氨基糖甙类抗生素JI-20A发酵培养条件的研究

研究了氨基糖甙类抗生素JI-20A分批发酵培养基和发酵工艺的优化。结果表明发酵培养基的优化组成为玉米淀粉60g/L,花生饼粉30g/L,麦芽糖10g/L,玉米浆8g/L,复合无机盐适量,淀粉酶适量,蛋氨酸1g/L和氯化钴6μg/mL。控制消后培养基pH值和氧的供应条件有助于抗生素JI-20A产生菌的菌体生长和产物合成。     

氨基糖甙类抗生素JI-20A发酵培养条件的研究

研究了氨基糖甙类抗生素JI-20A分批发酵培养基和发酵工艺的优化。结果表明发酵培养基的优化组成为玉米淀粉60g/L,花生饼粉30g/L,麦芽糖10g/L,玉米浆8g/L,复合无机盐适量,淀粉酶适量,蛋氨酸1g/L和氯化钴6μg/mL。控制消后培养基pH值和氧的供应条件有助于抗生素JI-20A产生菌的菌体生长和产物合成。     

细菌对氨基糖苷类抗生素产生抗性的机理及其控制策略

氨基糖苷类抗生素在治疗感染性疾病尤其是革兰氏阴性菌引起的严重感染方面起着重要作用 ,但是耐药菌株的出现较大地限制了此类抗生素的发展 ,因此 ,如何控制耐药性已经成为一项迫切需要解决的任务。细菌对氨基糖苷类抗生素产生抗性的机制很多 ,目前普遍接受的主要有三种 :1. 通过减少对氨基糖苷类抗生素的摄取或减少药物在体内的累积而产生抗性。 2. 通过改变核糖体结合位点而产生抗性。 3. 通过表达氨基糖苷类抗生素修饰酶而产生抗性。目前细菌耐药性的控制主要集中在对原有氨基糖苷类抗生素进行改造或合成新的抗生素 ,开发氨基糖苷类抗生素修饰酶抑制剂。     

等温滴定量热法研究核糖开关aac与氨基糖苷类抗生素的相互作用

核糖开关(riboswitch)是位于m RNA非编码区域的RNA元件,可与小分子配体结合导致结构转变,进而调控下游基因的表达。核糖开关aac能够特异性结合氨基糖苷类抗生素,从而调控氨基糖苷类抗生素抗性基因的表达。目前,核糖开关aac与氨基糖苷类抗生素相互作用的位点和机制尚不清楚。作者利用等温滴定量热法对核糖开关aac与氨基糖苷类抗生素的结合亲和力及结合热力学性质进行了研究,并初步探讨了点突变对相互作用的影响。结果发现,西索米星、庆大霉素、G418、奈替霉素和巴龙霉素能够特异性结合核糖开关aac,而阿米卡星、卡那霉素A、链霉素、链丝菌素、新霉胺、新霉素及核糖霉素与核糖开关aac无特异性相互作用;核糖开关aac与氨基糖苷类抗生素的结合热力学性质表明二者通过氢键和范德华力发生相互作用。西索米星滴定核糖开关aac突变体的结果表明,U68和A18位点很可能与氨基糖苷类抗生素形成氢键,A13和A44位点对于相互作用也有影响。这些结果对进一步研究核糖开关aac与氨基糖苷类抗生素相互作用的位点和机制具有重要的参考价值。     

利用糖芯片技术检测氨基糖苷类抗生素与RNAs和蛋白质之间的相互作用

氨基糖苷类抗生素是一类广谱型抗细菌感染药物,其不断增加的细菌耐药性很大程度上限制了它的临床应用,研究和开发新型氨基糖苷类抗生素具有重要意义。将氨基糖苷类抗生素固定到玻璃片基上,制成糖芯片,再分别与荧光标记的RNAs和蛋白质杂交,通过分析杂交后的荧光信号强度检测它们之间的相互作用。结果显示,氨基糖苷类抗生素芯片可以特异性地与r RNA的A位点模拟物、I型核酶和蛋白酶结合。因此糖芯片技术不仅可以检测氨基糖苷类抗生素与r RNAs的特异性结合,而且可以应用于寻找新型RNA结合配体的研究,为快速鉴定和筛选可紧密结合RNA靶标且毒性较低的新型氨基糖苷类抗生素奠定了一定的基础。     

重组大肠杆菌全细胞催化合成莱鲍迪苷D

莱鲍迪苷D(Rebaudioside D,RD)是一种稀有具有高甜度的甜菊糖苷类化合物。本文实现了重组大肠杆菌全细胞催化莱鲍迪苷A(Rebaudioside A,RA)合成RD。以水稻c DNA为模板,扩增得到葡萄糖基转移酶基因eugt11,构建了重组菌株E.coli BL21(p ETDuet-eugt11),并成功表达了重组蛋白6His-EUGT11。通过Ni柱亲和层析纯化并在体外酶催化反应表征了其催化活性。将重组菌BL21(p ETDuet-eugt11)应用于催化合成RD研究。探讨了反应体系pH、温度、柠檬酸钠浓度、菌体密度、二价金属离子、二甲苯体积分数、UDPG添加浓度对反应效率的影响。单因素考察结果显示,在菌体密度0.16 g湿细胞/m L反应液,底物RA浓度为1.0 mmol/L,pH 8.0,60 mmol/L柠檬酸钠,1%二甲苯,0.1 mmol/L Zn Cl2,12.0 mmol/L UDPG,反应温度42℃,反应时间24 h的条件下,RD产量为123.6 mg/L(约0.1 mmol/L)。     

氨基糖苷类抗生素应用的新机遇

氨基糖苷类抗生素是较早被发现并应用于临床上的一类抗生素,虽然它们没有完全从市面上消失,但由于其他副作用较少且广谱的抗生素的出现,其重要性已经减弱。目前,随着由多药耐药性（MDR）细菌引起的感染急剧增加,作为为数不多的治疗选择,氨基糖苷类抗生素重新进入了人们的视野,特别是用于革兰氏阴性细菌感染。尽管病菌对氨基糖苷类抗生素的耐药机制已基本清楚,但对氨基糖苷类抗生素抗菌模式的认识还远未全面。面对越来越多几乎无法治疗的细菌感染,氨基糖苷类抗生素在对抗多药耐药性病原菌上显示出新的应用前景。     

离子交换层析结合反向色谱纯化聚二氨基丙酸

ε-聚赖氨酸生产菌株Streptomyces albulus PD-1可合成一种新型非蛋白质氨基酸均聚物聚二氨基丙酸,采用离子交换层析和反向色谱,对聚二氨基丙酸的分离纯化进行研究。离子交换层析柱选用DEAE-Sepharose Fast Flow填料,50 mmol/L磷酸盐缓冲液(p H 7.5)平衡上样,含0.5 mol/L Na Cl的磷酸盐缓冲液(p H 7.5)洗脱,收集洗脱液用分子筛Sephadex G-25除去磷酸盐缓冲液。然后用C18反相色谱进一步纯化,流动相为V(甲醇)/V(0.1%磷酸)=5/95。经过离子交换层析和反向色谱,纯化得到聚二氨基丙酸纯品,回收率为39.8%,样品纯度达98.4%,为后续的聚二氨基丙酸的深入研究奠定基础。     

表达酿酒酵母ALAS的重组大肠杆菌胞外5-氨基乙酰丙酸的产量和纯化

5-氨基乙酰丙酸（5-aminolevulinate,ALA）由5-氨基乙酰丙酸合酶（5-aminolevulinate synthase,ALAS）催化产生。利用重组细菌在大肠杆菌合成ALA已有不少研究。重组真核生物ALAS在大肠杆菌合成ALA的研究没有报道。酿酒酵母ALAS在大肠杆菌重组表达,在摇瓶培养条件下,分析了胞外ALA的产量,重组菌的生长状况和细胞中ALAS的活性,利用两种国产树脂纯化ALA,毛细管电泳分析确定ALA纯度在LB培养基中,初始pH 6.5,含有20mmol/L的酮戊酸、20mmol/L琥珀酸和20mmol/L的甘氨酸,37℃下诱导培养12h,胞外ALA的产量为162mg /L培养基。纯化的ALA纯度达到90%。     

表达酿酒酵母ALAS的重组大肠杆菌胞外5-氨基乙酰丙酸的产量和纯化

5-氨基乙酰丙酸(5-aminolevulinate,ALA)由5-氨基乙酰丙酸合酶(5-aminolevulinate synthase,ALAS)催化产生。利用重组细菌在大肠杆菌合成ALA已有不少研究。重组真核生物ALAS在大肠杆菌合成ALA的研究没有报道。酿酒酵母ALAS在大肠杆菌重组表达,在摇瓶培养条件下,分析了胞外ALA的产量,重组菌的生长状况和细胞中ALAS的活性,利用两种国产树脂纯化ALA,毛细管电泳分析确定ALA纯度在LB培养基中,初始pH6.5,含有20mmol/L的酮戊酸、20mmol/L琥珀酸和20mmol/L的甘氨酸,37℃下诱导培养12h,胞外ALA的产量为162mg/L培养基。纯化的ALA纯度达到90%。     

磷对霍山石斛类原球茎悬浮培养细胞生长和多糖合成的影响

在确定了最适接种量和外植体细胞生理时间的基础上,研究了在不同起始磷浓度下,霍山石斛类原球茎生长、碳、氮消耗和多糖积累的动力学特性。以生长30d的类原球茎为材料,在接种量为100g/L时,类原球茎生长的最佳起始磷浓度为2.5mmol/L,培养36d时,类原球茎鲜重达496.5g/L。动力学分析表明,磷是霍山石斛类原球茎生长的限制性因素,胞内磷的积累水平与细胞生长具有相关性,2.5mmol/L的磷酸盐有利于碳、氮等营养物质的吸收;而多糖积累的最佳起始磷浓度为0.312mmol/L,培养36d时,其产量为2.22g/L。     

磷酸氢二铵对糙皮侧耳菌丝生长及基质降解酶活性的影响

氮源种类和浓度均会对糙皮侧耳Pleurotus ostreatus菌丝长势、生长速率以及代谢产生影响,而氮匮乏与氮过量积累都会对糙皮侧耳的生长产生不利影响.为了研究氮源对糙皮侧耳菌丝生长和基质降解酶活性的影响,本研究选取磷酸氢二铵[(NH4)2HP04]作为唯一氮源,通过在培养基中添加不同浓度的磷酸氢二铵检测糙皮侧耳菌...     

Effects of phosphate, glucose, and ammonium on cell growth and lincomycin production by Streptomyces lincolnensis in chemically defined media

Cell growth and lincomycin production were measured in batch cultures of Streptomyces lincolnensis in chemically defined media. In these fermentations the specific rate of antibiotic production was maximal during growth and always declined at the end of the growth phase. It was found that both phosphate and ammonium salts, while required for cell growth, had negative effects on antibiotic production. By increasing the concentration of magnesium sulfate, it was possible to increase both the production rates and final titers of lincomycin. The mechanism for this effect was found to be the reduction of soluble phosphate in the medium through the precipitation of ammonium magnesium phosphate. Lincomycin production rates were not inhibited by glucose at concentrations of up to 30 g/L.     

A study of N- and P-dependence of nikkomycin production in continuous culture with immobilized cells

Summary The influence of nitrogen and phosphate on the biosynthesis of nikkomycin was studied in chemically defined medium. Cells of Streptomyces tendae were immobilized on porous glass particles in a fluidized-bed reactor for continuous production of nikkomycin. Phosphate had no significant influence on the biosynthesis of nikkomycin. However, even a very low concentration of phosphate in the production medium (00.0125 mmol/l) resulted in microbial growth on the particles. The concentration of nitrogen was highly effective in the regulation of the biosynthesis of nikkomycin. A high level of antibiotic production (maximum 3.05 mg/g dry cell weight per hour) was maintained for a period of about 200 h in a medium that contained nitrogen at a concentration of 0.2 g NH₄NO₃/l. Offprint requests to: H. U. Trück     

Phytic acid-mediated regulation of secondary metabolism in Streptomyces thermoviolaceus grown in simple and complex media

Primary and secondary metabolism in the thermophilic actinomycete Streptomycesthermoviolaceus were found to be strongly regulated by phosphate in complexand defined media. Increasing phosphate levels in glutamate minimal salts media led to peakproduction of granaticin at 5 mmol phosphate, a concentration that was growth-limiting, beforetotal inhibition of antibiotic production at 50 mmol. Product formation in particulate rapeseedmeal-based media was found to be less affected by the initial phosphate concentration. Theaddition of 5 mmol phytic acid to proline minimal salts media led to an increase in theconcentration of phosphate optimal for antibiotic production from 5·7 mmol to 15 mmol andreduced inhibition at higher concentrations. Phytic acid was shown to bind phosphate fromminimal salts media and inhibit the growth of the organism at high concentrations. Differences inthe production of granaticin by S. thermoviolaceus in two rapeseed meal-derived mediawere shown to be phosphate and phytic acid-related. In particulate rapeseed, the additionalphosphate from minimal salts media was predominantly bound in an organic-soluble complex,while in extracted rapemeal media, phosphate was present predominantly in the free form.Overall, the work suggests that reduction in growth rate,which can be brought about by a varietyof factors including low phosphate concentrations,is the critical factor for the onset of secondarymetabolism in S.thermoviolaceus.     

Biosynthesis of cephamycin by resting cells of Streptomyces lactamdurans L 2/6

In order to investigate the nutritional conditions of cephamycin biosynthesis independently of the biomass growth process, the nutrient limited-resting cell system was used. A replacement medium eliminating cell multiplication was developed. The presence of Mg2+, carbon source and nitrogen source was necessary for cephamycin production by resting cells of Streptomyces lactamdurans L 2/6. Maximum antibiotic production was obtained when maltose, saccharose, and fructose were used as carbon source, and L-asparagine as nitrogen source. An inhibitory effect on the process was exerted by the calcium ions. There was no visible inhibition of cephamycin biosynthesis by inorganic phosphate ions in concentration up to 100 mM.     

Application of factorial design to the optimization of medium composition in batch cultures of Streptomyces lividans TK21 producing a hybrid antibiotic

Summary The composition of the liquid medium employed to obtain a hybrid antibiotic in batch cultures of a recombinant strain of Streptomyces lividans TK21 has been studied. Starch and glutamic acid are the most appropriate carbon and nitrogen sources to support respectively cell growth and antibiotic production. A central composite experimental design has been employed to derive a statistical model of the effect of phosphate and glutamic acid on growth and antibiotic production, and an initial concentration of 10 mM phosphate and 52.8 mM glutamic acid have been found optimal to maximize the final antibiotic concentration in batch cultures.     

Hexavalent molybdenum reduction to Mo-blue by <Emphasis Type="Italic">Acinetobacter calcoaceticus</Emphasis>

A local molybdenum-reducing bacterium was isolated and tentatively identified as Acinetobacter calcoaceticus strain Dr.Y12 based on carbon utilization profiles using Biolog GN plates and 16S rDNA comparative analysis. Molybdate reduction was optimized under conditions of low dissolved oxygen (37 °C and pH 6.5). Of the electron donors tested, glucose, fructose, maltose and sucrose supported molybdate reduction after 1 d of incubation, glucose and fructose supporting the highest Mo-blue production. Optimum Mo-blue production was reached at 20 mmol/L molybdate and 5 mmol/L phosphate; increasing the phosphate concentrations inhibited the production. An increase in an overall absorption profiles, especially at peak maximum at 865 nm and the shoulder at 700 nm, was observed in direct correlation with the increased in Mo-blue amounts. Metal ions, such as chromium, cadmium, copper, mercury and lead (2 mmol/L final concentration) caused ≈88, 53, 80, 100, and 20 % inhibition, respectively. Respiratory inhibitors, such as antimycin A, rotenone, sodium azide and cyanide showed in this bacterium no inhibition of the Mo-blue production, suggesting that the electron transport system is not a site of molybdate reduction.     

重组戊型肝炎病毒衣壳蛋白工程菌的高密度培养

在10L发酵罐中对戊型肝炎病毒衣壳蛋白在重组大肠杆菌中表达发酵工艺进行了研究,用分批培养方法探讨了不同培养基、培养基中磷酸盐浓度和Mg^2＋浓度等因素对菌体生长与重组蛋白表达的影响;用分批补料培养研究了不同的补料工艺对菌体生长与重组蛋白表达的影响,同时对重组菌诱导时期、诱导持续时间以及不同诱导温度表达包含体在尿素溶液中的溶解性进行了研究。结果表明,在优化后的培养基中,磷酸盐浓度、Mg^2＋浓度分别为80mmol/L 与20mmol/L时菌体生长与表达效果较好;分批补料培养中,37℃培养9h菌体达到对数期中期(约45OD600)为适宜诱导时期,加入终浓度为10mmol/L IPTG后诱导5h,OD600达到80以上,重组蛋白表达量达到29.74％,为最适收获菌体时间;37℃表达的包含体80％以上溶解在4mol/L的尿素溶液中,最终浓度达到14mg/mL; 10L发酵罐中确定的发酵工艺参数在30L发酵罐中进行了放大培养,10L发酵罐中确定的发酵工艺参数在30L发酵罐上具有可放大性与重复性, 可以应用于工业生产。     

除草剂精喹禾灵用于硅藻过量产生二十碳五烯酸

硅藻Nitzschia laevis是EPA很好的替代来源。除了对硅藻进行高密度培养外,EPA的产量还能利用除草剂来提高。本文研究了除草剂精喹禾灵对硅藻的生长和产EPA的影响。DMSO作为除草剂的溶剂,会对硅藻的生长造成抑制,DMSO在培养基中的添加量最好不要超过0.2%。除草剂能对硅藻的细胞形态造成损害,随着除草剂浓度的增加,硅藻的产量减低了,但脂质和EPA的含量提高了。当除草剂浓度为0.1mmol/L时,EPA的含量从3.00%增加到3.58%,提高了19.3%,EPA占总脂肪酸的含量也由25.15%提高到了32.88%。实验表明,除草剂精喹禾灵能促进硅藻EPA的积累,因而在筛选过量产生EPA微藻方面有重要用途。