吸水链霉菌NND-52-C菌株产阿扎霉素B 发酵条件的优化

通过碳源、氮源的单因子实验和正交实验,确定了吸水链霉菌NND-52-C菌株产阿扎霉素B最佳的液体发酵培养基组分(%,质量分数)甘油4.5,玉米粉3,黄豆粉1,蛋白胨1,NaNO30.5,NaCl 0.2,CaCO3 0.3,MgSO4·7H2 O0.05,FeSO4 0.05,PH 7.5;阿扎霉素B最佳的发酵条件发酵前期温度30℃,起始pH 7.5;发酵后期温度28℃,pH6.8;接种量10%,装液量30 mL/250mL摇瓶,发酵时间5 d,最终阿扎霉素B的产量达到l 434 mg/L,比原配方以及原发酵条件提高了76%.     

链霉菌发酵麦草产木聚糖酶的试验研究

通过正交设计试验 ,找出利用链霉菌和麦草基质发酵生产木聚糖酶的试验条件。培养基 (g/L) :麦草粉 ,4 5 ;(NH4 ) 2 SO4 ,7.5 ;酵母膏 ,8;K2 HPO4 ·3H2 O ,1;MgSO4 ·7H2 O ,0 .5 ;NaCl,0 .3。接种量为 5 .0× 10 8个孢子 / 5 0mL培养基 ,振荡培养 (12 0r/min) 5d     

娄彻氏链霉菌ATCC10739产抗生素Borrelidin发酵条件优化及其分离纯化

对娄彻氏链霉菌ATCC10739固体发酵产生十八元大环内酯抗生素Borrelidin进行了发酵条件的优化。首先筛选得到了理想的发酵培养基;其次考察了发酵时间、起始pH值以及在ISP-2培养基中添加附加碳源、氮源对Borrelidin产量的影响。初步确定最适发酵条件为:ISP-2培养基中添加1%甘油,起始pH值为6.0,培养温度30°C,发酵时间为7 d,产量可达1.336 mg/L。采用有机溶剂萃取、硅胶层析和半制备型高效液相色谱(HPLC)等分离技术纯化得到Borrelidin。     

产胞外木聚糖酶链霉菌发酵条件的正交试验

通过正变试验,设计出适合链霉菌（Streptomycessp.Strz—6）产胞外木聚糖酶的发酵条件,培养基（g／L）含麦草半纤维素5,NaNO31.67,酵母膏2,乳糖2,Tween801.5K2HPO4·3H2O1,MgSO4·7H2O0.5,NaCl0．3,微量元素B、Mn、Fe、Zn、Mo。接种量为1．4×108个孢子／50ml培养基,振荡,（120r／min）培养5d.     

腐植酸生产菌株——链霉菌发酵条件研究

利用链霉菌ST菌株发酵生产腐植酸。在蔗渣发酵培养基的基础上,采用一次回归正交试验,对腐植酸发酵过程中接种量（I）、通气量（搅拌次数,A）、温度（T）及时间（D）4个因素对腐植酸产量的影响情况进行分析。结果表明发酵时间的影响最为显著,接种量影响显著;所得到的回归方程有效且可信度高,回归方程为Y=6．0356＋0．02501＋0．0033A＋0．0069T＋0．2425D,其中各因素均与腐植酸产量呈正相关性。该回归方程为腐植酸生产过程链霉菌ST菌株发酵条件的控制提供了很好的指导作用。     

海洋来源链霉菌MY0504产纤溶酶的发酵条件优化

【目的】以发酵液纤溶酶活力为指标,优化海洋来源的链霉菌菌株MY0504的发酵条件。【方法】在菌株生长曲线及单因素试验基础上,采用Plackett-Burman设计筛选影响纤溶酶活性的主要因素,进一步用最陡爬坡试验及Box-Behnken中心组合设计法优化发酵条件。【结果】纤溶酶活性最高的发酵条件为:葡萄糖21.68 g/L,酵母粉25.31 g/L,NaCl5.0 g/L,K_2HPO_4·3H_2O3.0 g/L,MgSO_4·7H_2O 0.5 g/L,FeSO_4·7H_2O 0.02 g/L,装液量50 mL(250 mL摇瓶),接种量10%(体积比),初始pH 7.5,温度24°C,转速200 r/min,培养时间4.5 d。发酵液纤溶酶活性可达2 190.6 U/mL。【结论】确定了MY0504菌株产纤溶酶的最优发酵条件,为该酶的进一步分离纯化及性质研究奠定基础。     

链霉菌FIM-0916产安福霉素的发酵条件优化

本文采用单因素和正交试验设计,对链霉菌 Streptomyces canus sp. FIM-0916产安福霉素的发酵培养基配方及发酵条件进行了优化。优化后的最佳培养基配方为：蔗糖1.5%,黄豆粉1.0%,组氨酸0.1%,KNO3 0.1%, CaCO3 0.1%。最佳发酵条件为：种子菌龄54 h,装液量120 mL/500 mL,接种量2%,发酵温度28℃,摇床转速250 r/min;最佳发酵时间为5 d。在该优化条件下,安福霉素的发酵效价比对照提高248%,为安福霉素的后续开发奠定了基础。     

链霉菌A048产几丁质酶最佳发酵工艺研究

将链霉菌A048在完全培养基中培养至对数生长末期,离心洗涤收集菌丝体,然后接种入发酵产酶培养基中,进行二步发酵工艺牛产几丁质酶,几丁质酶活力比一步发酵工艺提高1．1倍,发酵周期共54h,比一步发酵工艺缩短66h;把菌丝体与几丁质粉共固定化,接入发酵产酶培养基中培养36h,几丁质酶活力比一步发酵工艺提高1．8倍,发酵周期缩短54h;在二步发酵工岂中另添加0．4％纤维素,几丁质酶活力可提高4倍,比一步发酵工艺提高10倍,酶活力达18．52U／mL。采用几丁质和纤维索双因子诱导二步发酵工艺可能是链霉菌A048生产几丁质酶的最佳工艺。     

阿维链霉菌发酵培养基的优化

通过优化发酵过程中培养基的组成使得阿维链霉菌的发酵单位及有效组分Bla含量提高。采用单因子试验法及均匀设计试验法分析各种营养成分及其配比对阿维链霉菌Co39-15发酵单位和有效组分Bla含量的影响。获得最佳的种子培养基和发酵培养基配方,发酵单位及有效组分Bla含量比原来的发酵水平分别提高了20%～30%、8%～10%。利用单因子试验法及均匀设计试验法对抗生素的发酵培养基进行优化,是一种快速、效果显著的方法。     

链霉菌A01-chit33CT产纳他霉素和几丁质酶协同表达发酵条件优化

生物农药由于具有良好的生态效应和安全性,因此比化学农药更受到人们的青睐,生物农药的发展契合低碳、循环、清洁绿色经济发展理念。因此,寻求利于食品安全和环境保护,同时高效控制植物病害的新型生物农药成为时下及未来研究的热点。链霉菌以产生纳他霉素等抗生素起到生防作用。链霉菌株A01-chit33CT既可以产生纳他霉素又可以高表达几丁质酶活,生防效果大大增加。为确定链霉菌A01-chit33CT产纳他霉素和几丁质酶协同表达的发酵条件,初步探索了碳氮源和发酵条件对菌株产生纳他霉素和几丁质酶的影响。结果表明,葡萄糖促进纳他霉素的产生而抑制几丁质酶的表达,因此分两阶段添加葡萄糖和几丁质粉来达到二者协同表达。研究确定最佳发酵培养基为:葡萄糖40 g/L,几丁质粉10 g/L(发酵4 d添加),黄豆粉30 g/L,大豆蛋白胨10 g/L,CaCO35 g/L,MgSO4.7H2O 0.5 g/L,K2HPO40.5 g/L。最优发酵条件为:初始pH 6.0,温度28℃,转速180 r/min。在此条件下,链霉菌A01-chit33CT产纳他霉素达1.52 g/L,同时几丁质酶活达990 U/ml,二者比优化前的水平分别提高了1.95倍和2.27倍。     

酪蛋白水解物对雷帕霉素产生菌Streptomyces hygroscopicus ATCC29253 接合转移效率的影响

吸水链霉菌(Streptomyces hygroscopicus)ATCC29253能够产生非常丰富的次级代谢产物,除了雷帕霉素外,还可以分泌尼日利亚菌素、洋橄榄叶素、六烯类抗生素等多种具有生物活性的物质,具有重要的研究价值和应用前景。【目的】而建立高效的遗传操作系统是研究该链霉菌相关代谢产物合成机理和构建基因工程菌株的基础。【方法】我们测试了不同培养基及供体菌对吸水链霉菌及其它链霉菌接合转移效率的影响。【结果】我们发现酪蛋白水解物和镁离子能显著提高S.hygroscopicus ATCC29253接合转移效率。通过随机组合试验,筛选出最佳的MgCl2和酪蛋白水解物浓度组合,使得S.hygroscopicus ATCC29253接合转移效率达到1.5×10-4。同时我们还发现酪蛋白水解物可以明显改变S.lividans、S.albus、S.avermitilis的接合转移效率。【结论】本研究首次发现酪蛋白水解物不光对S.hygroscopicus ATCC29253接合转移有作用,对其它常用的链霉菌如S.lividans、S.albus、S.avermitilis等的接合转移效率都有显著的影响。     

Preferential production of rapamycin vs prolylrapamycin by Streptomyces hygroscopicus

A trace of prolylrapamycin is often produced in rapamycin fermentations carried out by strains of Streptomyces hygroscopicus. Prolylrapamycin was produced as the major rapamycin when L-proline was added to the fermentation medium. Addition of proline plus thiazolidine-2-carboxylic acid (T2CA), a sulfur-containing proline analog, prevented rapamycin production and stimulated prolylrapamycin production, thereby resulting in an even greater selective production of prolylrapamycin. T2CA addition inhibited rapamycin production even in the presence of L-lysine which is converted into pipecolic acid intracellularly and normally stimulates rapamycin formation. Addition of the rapamycin precursor, DL-pipecolic acid, surprisingly failed to stimulate rapamycin production. However, when DL-pipecolic acid was added with L-proline, it reduced the formation of prolylrapamycin and stimulated rapamycin production; this was evident especially in the presence of T2CA. The evidence suggests that T2CA suppresses rapamycin production by inhibiting intracellular conversion of L-lysine into pipecolate. Furthermore, the data suggest that uptake of pipecolate into the cell is stimulated or induced by growth in the presence of L-proline and/or T2CA. Received 24 December 1997/ Accepted in revised form 12 May 1998     

添加胰蛋白酶促进Streptomyces hygroscopicus CCTCC M203062产谷氨酰胺转胺酶

研究了添加胰蛋白酶对Streptomyces hygroscopicus CCTCC M203062合成谷氨酰胺转胺酶的影响。结果表明,添加胰蛋白酶可以提高发酵过程中谷氨酰胺转胺酶的酶活。摇瓶培养中,在发酵起始时添加200U/ml的胰蛋白酶,谷氨酰胺转胺酶的酶活最高达到了6.61U/ml,比对照提高了27.1%。初步研究表明,添加胰蛋白酶可以直接切割发酵过程中产生的酶原,使其被快速地转化为成熟酶,因此推测胰蛋白酶提高谷氨酰胺转胺酶酶活的原因是解除了酶原的产物抑制作用,产生更多的酶原,从而促进了产酶。     

吸水链霉菌发酵生产谷氨酰胺转胺酶的补料研究

在吸水链霉菌(Streptomyces hygroscopicus)分批发酵研究的基础上,通过在菌体生长阶段指数流加葡萄糖,进行高细胞密度培养,获得了较高的菌体量;待菌体生长进入产酶期后,通过补加氮源,为产酶提供充足的氮源,其中通过流加蛋白质氮源,可以减少蛋白酶对成熟MTG的分解,促进产酶。结果表明,8~16 h采用较高的的比生长速率(0.15 h-1),后期降低比生长速率(0.10 h-1),此时得到的菌体量较高,可达到36 g/L,比分批发酵下的菌体量提高了80%。同时在培养基中添加50g/L的豆饼粉,最终酶活可达到5.79U/ml,提高了83%。     

Effect of nitrogen source on biosynthesis of rapamycin by Streptomyces hygroscopicus

Six non-amino acid nitrogen compounds were examined as nitrogen source for growth of Streptomyces hygroscopicus and biosynthesis of rapamycin. Of the nitrogen sources studied, ammonium sulfate was the best with respect to formation of rapamycin, and supported cell growth comparable to the organic nitrogen sources used in the control chemically defined medium, ie, aspartate, arginine plus histidine. In the new chemically defined medium, which is buffered with 200 mM 2-(N-morpholino)ethanesulfonic acid to prevent decline of pH during fermentation, an ammonium sulfate concentration of 40 mM was optimal for biosynthesis of rapamycin. Rapamycin production increased by more than 30% on both volumetric and specific bases as compared to the previous medium containing the three amino acids as nitrogen source. Received 08 November 1996/ Accepted in revised form 07 April 1997     

吸水链霉菌谷氨酰胺转胺酶基因的阻断及其对细胞分化的影响

【目的】通过对吸水链霉菌(Streptomyces hygroscopicus)中谷氨酰胺转胺酶基因的阻断,以期深入了解谷氨酰胺转胺酶生理功能,并为谷氨酰胺转胺酶发酵优化提供新的研究思路。【方法】以温敏型质粒pKC1139为出发质粒,构建阻断吸水链霉菌谷氨酰胺转胺酶编码基因的重组质粒pKC1139-TG1,转化吸水链霉菌原生质体,通过抗性筛选和PCR验证,成功得到一株谷氨酰胺转胺酶阻断菌株,命名为S.h-△TG。【结果】以原始菌株为对照,重组子基内菌丝生长不受影响,但是由基内菌丝分化形成气生菌丝的过程受到影响,重组子基本不产气生菌丝。【结论】谷氨酰胺转胺酶对吸水链霉菌气生菌丝的形成有着重要的影响,参与链霉菌气生菌丝的形成。     

星形孢菌素的发酵条件优化

提高抗生素在产生菌中的表达效价,从而降低生产成本,是实现抗生素生产应用的重要基础.星形孢菌素是一种非特异性的蛋白激酶抑制剂,能够诱导多种类型的细胞凋亡,但目前星形孢菌素生产菌株的表达效价均较低,达不到生产要求,使其应用受到限制[1-4].     

In vitro and in vivo antagonism of pathogenic turfgrass fungi by Streptomyces hygroscopicus strains YCED9 and WYE53

Disease prevention is a current practice used to minimize fungal diseases of turfgrasses in lawns and golf greens. Prevention is accomplished through fungicide applications, and by periodic thatch removal. During the development of a microbial biodethatch product utilizing the lignocellulose-degrading Streptomyces hygroscopicus strains YCED9 and WYE53, we demonstrated using in vitro plate antagonism bioassays that both strains are antagonists of various turfgrass fungal pathogens. These activities were present when the cultures were growing on thatch, as demonstrated by antifungal antagonism bioassays with culture filtrates. Experiments conducted using a growth chamber demonstrated that a bio-dethatch formulation containing spores of strains YCED9 and WYE53 in a zeolite carrier, provided protection for Kentucky bluegrass seedlings against turfgrass pathogens, including Pythium ultimum, Fusarium oxysporum, Rhizoctonia solani, Sclerotinia homeocarpa, Gaeumannomyces graminis and Microdochium nivale. Results showed that by integrating the use of the S. hygroscopicus YCED9/WYE53 bio-dethatch formulation into routine turf management practices, it should be possible to both minimize thatch build-up while also controlling fungal turfgrass diseases by way of the antifungal biocontrol activity of these strains. This in turn would help control fungal pathogens in turfgrass while minimizing the need for routine chemical fungicide applications. Received 19 October 1998/ Accepted in revised form 19 March 1999