Bioemulsifier production by Bacillus stearothermophilus VR-8 isolate

Bacillus stearothermophilus produced an extracellular bioemulsifier during growth in a medium containing 4% crude oil. Over the temperature range of 45° to 70°C, maximum recovery (0·6 g 1^-1) occurred at 50°C. The emulsifier had its greatest activity on benzene, among the hydrocarbons tested. Acetone precipitated, dialysed emulsifier contained 46% protein, 16% carbohydrate and 10% lipid. The emulsification activity was stable over a broad range of temperature (50–80°C), pH (2–8) and salt concentration (5% NaCl, 5% CaCl₂ and 1% MgCl₂). Thus, this emulsifier was found to be better than liposan (showing emulsifying activity between pH 2–5 and stable up to 70°C) in terms of pH and temperature stability. Additionally, it was also salt tolerant, suggesting its potential use in crude oil tank clean-up and enhanced oil recovery.     

Bioemulsifier production by Streptomyces sp. S22 isolated from garden soil

Out of 45 actinomycetes isolated from garden soil, pond water and air; fifteen showed good emulsification activity. Streptomyces sp. S22 isolated from garden soil produced maximum bioemulsifier with 0.5% (v/v) sunflower oil during stationary phase at 37 degrees C, pH 6 and 250 rev/min. Emulsification activity was maximum (320 EU/ml) with sunflower oil as substrate. Partially purified bioemulsifier from Streptomyces sp. S22 was a peptidoglycolipid containing lipid (51.25%), protein (30%), non-reducing sugar (17.75%) and reducing sugar (1%). The yield of partially purified bioemulsifier was 1.6 g/l and reduced the surface tension of water by 23.09 mN/m. The bioemulsifier produced by Streptomyces sp. S22 was stable at room temperature for seven days.     

Characterization and emulsifying property of a novel bioemulsifier by Aeribacillus pallidus YM-1

Aims: Biosurfactants and bioemulsifiers commonly have the advantages of biodegradability, low toxicity, selectivity and biocompatibility over chemically synthesized surfactants. The goal of the study is to present a novel bioemulsifier with great application potential. Methods and Results: Aeribacillus pallidus YM‐1, isolated from crude oil contaminated soil, was found to produce a novel high molecular bioemulsifier with an emulsification index of 60 ± 1% without remarkable surface tension reduction (45·7 ± 0·1 mN m^?1). The number‐average molecular weight was determined as 526 369 Da by gel permeation chromatography analysis. Bioemulsifier was subjected to FT‐IR and a complex of carbohydrates (41·1%), lipids (47·6%) and proteins (11·3%) was determined. Conclusions: The bioemulsifier of A. pallidus YM‐1 was isolated from the glucose‐based culture medium and characterized with the help of chemical analytical techniques. The bioemulsifier exhibited a promising emulsifying property for biotechnology application potential in bioremediation and microbial enhanced oil recovery. Significance and Impact of the Study: This is the first report of the bioemulsifier production by A. pallidus. The potential emulsifying activity of the bioemulsifier in the present study may be explored in various biotechnological and industrial applications.     

Effects of oil reservoir conditions on the production of water‐insoluble Levan by Bacillus licheniformis

Bacillus licheniformis produced a water‐insoluble levan which has potential application as a selective plugging agent in microbial enhanced oil recovery (MEOR). The microorganism grew on sucrose, glucose, and fructose but produced levan only on sucrose. Plugging may thus be selectively controlled in the reservoir by substrate manipulation. B. licheniformis and a crude preparation of its extracellular enzymes were evaluated for their ability to produce levan under reservoir conditions. Oil reservoirs which have a temperature of less than 55°C, a pH between 6 and 9, a pressure less than 500 atm, and a salt concentration of 4% or less are potentially suitable. Examples of such reservoir conditions are found in Lloydminster on the Alberta‐Saskatchewan border, one of the largest Canadian oil reserves.     

Screening of bioemulsifier-producing micro-organisms isolated from oil-contaminated sites

Eighty-eight micro-organisms were isolated from oil-contaminated soils and checked for their extracellular bioemulsifier producing potential. The micro-organisms were screened on the basis of oil spread, drop collapse and emulsification index. Most efficient strains were characterized as Lysinibacillus sp. SP1025 and Bacillus cereus SP1035. In Lysinibacillus sp. SP1025, the E-24 index, surface tension and production of crude bioemulsifier were found to be 83.3 % with diesel, 34.20?±?0.03 mN/m and 3.07?±?0.62 g/L, respectively, whereas in the case of Bacillus cereus SP1035, the E-24 index, surface tension and production of crude bioemulsifier recorded were 76.5 % with diesel, 43.42?±?0.03 mN/m and 3.90?±?0.3 g/L. Crude biomemulsifier produced by selected micro-organisms was stable, withstanding a wide temperature and pH range with an E-24 Index value greater than 50 %. All emulsions formed were oil-in-water type. Emulsions formed with tested aliphatic and aromatic hydrocarbons, except those formed with ester based oils, were 100 % stable with the entire organic layer converted into emulsion. To the best of our knowledge this is the first report for bioemulsifier production from the genus Lysinibacillus.     

Production of a peptidoglycolipid bioemulsifier by Pseudomonas aeruginosa grown on hydrocarbon

A strain of Pseudomonas aeruginosa isolated from a polluted soil was found to produce an extracellular bioemulsifier when cultivated on hexadecane as sole carbon source. The emulsifier was precipitated with acetone and redissolved in sterile water. Dodecane, crude oil and kerosene were found to be good substrates for emulsification by the bioemulsifier. Growth and bioemulsifier production reached the optimal levels on the fourth and fifth day, respectively. Emulsifying activity was observed over a pH range of 3.5 to 10.0 with a maximum at pH 7.0. The activity of the bioemulsifier was heat stable up to 70 degrees C while about 50 percent of its activity was retained at 100 degrees C. The components of the bioemulsifier were determined, it was found to contain carbohydrate, protein and lipid. The protein complex was precipitated with ammonium sulphate and fractionated on a Sephadex G-100. Gel electrophoresis of the bioemulsifier showed a single band whose molecular weight was estimated as 14,322 Da. The bioemulsifier was classified as a peptidoglycolipid. Certain strains of P. aeruginosa produce peptidoglycolipid in place of rhamnolipid.     

Optimizing the medium components in bioemulsifiers production by Candida lipolytica with response surface method

A response surface methodology was used to study bioemulsifier production by Candida lipolytica. A 2(4) full experimental design was previously carried out to investigate the effects and interactions of the concentrations of corn oil, urea, ammonium sulfate, and potassium dihydrogen orthophosphate on the emulsification activity (EA) of the bioemulsifier produced by C. lipolytica. The best EA value (3.727 units of emulsification activity (UEA)) was obtained with a medium composed of 0.4 g of urea, 1.1 g of ammonium sulfate, 2.04 g of potassium dihydrogen orthophosphate, 5 mL of corn oil, 50 mL of distilled water, and 50 mL of seawater. A curvature check was performed and revealed a lack of fit of the linear approximation. The proximity of the optimum point was evident, as was the need for quadratic model and second-order designs that incorporate the effect of the curvature. Medium constituents were then optimized for the EA using a three-factor central composite design and response surface methodology. The second-order model showed statistical significance and predictive ability. It was found that the maximum EA produced was 4.415 UEA, and the optimum levels of urea, ammonium sulfate, and potassium dihydrogen orthophosphate were, respectively, 0.544% (m/v), 2.131% (m/v), and 2.628% (m/v).     

Characteristics of bioemulsifier V2-7 synthesized in culture media added of hydrocarbons: chemical composition, emulsifying activity and rheological properties

The bioemulsifier V2-7 is an exopolysaccharide (EPS) synthesized by strain F2-7 of Halomonas eurihalina and it has the property of emulsifying a wide range of hydrocarbons i.e. n-tetradecane, n-hexadecane, n-octane, xylene mineral light and heavy oils, petrol and crude oil. Characteristics of exopolysaccharide V2-7 produced in media supplemented with various hydrocarbons (n-tetradecane, n-hexadecane, n-octane, xylene, mineral light oil, mineral heavy oil, petrol or crude oil) were studied. Yield production varied from 0.54 to 1.45 g L(-1) according to the hydrocarbon added, in the same way chemical composition, viscosity and emulsifying activity of EPS varied with the culture conditions. Respect to chemical composition, percentage of uronic acids found in exopolymers produced in hydrocarbon media was always higher than that described for V2-7 EPS (1.32%) obtained with glucose. This large amount of uronic acid present could be useful in biodetoxification and waste water treatment. On the other hand, the highest amount of biopolymer was synthesized with mineral light oil, while the most active emulsifiers were those obtained from media added with petrol and n-octane. Furthermore, all EPS were capable of emulsifying crude oil more efficiently than the three chemical surfactants tested as control (Tween 20, Tween 80 and Triton X-100). The capacity of strain F2-7 to grow and produce bioemulsifier in presence of oil hydrocarbons together with the high emulsifying activity and low viscosity power of the biopolymers synthesized in hydrocarbons media could be considered highly beneficial for application of both bioemulsifier and producing strain in bioremediation of oil pollutants.     

Studies on bioemulsifier production by Acinetobacter strains isolated from healthy human skin

AIMS: In recent years, interest has been growing in the search for novel bioemulsifiers. Many bacterial genera including Acinetobacter have been reported to produce bioemulsifiers. The present study aims to screen Acinetobacter isolates from healthy human skin for bioemulsifier production. Methods and Results: Acinetobacter junii SC14 produced maximum bioemulsifier in the presence of almond oil during stationary growth phase at 37 degrees C and pH 7.2. Partially purified, nondialysable bioemulsifier from SC14 was a proteoglycan. The protein and polysaccharide fractions resulted in 95.2% reconstitution of the emulsification activity. The role of esterase in the release of cell-bound emulsifier and the contribution of capsular polysaccharide to the emulsification activity were observed. CONCLUSION: Acinetobacter strains from human skin exhibited better emulsification activity than that by burn wound or soil isolates, owing to the inherent differences in chemical microenvironment of their habitats. SIGNIFICANCE AND IMPACT OF THE STUDY: Investigation of skin commensals, especially acinetobacters, would lead to the discovery of novel bioemulsifiers with interesting properties. Attempts of screening and strain improvement directed towards skin commensals will open up new avenues for strains producing bioemulsifier on a commercial scale.     

一株可乳化降解原油的Compostibacillus的分离及特性

【背景】通过实施多轮次微生物采油,华北油藏产出液菌浓达到了106个/mL以上,油藏内部已经形成了较稳定的微生物发酵场,从其中筛选出能够乳化降解原油的微生物,并在地面对其进行扩大培养,然后再应用到微驱油藏,以进一步提高微生物采油实施效果。【目的】筛选乳化降解原油性能良好的菌株,对其进行多相分类学鉴定和性能评价。【方法】利用原油为底物筛选乳化降解性能良好的菌株,通过形态特征观察、生理生化测定、16S rRNA基因序列分析等确定菌株的分类地位。通过乳化能力、降解率等方法确定菌株的原油乳化降解特性。【结果】从华北油田采集的地层水样品中分离得到一株乳化原油的菌株BLG74,经多相分类鉴定表明其是土壤堆肥芽孢杆菌(Compostibacillus humi)的新菌株,亲源性99.6%。该菌株的生长温度为30-60℃ (最适温度45℃),pH6.5-9.5(最适pH7.0),NaCl浓度0%-7%(质量体积比)。菌株BLG74在玉米浆培养基中培养,其发酵液的表面张力为56.3 mN/m,乳化力约95%,在初始原油质量浓度0.5%、温度45℃的条件下培养20d,对原油的降解率可达40.8%。【结论】菌...     

Characterization of new biosurfactant produced by Klebsiella sp. Y6-1 isolated from waste soybean oil

To obtain predominant bacteria degrading crude oil, we isolated some bacteria from waste soybean oil. Isolated bacterial strain had a marked tributyrin (C4:0) degrading activity as developed clear zone around the colony after incubation for 24h at 37 degrees C. It was identified as Klebsiella sp. Y6-1 by analysis of 16S rRNA gene. Crude biosurfactant was extracted from the culture supernatant of Klebsiella sp. Y6-1 by organic solvent (methanol:chloroform:1-butanol) after vacuum freeze drying and the extracted biosurfactant was purified by silica gel column chromatography. When the purified biosurfactant dropped, it formed degrading zone on crude oil plate. When a constituent element of the purified biosurfactant was analyzed by TLC and SDS-PAGE, it was composed of peptides and lipid. The emulsification activity and stability of biosurfactant was measured by using hydrocarbons and crude oil. The emulsification activity and stability of the biosurfactant showed better than the chemically synthesized surfactant. It reduced the surface tension of water from 72 to 32 mN/m at a concentration of 40 mg/l.     

Production of bioemulsifier by Bacillus subtilis, Alcaligenes faecalis and Enterobacter species in liquid culture

Three bacterial strains isolated from waste crude oil were selected due to their capacity of growing in the presence of hydrocarbons and production of bioemulsifier. The genetic identification (PCR of the 16S rDNA gene using fD1 and rD1 primers) of these strains showed their affiliation to Bacillus subtilis, Alcaligenes faecalis and Enterobacter sp. These strains were able to emulsify n-octane, toluene, xylene, mineral oils and crude oil, look promising for bioremediation application. Finally, chemical composition, emulsifying activity and surfactant activity of the biopolymers produced by the selected strains were studies under different culture conditions. Our results showed that chemical and functional properties of the bioemulsifiers were affected by the carbon source added to the growth media.     

Application of microbial enhanced oil recovery technique to a Turkish heavy oil

Summary Microbial enhance oil recovery utilizes microorganisms and their metabolic products to improve the recovery of crude oil from reservoir rocks. In this study an anaerobic bacterium, Clostridium acetobutylicum was injected into a one-dimensional model reservoir containing a Turkish heavy oil (Raman oil) at 38° C. This injection was followed by water flooding after a suitable shut-in period. Comparison of oil recovery results of pure water flooding runs with experiments in which bacterial concentration and shut-in periods were varied indicated increases in oil recovery of about 12% of the original oil in place. This increase was attributed to changes in the viscosity and pH of the crude oil.Offprint requests to: T. Mehmetoglu     

Biosurfactant production using molasses and whey under thermophilic conditions

Biosurfactant production was studied by Bacillus licheniformis K51, B. subtilis 20B, B. subtilis R1 and Bacillus strain HS3 using molasses or cheese whey as a sole source of nutrition at 45 degrees C. The isolates were able to grow and produce biosurfactant under shaking as well as static conditions. Maximum biosurfactant production was achieved with molasses at 5.0-7.0% (w/v). The biosurfactant retained its surface-active properties after incubation at 80 degrees C at a wide range of pH values and salt concentrations for nine days. Oil displacement experiments in sand pack columns with crude oil showed 25-33% recovery of residual oil.     

Characterization of a novel bioemulsifier from <Emphasis Type="Italic">Pseudomonas stutzeri</Emphasis>

This study describes a novel and efficient alasan-like bioemulsifier produced by Pseudomonas stutzeri NJtech 11-1, which was isolated from the Shengli Oilfield. The strain was found to produce a new and interesting emulsion stabilizer. The crude bioemulsifier showed super stability with 50% salinity and broad pH 3–10. The emulsion index (EI₂₄) was increased to 100% after heating from 45 to 95 °C and the emulsion could be stable for at least 30 days. The yield of Ps-bioemulsifier (pure bioemulsifier) was 0.68?±?0.05 mg mL^?1. The Ps-bioemulsifier was composed of carbohydrates (80?±?2.6%) and proteins (9.5?±?0.5%). A low concentration (0.2 mg mL^?1) of the Ps-bioemulsifier was obtained maximum emulsifying activity at pH 7.1 and its emulsifying activity strengthened by suitable salinity. Furthermore, Ps-bioemulsifier could also emulsify cyclohexane, hexadecane, kerosene, xylene hydrocarbons efficiently. Therefore, the Ps-bioemulsifier showed emulsifying characteristics which make it a good candidate for potential applications in bioremediation and microbial enhanced oil recovery.     

Effect of Emulsan on Biodegradation of Crude Oil by Pure and Mixed Bacterial Cultures

Crude oil was treated with purified emulsan, the heteropolysaccharide bioemulsifier produced by Acinetobacter calcoaceticus RAG-1. A mixed bacterial population as well as nine different pure cultures isolated from various sources was tested for biodegradation of emulsan-treated and untreated crude oil. Biodegradation was measured both quantitatively and qualitatively. Recovery of ¹⁴CO₂ from mineralized ¹⁴C-labeled substrates yielded quantitative data on degradation of specific compounds, and capillary gas chromatography of residual unlabeled oil yielded qualitative data on a broad spectrum of crude oil components. Biodegradation of linear alkanes and other saturated hydrocarbons, both by pure cultures and by the mixed population, was reduced some 50 to 90% after emulsan pretreatment. In addition, degradation of aromatic compounds by the mixed population was reduced some 90% in emulsan-treated oil. In sharp contrast, aromatic biodegradation by pure cultures was either unaffected or slightly stimulated by emulsification of the oil.     

Bioemulsifier production by a halothermophilic Bacillus strain with potential applications in microbially enhanced oil recovery

A halothermotolerant Gram-positive spore-forming bacterium was isolated from petroleum reservoirs in Iran and identified as Bacillus licheniformis sp. strain ACO1 by phenotypic characterization and 16S rRNA analysis. It showed a high capacity for bioemulsifier production and grew up to 60°C with NaCl at 180 g l⁻¹. The optimum NaCl concentration, pH and temperature for bioemulsifier production were 4% (w/v), 8.0, and 45°C, respectively. Although ACO1 did not utilize hydrocarbons, it had a high emulsifying activity (E ₂₄ = 65 ± 5%) on different hydrophobic substrates. Emulsification was optimal while growing on yeast extract as the sole carbon source and NaNO₃ as the nitrogen source. The efficiency of the residual oil recovery increased by 22% after in situ growth of B. licheniformis ACO1 in a sand-pack model saturated with liquid paraffin.     

Production of biosurfactant and antifungal compound by fermented food isolate Bacillus subtilis 20B

A biosurfactant producing strain, Bacillus subtilis 20B, was isolated from fermented food in India. The strain also showed inhibition of various fungi in in-vitro experiments on Potato Dextrose Agar medium. It was capable of growth at temperature 55 degrees C and salts up to 7%. It utilized different sugars, alcohols, hydrocarbons and oil as a carbon source, with preference for sugars. In glucose based minimal medium it produced biosurfactant which reduced surface tension to 29.5 mN/m, interfacial tension to 4.5 mN/m and gave stable emulsion with crude oil and n-hexadecane. The biosurfactant activity was stable at high temperature, a wide range of pH and salt concentrations for five days. Oil displacement experiments using biosurfactant containing broth in sand pack columns with crude oil showed 30.22% recovery. The possible application of organism as biocontrol agent and use of biosurfactant in microbial enhanced oil recovery (MEOR) is discussed.     

Physicochemical characterization of a thermostable glycoprotein bioemulsifier from Solibacillus silvestris AM1

A novel estuarine bacterial strain, Solibacillus silvestris AM1, was found to produce an extracellular, multimeric glycoprotein bioemulsifier, termed AM1, with a MW of 200 kDa and containing 30 kDa monomeric subunits. The bioemulsifier contained 3.6% of the minor carbohydrate components galactose and ribose/xylose. LC/MS-MS of the 30 kDa subunit revealed its homology with a flagellin-like protein arranged in the form of fibers, as shown by transmission electron micrographs. This is the first report of a flagellin-like protein that exhibits bioemulsifier activity being produced from a member of the Solibacillus genus. Bioemulsifier AM1 has a high emulsification index of 62.5% with 10^?2 critical micellar dilution. It was found to be thermostable and active in the pH 5–9 and 0–5 M NaCl ranges. Moreover, AM1 formed stable emulsions with a broad range of solvents, including aliphatics, aromatic hydrocarbons and oils, performing better than the well-known bioemulsifier emulsan. Emulsions formed with trichlorobenzene and paraffin oil have a pseudoplastic non-Newtonian rheological property, as observed by particle size and shear stress analysis. AM1, an eco-friendly bioemulsifier, formed stable emulsions in varied physical conditions, and these attributes may prove to be advantageous in cosmetic, pharmaceutical and environmental applications.     

超低渗油藏微生物吞吐技术的矿场试验

【目的】通过对渭北低渗油藏内源微生物的研究,考察分离纯化的内源解烃菌产生表面活性剂和降解原油的能力、岩心驱替增油效率,同时验证其在超低渗油田单井吞吐矿场实验的应用效果,探讨微生物采油技术在超低渗油田提高采收率的工艺和可行性。【方法】采集超低渗油藏的油水样,应用油平板进行产表面活性剂解烃菌的分离,通过生理生化特性和16S r RNA基因序列分析对菌株进行种属鉴定,评价其油藏环境适应性,利用内源-外源功能微生物复配体系进行原油降解,在填砂管和岩心物模上进行驱油实验,将优化好的微生物复配体系应用于现场实施单井吞吐工艺的实验。【结果】从渭北某区块超低渗油藏的原油样品中分离得到一株铜绿假单胞菌(Pseudomonas aeruginosa),命名为WB-001。该菌株可使发酵液的表面张力降至29.04 m N/m,使渭北原油蜡质含量降至8.48%。填砂管实验表明WB-001与外源枯草芽胞杆菌OPUS-HOB-001(Bacillus subtilis)复配后,驱油效率较单纯水驱提高了9.72%;岩心驱替实验较水驱提高12.54%。微生物单井吞吐措施后,平均日产油由措施前的0.42 t增加到0.89 t,累计增油44.47 t;原油降粘率为11.70%,降凝率为9.41%,采出水表面张力降低幅度为18.93%。【结论】通过详细的室内评估和成功的矿场实验,证明微生物采油技术在超低渗油藏有一定的应用可行性,并为后续规模化应用提供了理论基础和物质基础,为超低渗油田的高效精细开发探索一条新的途径。