以甘油为底物鼠李糖脂高产菌株的诱变选育

通过诱变选育,将铜绿假单胞菌(Pseudomonas aeruginosa)RG-14利用甘油发酵生产鼠李糖脂产量由13.6g/L提高到16.5 g/L。突变株经过5次连续传代培养,菌株仍维持稳定的鼠李糖脂产量,表明该菌株具有较好的遗传稳定性。利用基质辅助激光解析电离飞行时间质谱(MALDI-TOF-MS)技术分析诱变后菌株发酵甘油生产鼠李糖脂的组成,结果显示鼠李糖脂由Rha-C8-C8、Rha-C8-C10、Rha-C10-C10、Rha-C10-C12∶1、Rha-C10-C12、Rha2-C8-C10、Rha2-C10-C10、Rha2-C10-C12∶1和Rha2-C10-C12组成,其中单、双鼠李糖脂的相对丰度分别为54.8%和45.2%。当以工业粗甘油代替精甘油为底物时,该菌株鼠李糖脂产量达到14.2 g/L,表明其具有较好的应用潜力。     

预水解发酵碳源对铜绿假单胞菌NY3产鼠李糖脂特性及应用效能的影响研究

发酵碳源对铜绿假单胞菌NY3(Pseudomonas aeruginosa NY3)产鼠李糖脂(Rhamnolipids,Rha)的特性影响较大。研究了利用废弃动物油作为发酵碳源时,其碱预水解和酶预水解对NY3菌发酵产鼠李糖脂产量、产物结构和性能的影响,从碳源水解酸值与水解产物、鼠李糖脂组分结构和实际应用效果进行了研究。碱、酶预水解实验发现,碳源酸值由初始的19.81 mg/g分别提高到72.04 mg/g和73.75 mg/g,气质联用(GC-MS)分析检测结果表明,碱、酶预水解后,碳源均释放7种C14-C18碳链的脂肪酸,鼠李糖脂产量由未预水解的8.28 g/L分别提高到15.35 g/L和17.63 g/L。液质联用(LCMS-IT-TOF)分析结果表明,用未预水解及碱、酶预水解碳源发酵时,NY3菌所产鼠李糖脂中单糖脂含量分别为62.07%、65.67%、87.32%。利用NY3菌在中试条件下处理高浓度石化企业油污泥,发现鼠李糖脂能促进NY3菌去除油污泥中的石油烃,且促进作用强弱顺序为未预水解产Rha碱预水解产Rha酶预水解产Rha。     

废弃食用油脂生物合成鼠李糖脂研究进展

碳源的成本过高限制了鼠李糖脂的工业化生产及应用,废弃食用油脂作为一种廉价易得的碳源,越来越多的研究者开始关注用它发酵生产鼠李糖脂.废弃食用油脂的种类、投加量对鼠李糖脂的产量、结构、性质均会产生影响,目前研究中用废弃食用油脂作碳源,鼠李糖脂产量最高可达24.61g/L、表面张力最低达到24mN/m、产物CMC最低可达40.19mg/L.此外,本文还总结了菌株、氮源、微量元素、pH、溶氧及培养方式等因素对废弃食用油脂生产鼠李糖脂的影响,并展望了利用废弃食用油脂生产鼠李糖脂实现产业化的重点研究方向.     

以抽油烟机废油为原料发酵产鼠李糖脂的研究

鼠李糖脂是一种具有巨大潜力的阴离子生物表面活性剂,可应用于石油、食品、农业、日化工业等领域。探讨以抽油烟机废油为碳源发酵产鼠李糖脂的可能性,以铜绿假单胞菌WB505为出发菌体,在7 L发酵罐中鼠李糖脂的产量达到12.3±0.52 g/L。利用基质辅助激光解析飞行时间质谱(MALDI-TOF MS)分析出所产鼠李糖脂的组成,结果显示其主要含Rha-C_(10)-C_(10)和Rha_2-C_(10)-C_(10),其中单鼠李糖脂和双鼠李糖脂的总相对丰度分别为49.7%和50.3%。所产鼠李糖脂的临界胶束浓度(CMC)为45.0 mg/L,能将表面张力从60.5±0.81 mN/m降至25.3±0.68 mN/m,乳化系数E24均60%,并且对苯的乳化系数达到80.3±0.85%。以抽烟机废油为底物生产鼠李糖脂降低底物成本,为抽油烟机废油提供一种循环再利用处理方式。     

一株产鼠李糖脂菌株的筛选、鉴定及其产物特性分析

鼠李糖脂是最常见,研究最深入,应用最广泛的一类生物表面活性剂。从油田附近、沼气池旁的土壤中分离得到了25株菌,通过硫酸-苯酚反应,乳化实验,排油性实验,薄层色谱实验筛选产鼠李糖脂的菌株并表征产生的鼠李糖脂,通过16S r DNA序列确定细菌的种属。硫酸-苯酚反应显示有2株菌可能产鼠李糖脂;5株菌的发酵液具有明显的乳化效果,命名为"其红"这株菌的乳化指数可达58.97%;1株菌的发酵液上清稀释10倍后排油圈直径仍可达3.53 cm;薄层色谱实验也显示"其红"菌产鼠李糖脂。在四个实验中"其红"菌都检测到了鼠李糖脂,故确认"其红"菌可以产鼠李糖脂。16S r DNA序列分析表明"其红"菌属于希瓦氏菌属(Shewanella)并与腐败希瓦菌(S.putrefaciens LMG 26268(T))相似度最高。     

铜绿假单胞菌高产鼠李糖脂菌株的筛选

从多种来源筛选高产鼠李糖脂的菌株,并研究菌种发酵特性和鼠李糖脂产物的理化性质。采用CTAB平板初步筛选鼠李糖脂合成菌株,通过分析菌株的16S r RNA基因序列确定细菌种属,采用薄层色谱、红外光谱分析产物性质。结果显示,利用CTAB平板初筛获得163株阳性菌株,初步发酵确定10株高产细菌鼠李糖脂的产量为12.2-17.7 g/L,10株细菌均鉴定为铜绿假单胞菌。挑选产量最高的菌株B12,分别以甘油、菜籽油、花生饼粉或葵花籽饼粉为碳源进行发酵,发现菜籽油为合成鼠李糖脂的最佳碳源。进一步对比在35℃、37℃和40℃的发酵水平,发现37℃条件下鼠李糖脂产量最高,为26.8 g/L。最后,对鼠李糖脂发酵产物进行了初步纯化,并进行了薄层色谱和红外光谱分析。菌株B12能够合成较高水平的鼠李糖脂,可能成为工业生产的候选菌株。     

铜绿假单胞菌XJ601产鼠李糖脂的优化培养及其稳定性

以1株从原油污染样品中分离获得的铜绿假单胞菌XJ601为研究对象,采用蒽酮比色法定量分析鼠李糖脂,优化其产鼠李糖脂的培养基组成。研究表明:疏水性底物优于亲水性底物,具有更高的鼠李糖脂产量,尤以菜籽油最佳;氮源中,硝酸盐、NH_4Cl能促进鼠李糖脂的合成,以菜籽油为碳源时,最佳氮源为NaNO_3;C/N比值在20时,鼠李糖脂产量最高;P元素的微量添加会影响鼠李糖脂的合成。摇瓶培养获得的鼠李糖脂对不同温度、pH及NaCl浓度都具有较好的稳定性,表明其在三次采油及原油污染生物治理等领域具有较好的应用前景。     

铜绿假单胞杆菌O-2-2产鼠李糖脂的发酵培养基优化及LC-MS/MS分析

鼠李糖脂是一种性能优良的生物表面活性剂,在生物医药、环境保护、二次采油等方面具有很高的应用潜力.采用响应面分析法,对铜绿假单胞杆菌O-2-2的培养基进行了优化.Plackett-Burman(PB)实验设计表明,磷酸盐、硝酸盐和微量元素对鼠李糖脂的产量具有显著影响.Box-Behnke (BB)优化确定最佳培养基组成为磷酸盐、硝酸盐和微量元素用量分别为3.2g/L、13.76g/L和5.17ml,理论的最大产量为8.48g/L,与实测糖脂产量8.85g/L接近.摇瓶优化后的鼠李糖脂产量较优化前的6.24g/L提高了30.8％.最优化条件下采用10％的接种量逐级放大,并通过补料发酵,最终200L罐的鼠李糖脂产量达到70g/L,发酵时间仅为110h.采用新发明的二次蒸馏工艺,鼠李糖脂纯度达86.6％.液质联用(LC-MS)分析表明所生产的鼠李糖脂成分及含量为:双糖单脂32.9％、双糖双脂17.02％、单糖单脂3.16％、单糖双脂33.54％.     

不同结构配比的鼠李糖脂乳化活性与油泥清洗效果

以大庆油田原油和含油污泥为对象,研究不同结构配比鼠李糖脂表面活性剂乳化活性及其对含油污泥清洗效果的影响,并优化清洗工艺参数。结果表明:单鼠李糖脂比例越高,其表面活性越好;双鼠李糖脂比例越高,其对原油的乳化能力越强;临界胶束浓度随着双鼠李糖脂比例的增加而逐渐加大;单、双鼠李糖脂配比不同的表活剂对油泥的清洗效果也不同,质量比为50∶50时清洗效率最高;鼠李糖脂浓度为1.0 g·L^-1、热洗时间为1.5h、热洗温度为65℃、洗脱强度为220 r·min^-1、固液质量比为1∶5条件下,油泥的清洗效率最高,可达81.3%;含油率为29.6%的落地油泥,经一级洗涤后油泥残油率降至5.5%,原油回收率达到87.3%,清洗出的原油无明显乳化,易于分离。由此可知,鼠李糖脂的单、双糖脂比例不同对其理化性质和清洗含油污泥的效果均有不同程度的影响。     

产鼠李糖脂生物表面活性剂大肠杆菌的构建与优化

目前鼠李糖脂生物表面活性剂主要由条件致病的铜绿假单胞菌生产获得,从而影响工业应用。为了开发一种相对安全的鼠李糖脂生产菌,将带有不同强度组成型合成启动子的鼠李糖基转移酶基因(Rhamnosyltransferase gene,rhl AB)以单、中、高3种拷贝数分别在大肠杆菌ATCC 8739中异源表达,实现了不同产量的鼠李糖脂异源合成。对rhl AB基因和rha BDAC基因簇(TDP-L-鼠李糖合成的基因簇)进一步利用合成启动子进行组合调控,筛选获得了最优生产鼠李糖脂工程菌——大肠杆菌TIB-RAB226。对大肠杆菌TIB-RAB226进行发酵温度优化,鼠李糖脂产量达到124.3 mg/L,是优化前的1.17倍。通过分批补料发酵,12h时鼠李糖脂产量达到209.2 mg/L。对发酵产物进行高效液相色谱-质谱联用技术分析,共检出相对含量变化的5类质核比不同的鼠李糖脂同系物。本研究可为异源合成产鼠李糖脂提供重要参考。     

Physicochemical characterization and antimicrobial properties of rhamnolipids produced by Pseudomonas aeruginosa 47T2 NCBIM 40044

Pseudomonas aeruginosa 47T2, grown in submerged culture with waste frying oil as a carbon source, produced a mixture of rhamnolipids with surface activity. Up to 11 rhamnolipid homologs (Rha-Rha-C(8)-C(10); Rha-C(10)-C(8)/Rha-C(8)-C(10);Rha-Rha-C(8)-C(12:1); Rha-Rha-C(10)-C(10); Rha-Rha-C(10)-C(12:1); Rha-C(10)-C(10); Rha-Rha-C(10)-C(12)/Rha-Rha-C(12)-C(10); Rha-C(10)-C(12:1)/Rha-C(12:1)-C(10); Rha-Rha-C(12:1)-C(12); Rha-Rha-C(10)-C(14:1); Rha-C(10)-C(12)/Rha-C(12)-C(10)) were isolated from cultures of P. aeruginosa 47T2 from waste frying oil and identified by HPLC-MS analysis. This article deals with the production, isolation, and chemical characterization of the rhamnolipid mixture RL(47T2). The physicochemical and biological properties of RL(47T2) as a new product were also studied. Its surface tension decreased to 32.8 mN/m; and the interfacial tension against kerosene to 1 mN/m. The critical micellar concentration for RL(47T2) was 108.8 mg/mL. The product showed excellent antimicrobial properties. Antimicrobial activity was evaluated according to the minimum inhibitory concentration (MIC), the lowest concentration of an antimicrobial agent that inhibits development of visible microbial growth. Low MIC values were found for bacteria Serratia marcescens (4 microg/mL), Enterobacter aerogenes (8 microg/mL), Klebsiella pneumoniae (0.5 microg/mL), Staphylococcus aureus and Staphylococcus epidermidis (32 microg/mL), Bacillus subtilis (16 microg/mL), and phytopathogenic fungal species: Chaetonium globosum (64 microg/mL), Penicillium funiculosum (16 microg/mL), Gliocadium virens (32 microg/mL) and Fusarium solani (75 microg/mL).     

Chemical characterization and physical and biological activities of rhamnolipids produced by Pseudomonas aeruginosa BN10

Pseudomonas aeruginosa BN10 isolated from hydrocarbon-polluted soil was found to produce rhamnolipids when cultivated on 2% glycerol, glucose, n-hexadecane, and n-alkanes. The rhamnolipids were partially purified on silica gel columns and their chemical structures elucidated by combination of one- and two-dimensional 1H and 13C NMR techniques and ESI-MS analysis. Eight structural rhamnolipid homologues were identified: Rha-C10-C8, Rha-C10-C10, Rha-C10-C12:1, Rha-C10-C12, Rha2-C10-C8, Rha2-C10-C10, Rha2-C10-C12:1, and Rha2-C10-C12. The chemical composition of the rhamnolipid mixtures produced on different carbon sources did not vary with the type of carbon source used. The rhamnolipid mixture produced by Pseudomonas aeruginosa BN10 on glycerol reduced the surface tension of pure water from 72 to 29 mN m(-1) at a critical micellar concentration of 40 mg 1(-1), and the interfacial tension was 0.9 mN m(-1). The new surfactant product formed stable emulsions with hydrocarbons and showed high antimicrobial activity against Gram-positive bacteria. The present study shows that the new strain Pseudomonas aeruginosa BN10 demonstrates enhanced production of the di-rhamnolipid Rha2-C10-C10 on all carbon sources used. Due to its excellent surface and good antimicrobial activities the rhamnolipid homologue mixture from Pseudomonas aeruginosa BN10 can be exploited for use in bioremediation, petroleum and pharmaceutical industries.     

Structural characterization of rhamnolipid produced by Pseudonomas aeruginosa strain FIN2 isolated from oil reservoir water

Biosurfactant-producing microorganisms inhabiting oil reservoirs are of great potential in industrial applications. Yet, till now, the knowledge about the structure and physicochemical property of their metabolites are still limited. The aim of this study was to purify and structurally characterize the biosurfactant from Pseudomonas aeruginosa strain FIN2, a newly isolated strain from an oil reservoir. The purification was conducted by silica gel column chromatography followed by pre-RP HPLC and the structural characterization was carried out by GC–MS combined with MS/MS. The results show that the biosurfactant produced by FIN2 is rhamnolipid in nature and its four main fractions were identified to be Rha-C10-C10(46.1 %), Rha–Rha-C10-C10(20.1 %), Rha-C8-C10 (7.5 %) and Rha-C10-C12:1(5.5 %), respectively. Meanwhile, the rarely reported rhamnolipid congeners containing β-hydroxy fatty acids of C6, C9, C10:1 and C11 were also proved to be present in the rhamnolipid mixture produced. The rhamnolipid mixture exhibited a strong surface activity by lowering the surface tension of distilled water to 28.6 mN/m with a CMC value of 195 mg/l.     

Rhamnolipid biosurfactant production by strains of Pseudomonas aeruginosa using low-cost raw materials

This study was aimed at the development of economical methods for higher yields of biosurfactant by suggesting the use of low-cost raw materials. Two oil-degrading strains, Pseudomonas aeruginosa GS9-119 and DS10-129, were used to optimize a substrate for maximum rhamnolipid production. Among the two strains, the latter produced maxima of 4.31, 2.98, and 1.77 g/L rhamnolipid biosurfactant using soybean oil, safflower oil, and glycerol, respectively. The yield of biosurfactant steadily increased even after the bacterial cultures reached the stationary phase of growth. Characterization of rhamnolipids using mass spectrometry revealed the presence of dirhamnolipids (Rha-Rha-C(10)-C(10)). Emulsification activity of the rhamnolipid biosurfactant produced by P. aeruginosa DS10-129 was greater than 70% using all the hydrocarbons tested, including xylene, benzene, hexane, crude oil, kerosene, gasoline, and diesel. P. aeruginosa GS9-119 emulsified only hexane and kerosene to that level.     

Marine actinomycete Streptomyces sp. ISP2-49E,a new source of Rhamnolipid

Marine derived actinomycetes were isolated from sediment samples of Galveston Bay, Texas and screened for production of bioactive metabolites. Streptomyces sp. ISP2-49E, identified by 16s rDNA, produced a previously described Rha-Rha-C10-C10 rhamnolipid; however, this is the first report of a rhamnolipid produced by a Streptomyces sp. This organism was isolated from hydrocarbon contaminated sediment and further supports the trend of rhamnolipid production as a potential adaptation to this environment.     

Microbial synthesis of rhamnolipids by Pseudomonas aeruginosa (ATCC 10145) on waste frying oil as low cost carbon source

Vegetable edible oils and fats are mainly used for frying purposes in households and the food industry. The oil undergoes degradation during frying and hence has to be replaced from time to time. Rhamnolipids are produced by microbial cultivation using refined vegetable oils as a carbon source and Pseudomonas aeruginosa (ATCC 10145). The raw material cost accounts for 10-30% of the overall cost of biosurfactant production and can be reduced by using low-cost substrates. In this research, attention was focused on the preparation of rhamnolipids, which are biosurfactants, using potential frying edible oils as a carbon source via a microbial fermentation technique. The use of low-cost substrates as a carbon source was emphasized to tilt the cost of production for rhamnolipids. The yield was 2.8 g/L and 7.5 g/L from waste frying oil before and after activated earth treatment, respectively. The crude product contained mainly dirhamnolipids, confirmed by thin-layer chromatography (TLC), high-performance liquid chromatography (HPLC), liquid chromatography-mass spectroscopy (LC-MS), and (1)H-nuclear magnetic resonance (NMR). Hence, the treatment can be used to convert waste frying oil as a low-cost substrate into a cost-effective carbon source.     

MICROBIAL SYNTHESIS OF RHAMNOLIPIDS BY Pseudomonas aeruginosa (ATCC 10145) ON WASTE FRYING OIL AS LOW COST CARBON SOURCE

Vegetable edible oils and fats are mainly used for frying purposes in households and the food industry. The oil undergoes degradation during frying and hence has to be replaced from time to time. Rhamnolipids are produced by microbial cultivation using refined vegetable oils as a carbon source and Pseudomonas aeruginosa (ATCC 10145). The raw material cost accounts for 10–30% of the overall cost of biosurfactant production and can be reduced by using low-cost substrates. In this research, attention was focused on the preparation of rhamnolipids, which are biosurfactants, using potential frying edible oils as a carbon source via a microbial fermentation technique. The use of low-cost substrates as a carbon source was emphasized to tilt the cost of production for rhamnolipids. The yield was 2.8 g/L and 7.5 g/L from waste frying oil before and after activated earth treatment, respectively. The crude product contained mainly dirhamnolipids, confirmed by thin-layer chromatography (TLC), high-performance liquid chromatography (HPLC), liquid chromatography–mass spectroscopy (LC-MS), and ¹H-nuclear magnetic resonance (NMR). Hence, the treatment can be used to convert waste frying oil as a low-cost substrate into a cost-effective carbon source.     

Chemical structures and biological activities of rhamnolipids produced by Pseudomonas aeruginosa B189 isolated from milk factory waste

The aim of this work was to study chemical structures and biological activities of rhamnolipids produced by Pseudomonas aeruginosa B189 isolated from milk factory waste. The culture produced two biosurfactants, a and b, which showed strong activity and were identified as L-rhamnopyranosyl-L-rhamnopyranosyl-beta-hydroxydecanoyl-beta-hydroxydecanoate or Rha-Rha-C10-C10 and L-rhamnopyranosyl-L-rhamnopyranosyl-beta-hydroxydecanoyl-beta-hydroxydodecanoate or Rha-Rha-C10-C12, respectively. Both compounds exhibited higher surfactant activities tested by the drop collapse test than several artificial surfactants such as SDS and Tween 80. Rhamnolipid a showed significant antiproliferative activity against human breast cancer cell line (MCF-7) at minimum inhibitory concentration (MIC) at 6.25 microg/mL while rhamnolipid b showed MIC against insect cell line C6/36 at 50 microg/mL.     

Effect of nutritional and environmental conditions on the production and composition of rhamnolipids by P. aeruginosa UG2

The production of rhamnolipid biosurfactants by P. aeruginosa UG2 was examined under different culture conditions. Rhamnolipid yield was affected by the nature of the carbon sources, the nutrient concentrations, pH, and age of the culture. Hydrophobic substrates like corn oil, lard (rich in unsaturated and saturated fat), and long chain alcohols maximized biosurfactant production (100-165 mg/g substrate). Hydrophilic substrates like glucose, and succinic acid delivered poor yields (12-36 mg/g substrate). Rhamnolipid production was greater when N as (NH4)(2)SO4 and trace metals were added in several periodic doses rather than at the beginning of the process. Increased biosurfactant production was seen in cultures maintained at neutral pH relative to cultures allowed to develop acidic conditions (pH = 6.25). Although the level of rhamnolipid production was affected by culture conditions, the distribution of rhamnolipid subspecies did not vary between cultures. A dirhamnolipid species containing two 10 carbon alpha-hydroxy fatty acids [Rh2C10C10] was the most abundant in the mixtures (60.6 mol%), while the levels of the monorhamnolipid [RhC10C10] (20.7 mol%) and two dirhamnolipids [Rh2C10C12 and its dehydro variant Rh2C10C12-H2] (18.7 mol%) were similar. Biosurfactant mixtures produced with corn oil as sole carbon source solubilized the herbicide trifluralin [2,6-dinitro-N,N-dipropyl-4-(trifluoromethyl)benzamine] to a greater extent. This suggests that the presence of incompletely metabolized hydrophobic by-products acting as co-solvents can increase the solubilization capacity of biosurfactant mixtures.