褐藻胶裂解酶产生菌的分离鉴定及产酶发酵优化

对一株从腐烂海带中筛选得到的产褐藻胶裂解酶的菌株进行鉴定,并对其产酶条件进行发酵优化。经形态学、生理生化特征和分子生物学鉴定,将其鉴定为盐单胞菌属,并命名为Halomonas sp. WF6。通过在摇瓶培养水平上进行单因素和多因素正交试验,确定褐藻胶裂解酶产生菌WF6的最适产酶培养基为：褐藻酸钠6.0 g/L,蛋白胨5.0 g/L,酵母粉2.5 g/L,NaCl 30 g/L,K⁺ 5 mmol/L。进而采用最适培养基进行产酶条件的优化,优化后的发酵产酶条件为：初始pH 8.0,培养温度25℃,接种量为2%,摇瓶装液量30 ml/250 ml,培养时间39 h。优化后的褐藻胶裂解酶酶活达117.66 U/ml,是优化前的2.1倍。该酶对褐藻酸钠的酶解产物主要由聚合度为二和三的褐藻寡糖组成。     

混合菌株降解褐藻胶的筛选、鉴定及产酶条件优化

为获得仿刺参（Apostichopus japonicus）肠道菌群中可有效降解褐藻胶的混合菌株,以海藻酸钠为唯一碳源配制培养基,以透明圈法进行初筛,DNS法和紫外法复筛,从已驯化仿刺参肠道中筛选得到4株高酶活力褐藻胶降解菌株S1、S2、S10和S11,经16S rDNA序列分析、电镜观察,确定菌株S2与S11分别为微杆菌属（Microbacterium sp.）和微小杆菌属（Exiguobacterium sp.）。对该4株菌株分别进行混合培养,获得菌株S2与S11最佳配比组合,并通过单因素试验及响应面优化试验对影响混合菌株产酶条件的发酵初始pH值、NaCl质量浓度、装液量和发酵温度4个因素进行优化。得到混合菌株最佳产酶条件为pH 8,NaCl质量浓度为40 g/L,装液量80 mL,温度28 ℃。在最佳发酵条件下,混合菌株酶活力可达94.78 U/mL,相比于优化前提高了43.9%,优化后混合菌株的酶活力显著提高。     

响应面法优化类芽胞杆菌HB172198产褐藻胶裂解酶发酵培养基

为了提高类芽胞杆菌新种HB172198产褐藻胶裂解酶活力,本研究采用响应面法对该菌株液体发酵培养基进行了优化实验。在单因素实验和Plackett-Burman试验筛选出海藻酸钠、胰蛋白胨、NaCl、MgSO4·7H2O等4个显著影响产酶因素的基础上,通过Box-Behnken设计及响应面法进行回归分析,得出产褐藻胶裂解酶最佳发酵培养基,其成分为:海藻酸钠7.50 g/L、胰蛋白胨13.57 g/L、NaCl 29.75 g/L、MgSO4·7H2O 0.08 g/L。优化条件下该菌株最大酶活性达14.60 U/mL,是优化前的1.87倍。本研究为菌株HB172198产褐藻胶裂解酶的大规模生产和工业应用提供了重要的理论依据。     

一株产酸克雷伯氏菌发酵培养基优化

为提高产酸克雷伯氏菌(Klebsiella oxytoca)的发酵水平,通过单因素优化,研究培养条件、碳源、氮源、无机盐对产酸克雷伯氏菌活菌量的影响,利用响应面分析法对影响产酸克雷伯氏菌活菌量的关键因子进行优化,30 L发酵罐进行扩大培养。得出最佳配方（质量分数）：黄豆饼粉2.19%,玉米粉1.0%,蔗糖1.10%,硫酸铵0.06%,玉米浆干粉0.5%,蛋白胨0.05%,硫酸镁0.04%,磷酸二氢钾0.02%,氯化钠0.080%,硫酸锰0.03%,pH 7.0~7.4。活菌量稳定在2.0×10¹⁰  cfu/mL以上,能够满足生产要求,为产酸克雷伯氏菌作为微生物菌肥的应用提供参考。     

一株产低温碱性脂肪酶菌株的发酵条件优化

对一株产低温碱性脂肪酶细菌（Pseudoalteromonas sp．BJ17）的发酵条件进行了优化,研究各种碳源及氮源对产酶的影响,应用正交实验优化其发酵培养基组成。结果表明：最佳培养基组成为淀粉12g／L,蛋白胨12g／L,酵母膏3g／L,酪蛋白2g/L。最佳培养温度为25℃,发酵时间为16h。     

产低温脂肪酶菌株CZW001发酵培养基优化研究

【目的】研究产低温脂肪酶菌株CZW001发酵培养基。【方法】在单因素试验的基础上, 采用Plackett-Burman (P-B)设计, Box-Behnken (B-B)设计和响应面试验设计(RSM), 在20 °C、pH 8.0、160?r/min发酵2 d条件下, 对发酵培养基进行优化。【结果】该菌株最适产酶培养基为(g/L): 葡萄糖7.68, 橄榄油21.93, 硫酸铵2.0, 磷酸二氢钾1.0, 硫酸镁0.27, 氯化钙0.3, 氯化钠20.0, 吐温-80 1.0。其最高酶活为62.8 U/mL, 比优化前提高了3.14倍。【结论】通过对产低温脂肪酶菌株CZW001发酵培养基优化研究, 明显提高低温脂肪酶活力。     

褐藻胶降解菌的筛选、鉴定及产酶条件优化

【目的】筛选一株能降解褐藻胶的菌株,并优化产酶条件以提高褐藻胶裂解酶活力。【方法】从漳州海域采集到海水和海泥,以海藻酸钠为唯一碳源,通过富集培养、初筛、复筛筛选到一株能够降解褐藻胶的菌株。依据16S rRNA序列分析、生理生化特征、菌体形态及菌落特征对该菌进行鉴定。通过单因素和正交试验对该菌的产酶条件进行优化。【结果】该菌属于海科贝特氏菌,命名为Cobetiamarina HQZ08。该菌株最佳的产酶培养基组成为:海藻酸钠7.00g/L、蛋白胨3.00g/L、NaCl30.00g/L,K2HPO4·3H2O 1.25 g/L。最佳发酵条件为:接种量2%,接种龄12 h,培养基起始pH为7.0,培养温度25°C,培养时间24 h。优化后褐藻胶裂解酶活力达到68.5 U/mL,TLC法分析酶解产物为褐藻胶寡糖。【结论】HQZ08菌株可以用于降解褐藻胶,产生聚合度为2–6的褐藻胶寡糖。     

烟草节杆菌肌酐酶发酵培养基优化

对烟草节杆菌发酵产酶培养基进行了优化。在烟草节杆菌的初始发酵培养基条件下,肌酐酶初始酶活仅为9.2U/g湿菌。首先,通过肌酸诱导、金属离子筛选实验发现肌酸和金属离子对烟草节杆菌产肌酐酶酶活有重要影响;然后再通过碳源和氮源优化,以玉米浆和酵母膏作为复合氮源,可溶性淀粉为碳源,肌酐酶产量可达到108.5 U/g湿菌;在以上基础上,最后通过两次正交试验优化初始发酵培养基,最优培养基组成为:肌酸0.3%,玉米浆0.3%,可溶性淀粉0.4%,酵母膏0.7%,Fe~2+0.003%,Mn~2+0.006%,Mg~2+0.005%,K_2HPO_40.1%,KCl 0.5%。在优化后的发酵培养基条件下,烟草节杆菌肌酐酶酶活达到182.82 U/g湿菌,为初始发酵培养基酶活的19.87倍。     

一株新海洋粘质沙雷氏菌产灵菌红素发酵条件优化

灵菌红素是由微生物产生的一种红色次级代谢产物,因其具有抗菌、抗癌和抗疟疾等功效,受到了生物医药领域的广泛关注。微生物发酵是当前产灵菌红素的主要方法,分离筛选高产灵菌红素的微生物、优化发酵条件是提高灵菌红素产率的重要途径。本研究从深圳湾筛选出一株含有红色色素的菌株,并基于16S rRNA基因序列对该菌株进行了系统发育分析和物种鉴定。紫外可见光全波长扫描和HPLC-MS图谱分析证明,该菌株所产红色色素为灵菌红素。进一步通过单因素试验和正交优化法优化了该菌产灵菌红素的发酵条件和发酵培养基组分。系统发育分析表明,该菌株为一株海洋粘质沙雷氏菌（Serratia marcescens）,并将其命名为S. marcescens SOCE 001。产灵菌红素的最佳发酵条件为：温度28 ℃、振荡培养转速220 r/min、培养基pH 7。发酵培养基最佳组合为：果糖添加量2 g/L、蛋白胨添加量10 g/L,MgSO₄添加量2 g/L。优化发酵条件后,经24 h培养, 灵菌红素产量可达2.468 g/L。     

重组Bacillus subtilis产B.stearothermophilus环糊精葡萄糖基转移酶的发酵优化

利用本研究室已构建的重组菌Bacillus subtilis/pBSMuL3-α/β-CGTase对产B.stearothermophilus环糊精葡萄糖基转移酶的发酵产酶进行了优化,考察了培养基中重要成分:碳源、有机氮源、无机氮源、有机与无机氮源质量比、碳源与氮质量比、金属离子种类等单因素对该重组菌产α/β-CGTase的影响,并采用正交实验对发酵培养基进行优化,对优化结果分析可知,重组菌B.subtilis/pBSMuL3-α/β-CGTase发酵产α/β-CGTase的最优培养基成本为:葡萄糖5 g/L,氮源(鱼骨蛋白胨∶NH4Cl=3∶1)25 g/L,1 mmol/L Mg^2+。在最优条件下发酵培养,α/β-CGTase的酶活由原来TB发酵培养基的9.20 U/mL提高至20.32 U/mL,是优化前酶活的2.2倍,为α/β-环糊精葡萄糖基转移酶的工业应用提供了理论支持。     

Extracellular Formation of Alanine by Anaerobes

The possibility of extracellular formation of amino acids by anaerobes was investigated. In general, anaerobes were able to produce 20 to 50 mg of alanine per dl of medium extracellularly. Clostridium saccharoperbutylacetonicum, the anaerobic bacterium for acetone-butanol fermentation, accumulated 100 mg of alanine per dl of medium containing 5 g of glucose, 1 g of ammonium acetate, 0.1 g of potassium dihydrogen phosphate, 0.04 g of magnesium sulfate, 0.001 g of ferrous sulfate, 1 μg of biotin, 0.1 g of yeast extract and 1 g of calcium carbonate in tap water.

Relationships between alanine formation and solvent yields or sporulation were investigated. Spore formation was not active in the medium for alanine formation and yield of acetone increased in this medium.     

Optimization of culture medium for enhanced production of exopolysaccharide from Aureobasidium pullulans

Polysaccharides produced by microorganisms are utilized for a variety of purposes, including the use in cosmetics and as food additives. More recently, polysaccharides have been exploited by the medical and pharmaceutical industries, and those originated from many species of mushrooms have been especially useful in industrial applications; however, the production and synthesis of these compounds is costly and time consuming. In this study, we developed a method for low-cost production of exopolysaccharide (EPS) that effectively screens components and optimizes medium composition using statistical methods (Plackett-Burman and Box-Behnken design). As a result, we obtained the following optimized medium: sucrose 165.73 g/L, sodium nitrate 3.08 g/L, dipotassium phosphate 1.00 g/L, potassium chloride 0.50 g/L, magnesium sulfate 0.50 g/L, ferrous sulfate 0.01 g/L, and 0.71 g/L of Ashbya gossypii extract. The maximum production of about 29 g/L EPS was achieved in the optimized medium during 84 h batch fermentation.     

Mixed carbon source control strategy for enhancing alginate lyase production by marine Vibrio sp. QY102

Medium and culture conditions for alginate lyase production by marine Vibrio sp. QY102 were first optimized using statistical methods including Plackett–Burman design and central composite design. Then, fermentation in 5-L bioreactor showed that alginate acted as easily used carbohydrate for Vibrio sp. QY102, while starch extended its growth phase and stabilized pH variations. Thus, a novel strategy using mixed carbon sources was proposed that starch supported growth while enzyme synthesis was induced by pulse feedings of solid alginate. The optimized process followed that Vibrio sp. QY102 grew on starch until the end of the logarithmic growth phase, and then solid alginate was added as 1 g/L every 3 h. Meanwhile, initial pH 5.0 and natural pH during fermentation was favorable for alginate lyase production. After optimization, the highest alginate lyase production reached 52.8 U/mL, which was 329 % higher than the control. Finally, fermentation scale-up was performed in 30-L bioreactor and the maximum alginate lyase production was obtained as 46.8 U/mL.     

Purification and characterization of a novel alginate lyase from the marine bacterium Cobetia sp. NAP1 isolated from brown algae

The application of marine resources, instead of fossil fuels, for biomass production is important for building a sustainable society. Seaweed is valuable as a source of marine biomass for producing biofuels such as ethanol, and can be used in various fields. Alginate is an anionic polysaccharide that forms the main component of brown algae. Various alginate lyases (e.g. exo- and endo-types and oligoalginate lyase) are generally used to degrade alginate. We herein describe a novel alginate lyase, AlgC-PL7, which belongs to the polysaccharide lyase 7 family. AlgC-PL7 was isolated from the halophilic Gram-negative bacterium Cobetia sp. NAP1 collected from the brown algae Padina arborescens Holmes. The optimal temperature and pH for AlgC-PL7 activity were 45 °C and 8, respectively. Additionally, AlgC-PL7 was thermostable and salt-tolerant, exhibited broad substrate specificity, and degraded alginate into monosaccharides. Therefore, AlgC-PL7 is a promising enzyme for the production of biofuels.     

一株产褐藻胶裂解酶的需钠弧菌筛选及酶解产物分析

[背景]褐藻胶裂解酶种类丰富、降解机制多样,是高效环保降解褐藻胶、制备褐藻寡糖的工具酶,成为褐藻植物高值化开发利用的研究热点.[目的]从海泥中筛选获得褐藻胶裂解酶高效产酶菌株,确定菌株发酵产酶最优条件,鉴定和分析酶降解产物,进而解析该酶的降解特性.[方法]以褐藻胶为唯一碳源,从海带养殖场附近海泥中筛选菌株,通过形态学观...     

氮源对灵芝菌丝体液态深层发酵合成灵芝三萜的影响

以沪农灵芝1号为供试菌株,葡萄糖作为碳源,用硫酸铵、氯化铵、鱼粉蛋白胨、胰蛋白胨和酵母粉作为氮源,研究不同种类氮源对灵芝菌丝体液态深层发酵过程的影响。首先,确定了N-10酵母自溶粉作为发酵的氮源,降低了发酵的复杂性和不确定性;其次,考察N-10酵母自溶粉不同浓度对灵芝菌丝体发酵合成灵芝三萜过程中菌丝体的生物量、葡萄糖消耗、灵芝三萜产量等方面的影响,确定了N-10酵母自溶粉的适宜添加浓度。在此基础上,采用响应面中心组合设计,对4因素最佳水平范围进行研究,结果表明,葡萄糖、N-10酵母自溶粉、磷酸二氢钾和七水硫酸镁的含量分别为31.06g/L、2.76g/L、1.77g/L和1.99g/L时,灵芝三萜的理论产量为21.166g/kg干菌丝体,实际发酵产量提高到21.153g/kg干菌丝体。与原工艺相比,新工艺的灵芝三萜产量提高了6.22%。     

Enhanced uridine diphosphate <Emphasis Type="Italic">N</Emphasis>-acetylglucosamine production using whole-cell catalysis

Uridine diphosphate N-acetylglucosamine (UDPAG) can be produced by chemical, enzymatic, chemoenzymatic, and fermentative methods. In this study, we used whole-cell catalysis method to produce UDPAG for the first time by Saccharomyces cerevisiae. In order to increase the ATP utilization efficiency and UDPAG conversion yield, the response surface methodology was applied to optimize the whole-cell catalytic conditions for UDPAG production. Firstly, effects of uridine 5′-monophosphate (5′-UMP), glucosamine, vitamin B1, glycerol, magnesium chloride, potassium chloride, temperature, sodium dihydrogen phosphate, sodium acetate, fructose, and pH on UDPAG production were evaluated by a fractional factorial design. Results showed that UDPAG production was mainly affected by sodium dihydrogen phosphate, temperature, and vitamin B1. Then, the concentrations of sodium dihydrogen phosphate and vitamin B1 and temperature were further investigated with a central composite design and response surface analysis. The cultivation conditions to obtain the optimal UDPAG production were determined: sodium dihydrogen phosphate, 31.2 g/L; temperature, 29°C, and vitamin B1, 0.026 g/L. This optimization strategy led to an enhancement of UDPAG production from 2.51 to 4.25 g/L, yield from 44.6% to 75.6% based on the initial 5′-UMP concentration, and ATP utilization efficiency from 7.43% to 12.6%.     

红缘拟层孔菌发酵工艺的研究及其升罐培养

为筛选出红缘拟层孔菌发酵的最佳条件,并用于升罐发酵,试验优选出5个基础培养基,再以发酵菌丝体的生物量为指标,确定红缘拟层孔菌发酵的最佳条件。进行升罐发酵,间隔取出少量发酵液进行显微观察并检测葡萄糖含量,描述出菌丝体的生长状态。结果表明:红缘拟层孔菌发酵的最佳条件为马铃薯200 g/L,葡萄糖20 g/L,磷酸二氢钾1 g/L,硫酸镁1.5 g/L,维生素B10.4 g/L。升罐发酵中,菌丝干质量在前60 h处于快速的增长状态,最大为6.890 1 g/L,而60 h之后菌丝的生长变缓慢,到84 h之后,菌丝自溶,菌丝的产量开始下降。菌丝的葡萄糖含量经血糖仪检测在60 h时最高,达到0.296 5 g/L,之后呈现下降趋势。红缘拟层孔菌升罐发酵的最佳发酵时间为56~64 h。