生物表面活性剂产生菌的筛选及表面活性剂稳定性研究

大庆油田油泥样品经富集培养,平板分离,获得52株菌。排油性实验和表面张力测定表明,菌株B22、B24、B2s产生的表面活性剂表面活性稳定,表面张力较低。温度、pH和NaCl浓度实验证实,细菌B22,产生的生物表面活性剂可耐受120℃高温,另2种生物表面活性剂可耐受80℃;3种细菌生物表面活性剂对pH有广泛适应性,1322pH适应范围为4．0～13．0,B24、B25的pH适应范围为2．0～13．0;NaCl浓度对表面活性剂的生物活性影响不大。将3株菌的生物表面活性剂用于室内油泥处理实验,72h石油去除率达70％以上。     

有机农药活性污泥中表面活性剂产生菌的筛选及鉴定

目的:筛选表面活性剂产生菌,用于降解有机农药,提高氧化塘处理效率.方法:以液体石蜡为惟一碳源进行选择性培养,通过测定发酵液的排油活性和表面张力,对有机农药厂的活性污泥进行产生物表面活性剂细菌筛选,并对筛得的细菌进行形态学、生理生化及 16SrDNA 试验和鉴定.结果:筛选出 3 株产生物表面活性剂的细菌,经鉴定均属于不动杆菌属.结论:证实了有机农药活性污泥中存在表面活性剂的产生菌,对有机农药降解存在助溶作用.     

南海冷泉区深海沉积物中细菌的分离培养及多样性分析

为了认识南海深海冷泉区沉积物中可培养微生物的多样性,本文以冷泉区与非冷泉区两个站点的深海沉积物为样品,通过两种培养基(R2A海水培养基和2216E培养基)直接涂布或富集后平板分离纯化,从9个样品中共得到395株菌株,并通过16SrRNA基因鉴定,分属10个属。发现产芽胞细菌分布最广、丰度最大,包括3个属、15个种。其中芽胞杆菌(Bacillus)无论是在数量还是在种类上都分布最多。并且,随着水深和沉积物深度的增加,分离到的可培养微生物丰富度降低。本研究表明,即使在冷泉区,南海深海沉积物中产芽胞细菌也比较丰富。     

南海南沙海域沉积物中可培养微生物及其多样性分析

【目的】为了从南沙海域中分离获得微生物菌种资源，【方法】本文通过沉积物采样、可培养菌分离及16S rRNA鉴定，【结果】从22个站点的沉积物样品中获得349株细菌，分属于87个种。发现产芽孢细菌分布最广，并在10个站点的分离株中占多数；它们是Bacillus，Halobacillus，Brevibacillus，Paenibacillus，Pontibacillus和Thalassobacillus。其中芽孢杆菌（Bacillus）无论在数量上还是种类上都最多，分别属于34种，其中有8个可能的新种。此外，g-Proteobacteria是分离率较高的另一亚群；其中，假单胞菌（Pseudomonas），海杆菌（Marinobacter），食烷菌（Alcanivorax）属的细菌最多。统计还发现，在深度750~2000 m之间，低GC含量的细菌最丰富，而深度2000 m以下，分离株则全部为g-Proteobacteria。【结论】南沙沉积物可培养微生物中产芽孢细菌及 g-Proteobacteria比较丰富；其中，产芽孢细菌的多样性最高，具有进一步研究开发价值。     

一株糖脂表面活性剂产生菌的筛选及干酪根降解

【目的】从油页岩环境中筛选可降解油页岩干酪根的产生物表面活性剂菌株。【方法】从抚顺油页岩矿废水样品中用血平板法初筛,排油圈法、乳化法和表面张力法复筛,获得产生物表面活性剂菌株。对目标菌株进行生理生化鉴定、16S r RNA基因序列和系统发育分析,用薄层色谱鉴定其发酵液表面活性成分,优化产表面活性剂的培养条件,初步考察其对油页岩干酪根的降解能力。【结果】筛选到一株产糖脂表面活性剂菌株B-1,初步鉴定为Pseudomonas sp.,该菌株有良好的排油和乳化能力以及较低的表面张力,可利用烷烃、不饱和脂肪酸和糖类作为碳源。在30-34°C范围内添加0.3%Na Cl的葡萄糖培养基(p H 7.0)中该菌生长旺盛,发酵液表面张力最低为27 m N/m。菌株B-1在添加一定量葡萄糖的无机盐培养基中作用30 d后对干酪根的降解率为2.85%,高于不添加葡萄糖无机盐培养基对照组的降解率(1.04%)。【结论】菌株B-1是一株性能良好的产糖脂表面活性剂细菌,有降解干酪根的潜力。     

一株产脂肽类表面活性剂的碱性Dietzia菌及特性研究

【目的】筛选降解性能良好的产生物表面活性剂的菌株,对其进行分类学鉴定,确定所产表面活性剂物质并对各影响因素进行评价。【方法】利用液体石蜡为底物筛选降解性能良好的产生物表面活性剂菌株,通过形态特征观察、生理生化测定、16S rRNA基因序列分析等实验确定菌株的分类地位。通过排油圈活性、表面张力值、薄层层析等方法确定生物表面活性剂的性质,分析碳、氮源和温度、pH、盐浓度各因素对菌株产生物表面活性剂的影响。【结果】从大连新港采集的样品中分离得到一株产表面活性剂的嗜碱菌株3372,经分类鉴定表明其是Dietzia cercidiphylli的新菌株。嗜碱菌3372发酵液粗提物的排油直径为6.1 cm,表面张力可从67.62 mN/m降到32.95 mN/m,经薄层层析分析,初步鉴定为脂肽类表面活性剂。综合各因素对发酵液表面活性的影响,菌株3372在pH为9.0、适盐浓度为3%的培养基中,经30°C培养可将发酵液表面张力值降到最低。【结论】嗜碱菌3372是脂肽类生物表面活性剂产生菌的新成员,其在高盐碱条件下产生表面活性剂的特性在工业应用上有一定的潜力。     

红树林沉积物中天然多聚有机物厌氧降解菌多样性与细菌新类群分离

[目的]红树林沉积物中有机物丰富,通过研究认识参与难降解天然有机多聚物的微生物降解过程及其环境作用,并获得新颖的难培养厌氧微生物。[方法]对漳州九龙江河口红树林沉积物中降解纤维素、几丁质和木质素的厌氧细菌定向富集和平板分离纯化,并对其多样性进行分析。[结果]共筛选分离获得202株厌氧细菌(82株专性厌氧细菌,120株兼性厌氧细菌),包括4个疑似新属(Lachnotalea sp.MCCC 1A16036、Varunaivibrio sp.MCCC 1A15903、Clostridium sp.MCCC 1A15884、Caminicella sp.MCCC 1A17445)和4个疑似新种(Sunxiuqinia sp.MCCC 1A15904、Pseudodesulfovibrio sp.MCCC 1A16040、Pseudodesulfovibrio sp.MCCC 1A16038、Mangrovibacterium lignilyticum MCCC1A15882)。不同天然有机多聚物富集菌群分离到的优势可培养细菌主要属于变形菌门、拟杆菌门和厚壁菌门,但种群略有差异。在纤维素和几丁质富集菌群中,变形菌门和拟杆菌门菌株是纤维素和几丁质富集菌群的优势菌群,拟杆菌门的Prolixiacer bellariivorans、Mangrovibacterium lignilyticum和变形菌门的Desulfovibrio salexigenes、Vibrio alginolyticus分别在纤维素和几丁质富集菌群可培养细菌中占绝对优势。但降解实验表明,放线菌门细菌Demequina salsinemoris MCCC 1A15890和Brevibacterium celere MCCC 1A17451对纤维素降解活性最高。梭杆菌门细菌Propionigenium maris MCCC 1A15874和Ilyobacter polytropus MCCC 1A15889对几丁质降解活性最高。在木质素富集菌群中,拟杆菌门的Mangrovibacterium lignilyticum和厚壁菌门的Clostridium amygdalinum都具有较高的相对丰度。变形菌门细菌Desulfomicrobium apsheronum MCCC 1A15932和拟杆菌门细菌Mangrovibacterium lignilyticum MCCC 1A15882对木质素降解效果显著。[结论]红树林沉积物中存在丰富多样且新颖的厌氧难培养细菌,且多数具有纤维素、几丁质或木质素厌氧降解能力。该研究结果为探究红树林沉积物原位环境天然有机多聚物碳的生物地球化学循环机制提供了相关理论基础和纯培养微生物资源。     

长链烷烃降解菌的降解特性

对长链烷烃降解菌的降解能力和摄取模式进行了研究。评价14株烃降解菌利用中长链烃生长的能力,发现只有少数烃降解菌能够获得良好生长,其中Mycobacterium fortuitum514,Pseudomonas aeruginosa1785和Pseudomonas marginata766等3株菌能够高效降解C20到C33的长链烷烃。辛烷不能支持这些长链烷烃降解菌的生长,说明其烃氧化酶与Pseudomonas oleovorans的OCT质粒编码的单氧酶不同。此外,M.fortuitum不产胞外表面活性剂,而P.aeruginosa和P.marginata则是表面活性剂产生菌,然而三者在以烃为碳源生长时均显示出很高的细胞表面疏水性。根据生长现象分析3株菌采用了不同的烷烃摄取模式。     

烟碱降解菌以烷烃为碳源产生物表面活性剂的研究

通过测定发酵过程中菌体浓度和发酵上清液的表面张力,研究了烷烃碳源和发酵条件对烟碱降解菌(Ochrobactrum sp.)产生物表面活性剂的影响。结果表明,菌株Ochrobactrum sp.以十三烷和十六烷为碳源生长较好,而利用液体石蜡可产生较多生物表面活性剂。以2%液体石蜡为碳源,装液量为40%(250 m L三角瓶),于30℃,120 r/min培养4 d时,发酵液表面张力能降低至42.1m N/m。     

印度洋深海沉积物石油烃降解菌分离、鉴定与多样性分析

烃类物质在海洋环境中广泛分布,深海可能含有特殊的烃降解微生物。本研究通过对西南印度洋中脊与印度洋中部深海沉积物中石油降解菌的富集培养和分离鉴定,从6个站点的样品中共分离得到800株菌,通过BOX-PCR去重复菌株后,对其中183株菌进行了16S rRNA基因序列分析,发现这些菌分属于23个属;其中,γ-变形菌纲的食烷菌属(Alcanivorax)和放线菌纲的微杆菌属(Microbacterium)占优势。此外,还发现了食烷菌属2个潜在的新种、假海栖菌属(Pseudooceanicola)1个潜在新种。高通量测序结果证明,富集菌群中γ-变形菌纲是优势菌,主要包括食烷菌属、盐单胞菌属(Halomonas)、海杆菌属(Marinobacter)等。结合可培养菌与高通量测序结果,食烷菌属、盐单胞菌属、海杆菌属、交替假单胞菌(Pseudoalteromonas)、海源菌属(Idiomarina)与微杆菌属(Microbacterium)是沉积物样品中常见的石油烃降解菌,迪茨氏菌属(Dietzia)、红球菌属(Rhodococcus),假单胞菌属(Pseudomonas)、赤杆菌属(Erythrobacter)与副球菌属(Paracoccus)等可能也参与了烃的降解。     

Characterization of bacterial isolates from industrial wastewater according to probable modes of hexadecane uptake

Bacterial isolates from industrial wastewater were characterized according to probable modes of hexadecane uptake based on data for cell surface hydrophobicity, emulsifying activity, glycoside content and surface tension of cell-free culture medium. The results obtained suggested that both modes of biosurfactant-enhanced hexadecane uptake by bacterial strains take place, direct uptake and alkane transfer. The increase in cell surface hydrophobicity and glycoside production by the strains suggested the existence of biosurfactant-enhanced interfacial uptake of the alkane. Such mechanism is probably predominant for three isolates, Staphylococcus sp. HW-2, Streptococcus sp. HW-9 and Bacillus sp. HW-4. Secreted biosurfactants enhanced mainly alkane emulsification for most hydrophobic isolate Arthrobacter sp. HW-8, and micellar transfer for most hydrophilic isolate Streptococcus sp. HW-5. For other strains (67%) both mechanisms of biosurfactant-enhanced hexadecane uptake probably take place in similar degree, interfacial uptake and alkane emulsification. The results obtained could contribute to clarifying the natural relationships between the members of water ecosystem studied as well as will reveal potential producers of surface active compounds.     

Diversity of biosurfactant producing microorganisms isolated from soils contaminated with diesel oil

Biosurfactant production is a desirable property of hydrocarbon-degrading microorganisms (HDM). We characterized biosurfactant producing microbial populations from a Long Beach soil, California (USA) and a Hong Kong soil (China), contaminated with diesel oil. A total of 33 hydrocarbon-utilizing microorganisms were isolated from the soils. Twelve isolates and three defined consortia were tested for biosurfactant production and emulsification activity. The highest reduction of surface tension was achieved with a consortium of L1, L2 and L3 isolates from a Long Beach soil (41.4mN m(-1)). Isolate L1 (Acinetobacter junii) displayed the highest reduction of surface tension (46.5 mN m(-1)). The emulsifying capacity evaluated by the E24 emulsification index was highest in the culture of isolate L5 (74%). No substantial emulsification was achieved with the cell-free extracts, indicating that the emulsifying activity was not extracellular. Based on surface tension and the E24 index results, isolates F1, F2, F3, F4, L1, L2, L3 and L4 were identified by 16S rRNA gene sequencing as Bacillus cereus, Bacillus sphaericus, B. fusiformis, Acinetobacter junii, a non-cultured bacterium, Pseudomonas sp. and B. pumilus, respectively. Cluster analyses of 16S rRNA gene sequences of the bacterial isolates revealed 70% similarity amongst hydrocarbon-degrading bacterial community present in both soils. Five isolates (isolates F1, F2, F3, F4 and L4) belong to the Firmicutes order, two isolates (L1 and L3) belong to the Proteobacteria order and one isolate (L2) is an Actinomyces sp. Simpson's index (1 - D) and the Shannon-Weaver index (H) revealed more diversity of HDM in the Hong Kong soil, while evenness (E) and the equitability (J) data indicated that there was not a dominant population. Bacterial isolates displaying substantial potential for production of biosurfactants can be applied in the bioremediation of soils contaminated with petroleum hydrocarbons.     

Effect of Rhamnolipid (Biosurfactant) Structure on Solubilization and Biodegradation of n-Alkanes

A study to quantify the effect of rhamnolipid biosurfactant structure on the degradation of alkanes by a variety of Pseudomonas isolates was conducted. Two dirhamnolipids were studied, a methyl ester form (dR-Me) and an acid form (dR-A). These rhamnolipids have different properties with respect to interfacial tension, solubility, and charge. For example, the interfacial tension between hexadecane and water was decreased to <0.1 dyne/cm by the dR-Me but was only decreased to 5 dyne/cm by the dR-A. Solubilization and biodegradation of two alkanes in different physical states, liquid and solid, were determined at dirhamnolipid concentrations ranging from 0.01 to 0.1 mM (7 to 70 mg/liter). The dR-Me markedly enhanced hexadecane (liquid) and octadecane (solid) degradation by seven different Pseudomonas strains. For an eighth strain tested, which exhibited extremely high cell surface hydrophobicity, hexadecane degradation was enhanced but octadecane degradation was inhibited. The dR-A also enhanced hexadecane degradation by all degraders but did so more modestly than the dR-Me. For octadecane, the dR-A only enhanced degradation by strains with low cell surface hydrophobicity.     

Bioprospection and selection of bacteria isolated from environments contaminated with petrochemical residues for application in bioremediation

The use of microorganisms with hydrocarbon degrading capability and biosurfactant producers have emerged as an alternative for sustainable treatment of environmental passives. In this study 45 bacteria were isolated from samples contaminated with petrochemical residues, from which 21 were obtained from Landfarming soil contaminated with oily sludge, 11 were obtained from petrochemical industry effluents and 13 were originated directly from oily sludge. The metabolization capability of different carbon sources, growth capacity and tolerance, biosurfactant production and enzymes detection were determined. A preliminary selection carried out through the analysis of capability for degrading hydrocarbons showed that 22% of the isolates were able to degrade all carbon sources employed. On the other hand, in 36% of the isolates, the degradation of the oily sludge started within 18–48 h. Those isolates were considered as the most efficient ones. Twenty isolates, identified based on partial sequencing of the 16S rRNA gene, were pre-selected. These isolates showed ability for growing in a medium containing 1% of oily sludge as the sole carbon source, tolerance in a medium containing up to 30% of oily sludge, ability for biosurfactant production, and expression of enzymes involved in degradation of aliphatic and aromatic compounds. Five bacteria, identified as Stenotrophomonas acidaminiphila BB5, Bacillus megaterium BB6, Bacillus cibi, Pseudomonas aeruginosa, and Bacillus cereus BS20 were shown to be promising for use as inoculum in bioremediation processes (bioaugmentation) of areas contaminated with petrochemical residues since they can use oily sludge as the sole carbon source and produce biosurfactants.     

Emulsification of hydrocarbons by subsurface bacteria

Summary Biosurfactants have potential for use in enhancement of in situ biorestoration by increasing the bioavailability of contaminants. Microorganisms isolated from biostimulated, contaminated and uncontaminated zones at the site of an aviation fuel spill and hydrocarbon-degrading microorganisms isolated from sites contaminated with unleaded gasoline were examined for their abilities to emulsify petroleum hydrocarbons. Emulsifying ability was quantified by a method involving agitation and visual inspection. Biostimulated-zone microbes and hydrocarbon-degrading microorganisms were the best emulsifiers as compared to contaminated and uncontaminated zone microbes. Biostimulation (nutrient and oxygen addition) may have been the dominant factor which selected for and encouraged growth of emulsifiers; exposure to hydrocarbon was also important. Biostimulated microorganisms were better emulsifiers of aviation fuel (the contaminant hydrocarbon) than of heavier hydrocarbon to which they were not previously exposed. By measuring surface tension changes of culture broths, 11 out of 41 emulsifiers tested were identified as possible biosurfactant producers and two isolates produced large surface tension reductions indicating the high probability of biosurfactant production.     

Screening and preliminary characterization of biosurfactants produced by Ochrobactrum sp. 1C and Brevibacterium sp. 7G isolated from hydrocarbon-contaminated soils

Biosurfactant-producing bacteria were isolated from a crude-oil-contaminated soil in Hassi Messaoud (southern Algeria). Isolates were screened for biosurfactant/bioemulsifier production on different carbon sources (glucose, olive oil, and hexadecane) on the basis of their ability to reduce the surface tension. The highest number of positive isolates (19) was obtained on a medium containing hexadecane as carbon source. Culture broth from all 19 isolates emulsified motor oil and 14 exhibited high emulsion-stabilizing capacity, maintaining 50% of the original emulsion volume for 48 h. The cell-free culture broth of the two best-performing isolates (identified as Ochrobactrum sp. 1C and Brevibacterium sp. 7G) reduced the surface tension below 31.5 mN m⁻¹. Biosurfactant produced by strains 1C and 7G exhibited tolerance, with slight variations for heat, pH, and salinity, and based on spectral features, they were glycolipids. Furthermore, they exhibited antimicrobial activities against Pseudomonas aeruginosa and Staphylococcus aureus.     

The Effect of Rhamnolipid Biosurfactant Produced by <Emphasis Type="Italic">Pseudomonas fluorescens</Emphasis> on Model Bacterial Strains and Isolates from Industrial Wastewater

In this study, the effect of rhamnolipid biosurfactant produced by Pseudomonas fluorescens on bacterial strains, laboratory strains, and isolates from industrial wastewater was investigated. It was shown that biosurfactant, depending on the concentration, has a neutral or detrimental effect on the growth and protein release of model Gram (+) strain Bacillus subtilis 168. The growth and protein release of model Gram (−) strain Pseudomonas aeruginosa 1390 was not influenced by the presence of biosurfactant in the medium. Rhamnolipid biosurfactant at the used concentrations supported the growth of some slow growing on hexadecane bacterial isolates, members of the microbial community. Changes in cell surface hydrophobicity and permeability of some Gram (+) and Gram (−) isolates in the presence of rhamnolipid biosurfactant were followed in experiments in vitro. It was found that bacterial cells treated with biosurfactant became more or less hydrophobic than untreated cells depending on individual characteristics and abilities of the strains. For all treated strains, an increase in the amount of released protein was observed with increasing the amount of biosurfactant, probably due to increased cell permeability as a result of changes in the organization of cell surface structures. The results obtained could contribute to clarify the relationships between members of the microbial community as well as suggest the efficiency of surface properties of rhamnolipid biosurfactant from Pseudomonas fluorescens making it potentially applicable in bioremediation of hydrocarbon-polluted environments.     

The Potential of Bacterial Isolates for Emulsification with a Range of Hydrocarbons

A study was undertaken to investigate the distribution of biosurfactant producing and crude oil degrading bacteria in the oil contaminated environment. This research revealed that hydrocarbon contaminated sites are the potent sources for oil degraders. Among 32 oil degrading bacteria isolated from ten different oil contaminated sites of gasoline and diesel fuel stations, 80% exhibited biosurfactant production. The quantity and emulsification activity of the biosurfactants varied. Pseudomonas sp. DS10‐129 produced a maximum of 7.5 ± 0.4 g/l of biosurfactant with a corresponding reduction in surface tension from 68 mN/m to 29.4 ± 0.7 mN/m at 84 h incubation. The isolates Micrococcus sp. GS2‐22, Bacillus sp. DS6‐86, Corynebacterium sp. GS5‐66, Flavobacterium sp. DS5‐73, Pseudomonas sp. DS10‐129, Pseudomonas sp. DS9‐119 and Acinetobacter sp. DS5‐74 emulsified xylene, benzene, n‐hexane, Bombay High crude oil, kerosene, gasoline, diesel fuel and olive oil. The first five of the above isolates had the highest emulsification activity and crude oil degradation ability and were selected for the preparation of a mixed bacterial consortium, which was also an efficient biosurfactant producing oil emulsifying and degrading culture. During this study, biosurfactant production and emulsification activity were detected in Moraxella sp., Flavobacterium sp. and in a mixed bacterial consortium, which have not been reported before.     

Biosurfactant production and hydrocarbon-degradation by halotolerant and thermotolerant Pseudomonas sp.

A hydrocarbon degrading and biosurfactant producing, strain DHT2, was isolated from oil-contaminated soil. The organism grew and produced biosurfactant when cultured in variety of substrates at salinities up to 6 g l⁻¹ and temperatures up to 45°C. It was capable of utilizing crude oil, fuels, alkanes and PAHs as carbon source across the wide range of temperature (30–45°C) and salinity (0–6%). Over the range evaluated, the salinity and temperature did not influence the degradation of hydrocarbon and biosurfactant productions. Isolate DHT2 was identified as Pseudomonas aeruginosa by analysis of 16S rRNA sequences (100% homology) and biochemical analysis. PCR and DNA hybridization studies revealed that enzymes involved in PAH metabolism were related to the naphthalene dioxygenase pathway. Observation of both tensio-active and emulsifying activities indicated that biosurfactants were produced by DHT2 during growth on both, water miscible and immiscible substrates, including PAH. The biosurfactants lowered the surface tension of medium from 54.9 to 30.2 dN/cm and formed a stable emulsion. The biosurfactant produced by the organism emulsified a range of hydrocarbons with hexadecane as best substrate and toluene was the poorest. These findings further indicate that the isolate could be useful for bioremediation and bio-refining application in petroleum industry.     

Co-Utilization of Canola Oil and Glucose on the Production of a Surfactant by <Emphasis Type="Italic">Candida lipolytica</Emphasis>

Candida lipolytica synthesized a surfactant in a cultivation medium supplemented with canola oil and glucose as carbon sources. Measurements of biosurfactant production and surface tension indicated that the biosurfactant was produced at 48 h of fermentation. The surface-active species is constituted by the protein–lipid–polysaccharide complex in nature. The cell-free broth was particularly influenced by the addition of salt, the pH and temperature depending on the emulsified substrate (hexadecane or a vegetable oil). After comparison between ethyl acetate and mixtures of chloroform and methanol as solvent systems for surfactant recovery, it was found that ethyl acetate was able to extract crude surfactant material with high product recovery (8.0 g/L). The isolated biosurfactant decreased the surface tension to values of 30 mN/m at the critical micelle concentration. Emulsification properties of the biosurfactant produced were compared to those of commercial emulsifiers and other microbial surfactants.