一株原油降解菌的分离鉴定及降解特性研究

[目的]对从大连湾原油污染海域生长的海绵中分离的原油降解菌2-9进行鉴定及降解特性研究.[方法]采用16S rRNA基因序列同源性分析、生理生化指标测定、DNAG+C含量测定、全细胞脂肪酸组成测定、碳源利用实验等多种方法对该菌株进行鉴定,并通过降解实验测定其对原油的降解情况.[结果]菌株2-9鉴定为Nitratireductor basaltis,革兰氏阴性,接触酶和氧化酶阳性.在GenBank中与其16S rRNA基因序列相似度最高的模式株为Nitratireductor basaltis J3T,相似性为99％.可生长的pH范围为6.0-10.0,最适生长pH值为8.0;可生长温度范围为15℃-42℃,最适生长温度为30℃; NaCl浓度生长范围是0-8％(W/V),最适生长盐度为2％.该菌株可以利用多种糖和有机酸的碳源,其DNA G+C含量为57.29 mol％,主要脂肪酸组成为ω7c-十八碳单不饱和脂肪酸(63.61％)、ω8c型环式十九碳饱和脂肪酸(16.97％)、饱和十八碳脂肪酸(4.28％)和十六碳饱和脂肪酸(3.39％).同时,考察了该菌株对原油的降解效果,在人工海水培养基中,14d内对原油(初始浓度为1 g/L)的平均降解率为63.5％.[结论]菌株2-9是一株具有开发潜力的原油降解菌.     

Intensification of microbial degradation of crude oil and oil products in the presence of perfluorodecalin

The possibility of using perfluorinated organic compounds for growing microorganisms and degrading xenobiotics has been demonstrated for the first time with perfluorodecalin (PFD), a gas-transporting component of the blood substitute Perftoran. In particular, this is promising for intensifying microbial degradation of oil and oil products and production of biodegrader biomass in synthetic mineral media. Addition of PFD to a mineral medium with crude oil and masut increased 4.5-10.2 times maximum concentrations and growth rates of all bacterial strains under study (Pseudomonas, Rhodococcus, and Bacillus genera). The degree of oil product consumption was increased 8.7-12.7 times.     

Low-temperature microbial degradation of crude oil products differing in the extent of condensation

Out of the 30 strains capable of oil degradation at 4-6 degrees C, four were selected by the ability to degrade 40% of the oil substrate present in the growth medium: Rhodococcus spp. DS-07 and DS-21 and Pseudomonas spp. DS-09 and DS-22. We studied the activity of these strains as degraders of oil products of various condensation degrees (crude oil, masut, petroleum oils, benzene resins and ethanol-benzene resins) at 4-6 degrees C. The maximum degrees of degradation of masut and ethanol-benzene resins were observed in Pseudomonas spp. DS-22 (17.2% and 5.2%, respectively). The maximum degradation of petroleum oils and benzene resins was observed in Rhodococcus spp. DS-07 (40% and 16.6%, respectively). The strains provide a basis for developing biodegrader preparations applicable to bioremediation of oil-polluted sites under the conditions of cold climate.     

高效石油降解菌群的构建及对芳香烃化合物萘的协同降解性能

【背景】石油作为一类混杂有机化合物,一旦产生污染就会对人类和环境造成严重的危害。【目的】从新疆石油污染土壤中分离筛选石油降解菌,为石油污染土壤的生物修复提供数据支持及技术参考。【方法】以石油为唯一碳源,通过富集培养、筛选分离得到123株单菌,根据菌落形态挑选出30个不同形态菌株,通过16S rRNA基因序列确定其种属,构建系统发育树;通过原油降解实验筛选出高效石油降解菌,以芳香烃的标志化合物萘为唯一碳源筛选出高效降解菌株,并分别筛选可降解水杨酸、邻苯二酚的菌株。【结果】分离筛选出5株高效石油降解菌,降解率高于85%;萘、水杨酸和邻苯二酚降解菌株各获得一株,将3种菌株按照1:1:1的接种比例对萘进行降解,萘的降解率从单菌60.74%提升到89.40%,菌株间的分工协作可以提高有机物的降解效率。【结论】筛选得到的菌株丰富了石油降解微生物菌种库,不同微生物菌株之间的分工协作为石油污染物的降解提供了新思路,为进一步研究石油污染治理提供参考。     

Biodeterioration of crude oil and oil derived products: a review

Biodeterioration of crude oil and oil fuels is a serious economic and an environmental problem all over the world. It is impossible to prevent penetration of microorganisms in oil and fuels both stored in tanks or in oilfields after drilling. Both aerobic and anaerobic microorganisms tend to colonise oil pipelines and oil and fuel storage installations. Complex microbial communities consisting of both hydrocarbon oxidizing microorganisms and bacteria using the metabolites of the former form an ecological niche where they thrive. The accumulation of water at the bottom of storage tanks and in oil pipelines is a primary prerequisite for development of microorganisms in fuels and oil and their subsequent biological fouling. Ability of microorganisms to grow both in a water phase and on inter-phase of water/hydrocarbon as well as the generation of products of their metabolism worsen the physical and chemical properties of oils and fuels. This activity also increases the amount of suspended solids, leads to the formation of slimes and creates a variety of operational problems. Nowadays various test-systems are utilized for microbial monitoring in crude oils and fuels; thus allowing an express determination of both the species and the quantities of microorganisms present. To suppress microbial growth in oils and fuels, both physico-mechanical and chemical methods are applied. Among chemical methods, the preference is given to substances such as biocides, additives, the anti-freezing agents etc that do not deteriorate the quality of oil and fuels and are environmentally friendly. This review is devoted to the analysis of the present knowledge in the field of microbial fouling of crude oils and oil products. The methods utilized for monitoring of microbial contamination and prevention of their undesirable activities are also evaluated. The special focus is given to Russian scientific literature devoted to crude oil and oil products biodeterioration.     

石油降解细菌的表型特性和系统发育分析

从3种不同土壤中分离和纯化得到10个石油降解细菌菌株,分离菌株均为好氧菌、革兰氏阴性菌、不形成芽孢的杆菌,10个菌株均能利用中等链长的烷烃、柴油和原油作为碳源,而不能以单环芳烃和多环芳烃为碳源。根据其生理生化性状和16SrDNA序列分析结果表明,分离菌株EVA5,EVA6,EVA7,EVA8和EVA9为假单胞菌（Pseudomonas spp.）,EVA10、EVA11、EVA12、EVA13和EVA14为不动杆菌（Acinetobacter spp.）,均属于Proteobac-teria的γ亚群。     

Monitoring of alkane-degrading bacteria in a sea-water microcosm during crude oil degradation by polymerase chain reaction based on alkane-catabolic genes

Behaviour of microbial populations responsible for degrading n-alkanes, a major component of crude oil, was monitored during crude oil degradation in a sea-water microcosm by both traditional colony culturing and molecular techniques. A DNA extraction method applicable to crude oil-amended sea-water samples was developed to obtain DNA applicable to most probable number (MPN) polymerase chain reaction (PCR). The population of alkane-degrading bacteria responsible for degradation of n-alkanes in a crude oil-amended microcosm altered, so that shorter alkanes were degraded first by alkane-degrading bacteria possessing alkane hydroxylase genes from group I (Kohno et al., 2002, Microb Environ 17: 114-121) and longer ones afterwards by those possessing alkane hydroxylase genes from group II. Thus, the degradation mechanism of the n-alkanes can be clarified during crude oil degradation. Application of the method of detecting different types of alkane-catabolic genes, as shown in the present study, enabled bacterial groups preferring alkanes of either shorter or longer chain lengths to be enumerated selectively.     

Changes in mutagenicity during crude oil degradation by fungi

Two fungal strains, Cunninghamella elegans and Penicillium zonatum, that grow with crude oil as a sole carbon source were exposed to three crude oils that exhibit a range of mutagenic activity. At regular time intervals following fungal incubation with the various crude oils, extracts were tested for the presence of mutagenic activity using the spiral Salmonella assay. When the most mutagenic of the oils, Pennsylvania crude oil, was degraded by C. elegans or by P. zonatum, its mutagenicity was significantly reduced; corresponding uninoculated (weathered) controls of Pennsylvania crude remained mutagenic. West Texas Sour crude oil, a moderately mutagenic oil, exhibited little change in mutagenicity when incubated with either C. elegans or P. zonatum. Swanson River Field crude oil from Cook Inlet, Alaska is a slightly mutagenic oil that became more mutagenic when incubated with C. elegans; weathered controls of this oil showed little change in mutagenicity. Mycelial mat weights measured during growth on crude oils increased corresponding to the biodegradation of about 25% of the crude oil.     

Hydrocarbon emulsification and enhanced crude oil degradation by lauroyl glucose ester

Enzymatically synthesized lauroyl glucose emulsified different hydrophobic substrates when assayed spectrophotometrically. Stable emulsions were formed with triglycerides as well as with hydrocarbons. There was a linear relation between the concentration of lauroyl glucose (50-450 microg) and emulsification activity under the assay conditions when tested with aromatic and aliphatic hydrocarbons. This sugar ester was able to emulsify the aromatic hydrocarbons benzene, toluene and xylene. Long chain alkanes (n-decane and n-hexadecane) as well as brominated long chain alkanes (1-bromodecane and 1-bromohexadecane) were efficiently emulsified. The effect of lauroyl glucose ester on degradation of crude oil by a known oil-degrading Rhodococcus species was also investigated. The culture showed enhanced degradation of crude oil when lauroyl glucose ester was used as an emulsifier. It degraded 70% of the aliphatic fraction of Bombay High crude oil in the presence of the sugar ester at a concentration of 200mg l(-1) as compared to 50% without the emulsifier.     

Towards efficient crude oil degradation by a mixed bacterial consortium

A laboratory study was undertaken to assess the optimal conditions for biodegradation of Bombay High (BH) crude oil. Among 130 oil degrading bacterial cultures isolated from oil contaminated soil samples, Micrococcus sp. GS2-22, Corynebacterium sp. GS5-66, Flavobacterium sp. DS5-73, Bacillus sp. DS6-86 and Pseudomonas sp. DS10-129 were selected for the study based on the efficiency of crude oil utilisation. A mixed bacterial consortium prepared using the above strains was also used. Individual bacterial cultures showed less growth and degradation than did the mixed bacterial consortium. At 1% crude oil concentration, the mixed bacterial consortium degraded a maximum of 78% of BH crude oil. This was followed by 66% by Pseudomonas sp. DS10-129, 59% by Bacillus sp. DS6-86, 49% by Micrococcus sp. GS2-22, 43% by Corynebacterium sp. GS5-66 and 41% by Flavobacterium sp. DS5-73. The percentage of degradation by the mixed bacterial consortium decreased from 78% to 52% as the concentration of crude oil was increased from 1% to 10%. Temperature of 30 degrees C and pH 7.5 were found to be optima for maximum biodegradation.     

Variability in Pseudomonas aeruginosa lipopolysaccharide expression during crude oil degradation

Bacterial utilization of crude oil components, such as the n-alkanes, requires complex cell surface adaptation to allow adherence to oil. To better understand microbial cell surface adaptation to growth on crude oil, the cell surface characteristics of two Pseudomonas aeruginosa strains, U1 and U3, both isolated from the same crude oil-degrading microbial community enriched on Bonny Light crude oil (BLC), were compared. Analysis of growth rates demonstrated an increased lag time for U1 cells compared to U3 cells. Amendment with EDTA inhibited U1 and U3 growth and degradation of the n-alkane component of BLC, suggesting a link between cell surface structure and crude oil degradation. U1 cells demonstrated a smooth-to-rough colony morphology transition when grown on BLC, while U3 cells exhibited rough colony morphology at the outset. Combining high-resolution atomic force microscopy of the cell surface and sodium dodecyl sulfate-polyacrylamide gel electrophoresis of extracted lipopolysaccharides (LPS), we demonstrate that isolates grown on BLC have reduced O-antigen expression compared with that of glucose-grown cells. The loss of O-antigen resulted in shorter LPS molecules, increased cell surface hydrophobicity, and increased n-alkane degradation.     

Extracellular polysaccharides of Rhodococcus rhodochrous S-2 stimulate the degradation of aromatic components in crude oil by indigenous marine bacteria

Rhodococcus rhodochrous S-2 produces extracellular polysaccharides (S-2 EPS) containing D-glucose, D-galactose, D-mannose, D-glucuronic acid, and lipids, which is important to the tolerance of this strain to an aromatic fraction of (AF) Arabian light crude oil (N. Iwabuchi, N. Sunairi, H. Anzai, M. Nakajima, and S. Harayama, Appl. Environ. Microbiol. 66:5073-5077, 2000). In the present study, we examined the effects of S-2 EPS on the growth of indigenous marine bacteria on AF. Indigenous bacteria did not grow significantly in seawater containing AF even when nitrogen, phosphorus, and iron nutrients were supplemented. The addition of S-2 EPS to seawater containing nutrients and AF resulted in the emulsification of AF, promotion of the growth of indigenous bacteria, and enhancement of the degradation of AF by the bacteria. PCR-denaturing gradient gel electrophoresis analyses show that addition of S-2 EPS to the seawater containing nutrients and AF changed the composition of the bacterial populations in the seawater and that bacteria closely related to the genus Cycloclasticus became the major population. These results suggest that Cycloclasticus was responsible for the degradation of hydrocarbons in AF. The effects of 15 synthetic surfactants on the degradation of AF by indigenous marine bacteria were also examined, but enhancement of the degradation of AF was not significant. S-2 EPS was hence the most effective of the surfactants tested in promoting the biodegradation of AF and may thus be an attractive agent to use in the bioremediation of oil-contaminated marine environments.     

Production and partial characterization of biosurfactant produced by crude oil degrading bacteria

Production of biosurfactant by crude oil degrading bacteria for use in microbial enhanced oil recovery was investigated. Crude oil utilizing bacteria were isolated from soil by enrichment method on oil agar at 30 °C for 5 days. The isolates were identified and screened for biosurfactant production using blood haemolysis and emulsification tests. IR and GC–MS analyses were carried out to detect the type of biosurfactant. The biosurfactant was purified and its stability at various pH, temperature and salinity levels was studied. The organisms were identified as: Achromobacter xylosoxidans subspecies xylosoxidans, Bacillus licheniformis, Proteus vulgaris, Proteus mirabilis, Serratia marcescens, Sphingomonas paucimobilis and Micrococcus kristinae. Emulsification test (E₂₄) revealed that Serratia marcescens had the highest emulsification index of 87%. GC–MS indicated the biosurfactants as lipopeptides. The biosurfactant can be used in EOR under various environmental conditions.     

Microbial degradation of crude oil in sea water in continuous culture

Summary The degradation of crude oil in continuous culture of a mixed bacteria population has been studied. The degradation percentage reaches 83 % with a 0.05 h^-1 dilution rate and a 6 g 1^-1 crude oil concentration. The different crude oil compounds : saturated, aromatic, polar hydrocarbons and asphaltenes are degraded at 97 %, 81 %, 52 % and 74 % respectively.     

Effect of photosynthetic bacteria and compost on degradation of petroleum products in soil

Addition of diesel fuel and waste engine oil to soil was found to cause biostimulation of hydrocarbon-oxidizing microorganisms. Corynebacteria constitute a large group of hydrocarbon-oxidizing microorganisms. Addition of a liquid culture of photosynthetic bacteria to soil not only facilitates degradation of petroleum products, but also stimulates growth of hydrocarbon-oxidizing microorganisms. Combined addition of photosynthetic bacteria and compost to soil polluted with petroleum products causes even a more significant increase in the count of hydrocarbon-oxidizing bacteria and substantially increases the rate of pollutant degradation.     

Efficacy of intervention strategies for bioremediation of crude oil in marine systems and effects on indigenous hydrocarbonoclastic bacteria

There is little information on how different strategies for the bioremediation of marine oil spills influence the key indigenous hydrocarbon-degrading bacteria (hydrocarbonoclastic bacteria, HCB), and hence their remediation efficacy. Therefore, we have used quantitative polymerase chain reaction to analyse changes in concentrations of HCB in response to intervention strategies applied to experimental microcosms. Biostimulation with nutrients (N and P) produced no measurable increase in either biodegradation or concentration of HCB within the first 5 days, but after 15 days there was a significant increase (29%; P < 0.05) in degradation of n-alkanes, and an increase of one order of magnitude in concentration of Thalassolituus (to 10(7) cells ml(-1)). Rhamnolipid bioemulsifier additions alone had little effect on biodegradation, but, in combination with nutrient additions, provoked a significant increase: 59% (P < 0.05) more n-alkane degradation by 5 days than was achieved with nutrient additions alone. The very low Alcanivorax cell concentrations in the microcosms were hardly influenced by addition of nutrients or bioemulsifier, but strongly increased after their combined addition, reflecting the synergistic action of the two types of biostimulatory agents. Bioaugmentation with Thalassolituus positively influenced hydrocarbon degradation only during the initial 5 days and only of the n-alkane fraction. Bioaugmentation with Alcanivorax was clearly much more effective, resulting in 73% greater degradation of n-alkanes, 59% of branched alkanes, and 28% of polynuclear aromatic hydrocarbons, in the first 5 days than that obtained through nutrient addition alone (P < 0.01). Enhanced degradation due to augmentation with Alcanivorax continued throughout the 30-day period of the experiment. In addition to providing insight into the factors limiting oil biodegradation over time, and the competition and synergism between HCB, these results add weight to the use of bioaugmentation in oil pollution mitigation strategies.     

A highly selective direct method of detecting sulphate-reducing bacteria in crude oil

AIMS: The aim of this work was to develop a highly selective method of detecting sulphate-reducing bacteria (SRB) in crude oil. METHODS: A pair of PCR primers was designed based on an alignment of the nucleotide sequence of the 16S rRNA genes from the Desulfovibrionaceae family. DNA extraction from crude oil was performed by the method using zirconia beads and a stool kit. RESULTS: The PCR specifically detected Desulfovibrio and Desulfomicrobium in a sediment sample. When nucleic acids extracted directly from crude oil were used for the PCR, 16S rRNA genes of Desulfovibrio and Thermodesulforhabdus norvegicus were detected. IMPACT OF STUDY: A simple direct method for detection of the SRB in crude oil using PCR was established.     

Immobilization of proteins on organic polymer beads

A new method is described for the immobilization of biologically active proteins onto several types of organic polymer beads. First, the soluble protein is modified by reaction with an excess of a hydrophobic imidoester, for example methyl 4-phenyl-butyrimidate, at ca. pH 9 and 0 degrees . Excess imidoester and side products resulting from imidoester hydrolysis are separated from the hydrophobic protein derivative by exclusion chromatography or dialysis. A suspension of polymer beads (e.g. Amberlite XAD-7) is then added to a solution of the modified protein at room temperature or below and stirred gently for 1-2 h. The polymer beads are allowed to settle, separated from the solution by decantation or filtration, washed, and resuspended in an appropriate buffer. Quantitative adsorption of protein to the polymer beads is observed under such conditions. The synthesis of seven hydrophobic imidoesters and their use for the immobilization of trypsin onto several types of porous polymer beads is described. The immobilizations of trypsin, yeast alcohol dehydrogenase, and E. coli asparaginase by this procedure with high recoveries of catalytic activity, suggests that it will be applicable to a large number of biologically active proteins.     

Plasminogen activation in degradation and penetration of extracellular matrices and basement membranes by invasive bacteria

Methods to assess in vitro the role of plasminogen activation in enterobacterial degradation of extracellular matrices and their protein components as well as in penetration through basement membrane are described. Development of these methods was initiated after the findings that enterobacterial surface structures (fimbriae and the Pla surface protease) function in plasminogen activation as well as in laminin- and/or fibronectin-specific adhesion. Enterobacteria with these properties degrade radiolabeled laminin as well as metabolically labeled extracellular matrix from cultured endothelial or epithelial cells. Plasmin-coated bacteria also penetrate through the reconstituted basement membrane preparation Matrigel. The processes are dependent on plasminogen activation by the invasive bacteria. The results suggest a pathogenic similarity between enterobacteria and tumor cells in cellular metastasis through tissue barriers.     

Methods evaluating vanadium tolerance in bacteria isolated from crude oil contaminated land

Investigations into bacterial responses to vanadium are rare, and in this study were initiated by isolating cultures from crude oil contaminated soil from Russia and Saudi Arabia. Addition of vanadyl sulphate and vanadium pentoxide created acid conditions in the media whilst sodium metavanadate and sodium orthovanadate produced neutral and alkaline effects, respectively. Buffers were introduced for wider comparison of the sample set treatments and to distinguish between the effects of pH and compound toxicity. This study has resulted in the creation of protocols for the pH stabilisation of media containing vanadium compounds and revealed that, although vanadium salts demonstrated some toxic effects, as revealed by MIC and bioluminescence decay tests, the effects were mainly due to pH rather than inherent toxicity of the metal. Capacity for sorption of vanadium to biomass was also investigated.