditions were determined. For optimal growth, the strain required Tween 80 (1 g/l) and a source of inorganic nitrogen (e.g., ammonium citrate). The bacterium had no requirement for sodium acetate for either growth or production of isomerases. The production rate of enzymes was increased when metal ions were added, primarily manganese (2.5 mM). The text was submitted by the authors in English.     

Suppression of intracellular superoxide dismutase activity by antisense oligonucleotides causes inhibition of progesterone production by rat luteal cells.

Superoxide radicals are known to inhibit progesterone production by luteal cells and have also been reported to cause apoptosis in various cells. The corpus luteum has an antioxidant enzyme to scavenge superoxide radicals: copper-zinc superoxide dismutase (Cu, Zn-SOD). However, it remains unknown how the decrease in intracellular Cu,Zn-SOD activity influences luteal function. This study was therefore undertaken to investigate whether suppression of intracellular Cu,Zn-SOD activity inhibits progesterone production by rat luteal cells and causes apoptosis. To suppress intracellular Cu, Zn-SOD activity, dispersed rat luteal cells were incubated with Cu, Zn-SOD antisense oligonucleotides. The 48-h treatment with antisense oligonucleotides (10 microM) inhibited Cu,Zn-SOD activity by 50% and Cu,Zn-SOD mRNA level by 30%, whereas sense oligonucleotides used as the control had no effect. Progesterone concentration in the medium was significantly decreased by the 48-h treatment with antisense oligonucleotides in the presence of hCG, and this inhibitory effect was completely blocked by the simultaneous addition of N-acetyl-L-cysteine, an antioxidant. Treatment with antisense oligonucleotides caused no significant change in the percentage of apoptotic cells as morphologically evaluated by the nuclear staining with Hoechst dye. In conclusion, the decrease in intracellular Cu, Zn-SOD activities inhibits progesterone production by rat luteal cells, which may be mediated by superoxide radicals, suggesting that intracellular Cu,Zn-SOD plays important roles in the regulation of luteal function.     

Optimization of culture medium and growth conditions for production of L-arabinose isomerase and D-xylose isomerase by Lactobacillus bifermentans

Lactobacillus bifermentans was used to produce the intracellular enzymes L-arabinose isomerase and D-xylose isomerase. Various factors of cultivation (temperature, pH, or incubation period) and culture medium composition (mineral salts, carbon and nitrogen source) were studied to select the conditions that maximize production of these enzymes. Arabinose isomerase and xylose isomerase activities were 9.4 and 7.24 U/ml, respectively. They were highest at 9 h of cultivation in the optimized medium, 1.6 times higher than that in the basic MRS broth. The optimal medium composition and cultivation conditions were determined. On the other hand, the strain required for growth Tween 80 (1 g/l) and a source of inorganic nitrogen (e.g. ammonium citrate). The bacterium had no requirement for sodium acetate for both growth and production of isomerases. The production rate of enzymes was increased when metal ions were added and mainly manganese (2.5 mM).     

Insufficient uracil supply in fully aerobic chemostat cultures of Saccharomyces cerevisiae leads to respiro-fermentative metabolism and double nutrient-limitation

A combination of chemostat cultivation and a defined medium was used to demonstrate that uracil limitation leads to a drastic alteration in the physiology of auxotrophic cells of Saccharomyces cerevisiae. Under this condition, the carbon source is dissimilated mainly to ethanol and acetate, even in fully aerobic cultures grown at 0.1 h^?1, which is far below the critical dilution rate. Differently from nitrogen-, sulphur-, or phosphate-limited cultures, uracil limitation leads to residual sugar (either glucose or sucrose) concentrations below 2 mM, which characterizes a situation of double-limitation: by the carbon source and by uracil. Furthermore, the specific rates of CO₂ production and O₂ consumption are increased when compared to the corresponding prototrophic strain. We conclude that when auxotrophic strains are to be used for quantitative physiological studies, special attention must be paid to the cultivation conditions, mainly regarding medium formulation, in order to avoid limitation of growth by the auxotrophic nutrient.     

Intensification of the growth and development of Bacillus thuringiensis H14 266/2-1 by optimizing the nutrient medium

The mathematical method of experimental design was used to develop a new enzymic medium for cultivation of Bacillus thuringiensis H14 266/2-1, a bactoculicide producer. The optimized medium based on corn flour enzyme lysate as a carbon source and fodder yeast enzyme lysate as a source of nitrogen amine made it possible to increase twice the titre biomass yield for 24 h cultivation as compared to the initial medium. The above medium does not yield to the initial production medium in the insecticide activity.     

A novel approach for medium formulation for growth of a microalga using motile intensity

Motile intensity of the cells, defined as the specific mean kinetic energy, was measured by image analysis and used to formulate a suitable medium for the cultivation of a motile microalga. Nitrogen source at 60 mg/L was used as the target component. The cells grown in a medium containing urea showed the highest motile intensities during cultivation when compared to the cells grown with NH(4)Cl or (NH(4))(2)SO(4) as the nitrogen source. The urea culture gave the highest biomass yield and lipid content of 1.06+/-0.12 g/L and 22.34+/-2.56%, respectively after 150 h of cultivation. These results indicated a strong dependence of motile intensity on the nitrogen source used in the growth medium. This concept, which requires only a small droplet of the sample, can find potential application in the design and optimization of culture media.     

Nitrogen Effect on Water-Soluble Polysaccharide Accumulation in <Emphasis Type="Italic">Streblonema</Emphasis> sp. (Ectocarpales,Phaeophyceae)

The water-soluble polysaccharides of brown algae attract the increasing attention of researchers as an important class of polymeric materials of biotechnological interest. The sole source for production of these polysaccharides has been large brown seaweeds such as members of Laminariales and Fucales. A new source of water-soluble polysaccharides is suggested here: it is a filamentous brown alga Streblonema sp., which can be cultivated under controlled conditions in photobioreactors that allow obtaining algal biomass with reproducible content and quality of polysaccharides. The accumulation of water-soluble polysaccharides can be stimulated by macronutrient limitation. In response to nitrogen deficiency, Streblonema sp. accumulated water-soluble polysaccharides (WSPs) rich in laminaran. WSP accumulation started after 3–4 days following nitrate depletion and reached a plateau at around day 7. Polysaccharide accumulation was related to cellular nitrogen content. The critical internal N level that triggered the onset of polysaccharide accumulation was 2.3% dry weight (DW); at a cellular N concentration less than 1.4% DW, the polysaccharide synthesis stopped. Upon nitrate re-supply, mobilization of WSP occurred after 3 days. These results suggest that a two-stage cultivation process could be used to obtain large algal biomass with high water-soluble polysaccharide production: a first cultivation stage using nitrate-supplemented medium to accumulate algal biomass followed by a second cultivation stage in a nitrate-free medium for 3 to 7 days to enhance polysaccharide content in the alga.     

Efficient cellulase production by Trichoderma reesei in continuous cultivation on lactose medium with a computer-controlled feeding strategy

A low-foaming hydrophobin II deletant of the Trichoderma reesei strain Rut-C30 was used for production of cellulases by continuous cultivation on lactose medium in a laboratory fermenter. The control paradigm of the addition of new medium to the continuous process was based on the growth dynamics of the fungus. A decrease in the rate of base addition to the cultivation for pH-minimum control was used as an indicator of imminent exhaustion of carbon source for growth and enzyme induction. When the amount of base added per 5 min computation cycle decreased below a given value, new medium was added to the fermenter. When base addition for pH control thereafter increased above the criterion value, due to increased growth, the medium feed was discontinued or decreased. The medium feeding protocol employed was successful in locking the fungus in the stage of imminent, but not actual, exhaustion of carbon source. According to the results of a batch cultivation of the same strain on the same medium, this is the phase of maximal enzyme productivity. The medium addition protocol used in this work resulted in a very stable continuous process, in which cellulase productivity was maintained for several hundred hours at the maximum level observed in a batch cultivation for only about 10 h. Despite a major technical disturbance after about 420 h, the process was restored to stability. When the cultivation was terminated after 650 h, the level of enzyme production was still maximal, with no signs of instability of the process.