响应面法优化Alcaligenes sp.产脂肽生物破乳剂培养基的研究

生物破乳刺是应用于石油开采业中的新型破乳剂之一,本研究对筛选得到的一株破乳剂产生菌(鉴定为Alcdigenes sp.)产生的脂肽类生物破乳剂进行了发酵培养基的优化,采用SAS软件的响应面回归方法对培养基中主要因素进行了研究,试验结果表明,在碳源石蜡为4.76%、氮源牛肉膏为0.12%、磷源K2HPO4/KH2PO4为0.53/0.8%时,破乳剂的产生量为最大,比优化前提高了近一倍.     

毕赤氏酵母植酸酶工程菌高密度培养条件的研究

研究了毕赤氏酵母植酸酶工程菌高密度生长的培养条件 ,包括不同碳源、酵母粉、(NH4 ) 2 SO4 、KH2 PO4 等不同用量对菌体生长的影响。结果是甘油 4 %、蛋白陈 2 %、酵母粉 0 5%、(NH4 ) 2 SO4 0 .8%、K2 HPO4 0 1%、KH2 PO4 0 6 %。在此基础上 ,对温度、起始pH、接种量等影响该工程菌菌体生长的因素也作了初步研究。     

一株假单胞菌HZ-1降解石油烃的初步研究

从石油废水活性污泥中分离到一株可以较好降解石油烃的假单胞菌（Pseudomonas sp）HZ-1,采用生物膜法对该菌株在30℃条件下降解某炼油厂废水中的烃类物质进行了研究.研究结果表明不同营养盐NH4NO3、NaH2PO4、NH4Cl对菌株HZ-1处理石油废水的作用不同,终浓度为1000mg/L的NH4NO3对菌株HZ-1处理石油废水效果最佳.并在30℃和pH 8.0的条件下,初步研究了该菌株降解萘的情况,在萘浓度低于78 mg/L的情况下,120 rpm好氧振荡培养144h,这株菌对萘的降解率在86%以上.     

曲霉液体发酵产原果胶酶的条件优化研究*

研究了碳源、氮源、金属离子及表面活性剂等对菌株(Aspergillus sp.)XZ-131产原果胶酶的影响.果胶类物质是该菌株产原果胶酶所必需的诱导物.以(NH4)2SO4和(NH4)2HPO4作为氮源时,产酶较高,达到300 U/mL.钙离子及Tween-20均能促进该酶的产生.通过正交试验优化得出该菌株产酶的最佳培养基配方为桔皮粉 1g,(NH4)2SO4 2g,CaCl2 0.015g,Tween-20 0.2mL,KH2PO4 3.8g,K2HPO4*3H2O 0.2g,水 100mL,pH 6.5.     

灰树花发酵工艺及培养基研究

详细、系统地研究了碳源、氮源、无机盐、维生素以及种龄、接种量、摇床转速、摇瓶装液量和培养基 pH值等因素对灰树花液体深层发酵菌丝体产量的影响 ,结果表明 :玉米粉、葡萄糖为最佳碳源 ,豆饼粉为最佳氮源 ,KH2 PO4 ,MgSO4 以及少量VB1的添加均使菌丝体产量明显增加     

K88大肠杆菌菌毛蛋白发酵工艺条件优化研究

分别采用LB培养基、牛肉膏蛋白胨培养基、强化营养培养基、玉米浆培养基对大肠杆菌K88进行发酵培养,选出最适于大肠杆菌K88生长的玉米浆培养基;采用正交实验对玉米浆培养基的C／N、K2HPO4／KH2PO4、Mg^2＋的配比进行优化,筛选最适于大肠杆菌K88生长的营养配比;研究生长曲线、接种量以及菌体和菌毛生产量的相关性,根据实验结果优化发酵培养条件,确定菌种的最佳发酵工艺,以收获最多的K88菌毛蛋白。研究表明,K88大肠杆菌在玉米浆培养基C／N、K2HP04／KH2PO4的配比分别为5／11、1／1,Mg^2＋为0．1g/mL,pH值为7．2,转速为200r／min,接种量为4．5％的条件下发酵26个小时,菌体和菌毛生产量均达到高峰,同时得出菌毛蛋白产生量和菌体量成正相关。     

微生物多糖WL-26深层发酵工艺的优化

产碱杆菌Alcaligenes sp.JL-1能分泌一种高分子多糖WL-26.以生物量、发酵产量和黏度为主要指标,对其深层发酵培养基进行了筛选,并在此基础上对发酵条件进行优化.培养条件确定为:40g/L蔗糖,4g/L复合氮源(20%硝酸钠和80%的牛肉膏),2g/L KH2PO4,0.1g/L MgSO4,0.5mL/L FeSO4.初始pH为7.2～7.4,5%的接种量、装液量为50mL/250mL三角瓶、转速为200r/min、30℃恒温培养58h,WL-26产量从9.326g/L提高到21.767g/L.     

响应面试验设计优化脱氢酶发酵培养基

目的:对简单节杆菌,TCCC11037发酵生产脱氢酶的培养基进行优化.方法:利用单因子试验筛选出最适碳源为葡萄糖,氮源为酵母膏.采用Plackett-Burman(P-B)方法筛选出对产酶有重要影响的因素,并采用响应面试验设计(RSM)对重要因素进行优化.结果:葡萄糖、酵母膏、KH2PO4的浓度是影响脱氢酶产生的重要因素.优化后的培养基组成为(%):葡萄糖1.21,酵母膏0.65,KH2PO4 0.24,玉米浆0.8;培养基初始pH值7.0,接种量5%,通气条件为装液量100mL/500mL.结论:优化后脱氢酶活力达到24.57μmol/(g·min),得到了明显的提高.     

嗜线虫致病杆菌HB310培养基筛选和培养条件优化

嗜线虫致病杆菌Xenorhabdus nematophila是与小卷蛾斯氏线虫Steinernema carpocapsae互惠共生的一种革兰氏阴性菌,对多种农业害虫都具有很高的杀虫活性。本研究对多种影响嗜线虫致病杆菌HB310菌株发酵培养的因素进行了筛选优化。通过单因素试验确定最佳碳源、氮源和无机盐分别为葡萄糖、牛肉蛋白胨和KH2PO4;通过正交实验确定培养基的最优组合为：葡萄糖2 %、牛肉蛋白胨1 %、牛肉浸膏0.3% 和K2HPO4.1 %;最佳摇瓶培养条件为：接种量6%、培养基pH 7.5、摇床转速200 rpm、培养温度28℃和培养时间48 h,在此条件下,嗜线虫致病杆菌HB310菌株生长速率最快,菌液的杀虫活性最高。     

5′—磷酸二酯酶高产菌株的选育和发酵培养条件的优点

以ATCC14994为出发菌株,采用紫外线与亚硝基胍相结合的多次诱变育种,获得1株5′-磷酸二酯酶高产菌株HAT2228.通过单因子和正交试验对该菌株的产酶发酵条件进行了优化,优化发酵产酶条件为蔗糖5%,酵母膏0 3%,蛋白胨0.3%,K2HPO4 0.8%,KH2PO40.8%,MgSO4 0.2%,ZnSO4 0.2%,培养基起始pH6 0,接种量10%,培养温度30℃,摇床转速120r/min,发酵时间48h.在优化条件下,HAT2228的产酶水平达1 329u/ml.     

Biodegradation of petroleum hydrocarbons by filamentous fungi (Aspergillus ustus and Purpureocillium lilacinum) isolated from used engine oil contaminated soil

The use of microorganisms for remediation and restoration of hydrocarbons contaminated soils is an effective and economic solution. The current study aims to find out efficient telluric filamentous fungi to degrade petroleum hydrocarbons pollutants. Six fungal strains were isolated from used engine (UE) oil contaminated soil. Fungi were screened for their ability to degrade crude oil, diesel and UE oil using 2.6-dichlorophenol indophenol (DCPIP). Two isolates were selected, identified and registered at NCBI as Aspergillus ustus HM3.aaa and Purpureocillium lilacinum HM4.aaa. Fungi were tested for their tolerance to different concentration of petroleum oils using radial growth diameter assay. Hydrocarbons removal percentage was evaluated gravimetrically. The degradation kinetic of crude oil was studied at a time interval of 10 days. A.ustus was the most tolerant fungi to high concentration of petroleum oils in solid medium. Quantitative analysis showed that crude oil was the most degraded oil by both isolate; P. lilacinium and A. ustus removed 44.55% and 30.43% of crude oil, respectively. The two fungi were able to degrade, respectively, 27.66 and 21.27% of diesel and 14.39 and 16.00% of UE oil. As compared to the controls, these fungi accumulated high biomass in liquid medium with all petroleum oils. Likewise, crude oil removal rate constant (K) and half-lives (t_1/2) were 0.02 day⁻¹, 34.66 day and 0.015 day⁻¹, 46.21 day for P. lilacinium and A. ustus, respectively. The selected fungi appear interesting for petroleum oils biodegradation and their application for soil bioremediation require scale-up studies.     

Hydrocarbon-degrading filamentous fungi isolated from flare pit soils in northern and western Canada

Sixty-four species of filamentous fungi from five flare pits in northern and western Canada were tested for their ability to degrade crude oil using gas chromatographic analysis of residual hydrocarbons following incubation. Nine isolates were tested further using radiorespirometry to determine the extent of mineralization of model radiolabelled aliphatic and aromatic hydrocarbons dissolved in crude oil. Hydrocarbon biodegradation capability was observed in species representing six orders of the Ascomycota. Gas chromatography indicated that species capable of hydrocarbon degradation attacked compounds within the aliphatic fraction of crude oil, n-C12-n-C26; degradation of compounds within the aromatic fraction was not observed. Radiorespirometry, using n-[1-14C]hexadecane and [9-14C]phenanthrene, confirmed the gas chromatographic results and verified that aliphatic compounds were being mineralized, not simply transformed to intermediate metabolites. This study shows that filamentous fungi may play an integral role in the in situ biodegradation of aliphatic pollutants in flare pit soils.     

Isolation and characterization of Halomonas sp. strain C2SS100, a hydrocarbon-degrading bacterium under hypersaline conditions

Aims:  To isolate and characterize an efficient hydrocarbon-degrading bacterium under hypersaline conditions, from a Tunisian off-shore oil field.
Methods and Results:  Production water collected from 'Sercina' petroleum reservoir, located near the Kerkennah island, Tunisia, was used for the screening of halotolerant or halophilic bacteria able to degrade crude oil. Bacterial strain C2SS100 was isolated after enrichment on crude oil, in the presence of 100 g l⁻¹ NaCl and at 37°C. This strain was aerobic, Gram-negative, rod-shaped, motile, oxidase + and catalase +. Phenotypic characters and phylogenetic analysis based on the 16S rRNA gene of the isolate C2SS100 showed that it was related to members of the Halomonas genus. The degradation of several compounds present in crude oil was confirmed by GC–MS analysis. The use of refined petroleum products such as diesel fuel and lubricating oil as sole carbon source, under the same conditions of temperature and salinity, showed that significant amounts of these heterogenic compounds could be degraded. Strain C2SS100 was able to degrade hexadecane (C₁₆). During growth on hexadecane, cells surface hydrophobicity and emulsifying activity increased indicating the production of biosurfactant by strain C2SS100.
Conclusions:  A halotolerant bacterial strain Halomonas sp. C2SS100 was isolated from production water of an oil field, after enrichment on crude oil. This strain is able to degrade hydrocarbons efficiently. The mode of hydrocarbon uptake is realized by the production of a biosurfactant which enhances the solubility of hydrocarbons and renders them more accessible for biodegradation.
Significance and Impact of the Study:  The biodegradation potential of the Halomonas sp. strain C2SS100 gives it an advantage for possibly application on bioremediation of water, hydrocarbon-contaminated sites under high-salinity level.     

Isolation and Identification of hydrocarbon degrading bacteria from Ennore creek

The widespread problem caused due to petroleum products, is their discharge and accidental spillage in marine environment proving to be hazardous to the surroundings as well as life forms. Thus remediation of these hydrocarbons by natural decontamination process is of utmost importance. Bioremediation is a non-invasive and cost effective technique for the clean-up of these petroleum hydrocarbons. In this study we have investigated the ability of microorganisms present in the sediment sample to degrade these hydrocarbons, crude oil in particular, so that contaminated soils and water can be treated using microbes. Sediments samples were collected once in a month for a period of twelve months from area surrounding Ennore creek and screened for hydrocarbon degrading bacteria. Of the 113 crude oil degrading isolates 15 isolates were selected and cultivated in BH media with 1% crude oil as a sole carbon and energy source. 3 efficient crude oil bacterial isolates Bacillus subtilis I1, Pseudomonas aeruginosa I5 and Pseudomonas putida I8 were identified both biochemically and phylogenetically. The quantitative analysis of biodegradation is carried out gravimetrically and highest degradation rate, 55% was recorded by Pseudomonas aeruginosa I5 isolate.     

Petroleum Bioremediation in Seawater Using Guano as the Fertilizer

The biodegradation of hydrocarbon pollutants in open systems, such as oceans, is generally limited by the availability of utilizable nitrogen and phosphorus sources. Here the authors demonstrate the potential of overcoming this problem with guano as the fertilizer. In the first set of experiments, the principle and conditions for growing bacteria on a water insoluble fertilizer was established, using uric acid as the nitrogen source and a pure culture of an isolated hydrocarbon-degrading bacterium, Alcanivorax sp. OK2. Using a simulated open system, it was demonstrated that uric acid (the major nitrogen component of guano) binds to crude oil and is available for the growth of strain OK2 and petroleum degradation. In the second set of experiments, using a simulated open system, it was demonstrated that commercial guano was an effective source of nitrogen and phosphorus for the growth of marine bacteria on crude oil. Bacterial cultures reached over 10⁸ cells per ml and 70% of the crude oil was degraded. Controls using ammonium sulfate and phosphate in place of guano in the simulated open system reached only 10⁶ cells per ml and showed no detectable hydrocarbon degradation. Isolation and characterization of the bacteria in the crude oil/guano cultures indicated that they were primarily strains of Alcanivorax and Alteromonas.     

Mycoremediation of crude oil contaminated soil by specific fungi isolated from Dhahran in Saudi Arabia

Crude oil biodegrading microorganism considers the key role for environmental preserving. In this investigation, crude oil biodegrading fungal strains have been isolated in polluted soil of crude-oil at khurais oil ground in Kingdom of Saudi Arabia. Among of 22 fungal isolates, only three isolates reflected potential capability for oil degradation. These isolates were identified and submitted to GenBank as (A1) Aspergillus polyporicola (MT448790), (A2) Aspergillus spelaeus (MT448791) and (A3) Aspergillus niger (MT459302) through internal-transcribed spacer-regions (ITS1&ITS2) for sequencing in molecular marker. Comparing with controls, strain (A1) Aspergillus niger was superior for biodegradation ability (58%) comparing with Aspergillus polyporicola and Aspergillus spelaeus degrading were showed 47 and 51% respectively. Employed CO₂ evolution as indicator for petroleum oil biodegradation by the fungal isolates reflected that, Aspergillus niger emission highest CO2 (28.6%) comparing with Aspergillus spelaeus and Aspergillus polyporicola which showed 13% and 12.4% respectively. capability of Aspergillus sp. to tolerate and adapted oil pollutants with successful growth rate on them, indicated that it can be employed as mycoremediation agent for recovering restoring ecosystem when contaminated by crude oil.     

Stimulation of Diesel Fuel Biodegradation by Indigenous Nitrogen Fixing Bacterial Consortia

Abstract Successful stimulation of N₂ fixation and petroleum hydrocarbon degradation in indigenous microbial consortia may decrease exogenous N requirements and reduce environmental impacts of bioremediation following petroleum pollution. This study explored the biodegradation of petroleum pollution by indigenous N₂ fixing marine microbial consortia. Particulate organic carbon (POC) in the form of ground, sterile corn-slash (post-harvest leaves and stems) was added to diesel fuel amended coastal water samples to stimulate biodegradation of petroleum hydrocarbons by native microorganisms capable of supplying a portion of their own N. It was hypothesized that addition of POC to petroleum amended water samples from N-limited coastal waters would promote the growth of N₂ fixing consortia and enhance biodegradation of petroleum. Manipulative experiments were conducted using samples from coastal waters (marinas and less polluted control site) to determine the effects of POC amendment on biodegradation of petroleum pollution by native microbial consortia. Structure and function of the microbial consortia were determined by measurement of N₂ fixation (acetylene reduction), hydrocarbon biodegradation (¹⁴C hexadecane mineralization), bacterial biomass (AODC), number of hydrocarbon degrading bacteria (MPN), and bacterial productivity (³H-thymidine incorporation). Throughout this study there was a consistent enhancement of petroleum hydrocarbon degradation in response to the addition of POC. Stimulation of diesel fuel biodegradation following the addition of POC was likely attributable to increases in bacterial N₂ fixation, diesel fuel bioavailability, bacterial biomass, and metabolic activity. Toxicity of the bulk phase water did not appear to be a factor affecting biodegradation of diesel fuel following POC addition. These results indicate that the addition of POC to diesel-fuel-polluted systems stimulated indigenous N₂ fixing microbial consortia to degrade petroleum hydrocarbons. Received: 29 December 1998; Accepted: 6 April 1999     

Nutrient Amendments of Inorganic Fertiliser and Oil Palm Empty Fruit Bunch and Their Influence on Bacterial Species Dominance and Degradation of the Associated Crude Oil Constituents

The effects of inorganic commercial fertiliser (N:P:K = 8:8:1) and oil palm empty fruit bunch (EFB) as nutrient amendments for crude oil degradation and microbial population shift by a microbial consortium [Pseudomonas sp. (UKMP-14T), Acinetobacter sp. (UKMP-12T), Trichoderma sp. (TriUKMP-1M and TriUKMP-2M)] were assessed. The bacterial populations present during crude oil degradation were analysed by spread plate method and 16S rRNA sequences, whereas the presence of fungi was assessed by growth on potato dextrose agar. Crude oil degradation analysed using gas chromatography-flame ionisation detection showed total petroleum hydrocarbon reduced between 70 and 100%, depending on the type of amendments compared to control (≈55%) after 30 days of incubation. Nutrient amendments using NPK fertiliser or EFB were found to influence the domination of different bacterial species, which in turn preferentially utilised different hydrocarbons. This study suggested different nutrient amendments could be used to preferentially select bacteria to degrade different components of crude oil, particularly pertaining to the recalcitrant phytane. This information is very useful for application of in situ bioremediation of soil hydrocarbon contamination.     

Biodegradation of petroleum hydrocarbons in estuarine sediments: metal influence

In this work, the potential effect of metals, such as Cd, Cu and Pb, on the biodegradation of petroleum hydrocarbons in estuarine sediments was investigated under laboratory conditions. Sandy and muddy non-vegetated sediments were collected in the Lima River estuary (NW Portugal) and spiked with crude oil and each of the metals. Spiked sediments were left in the dark under constant shaking for 15 days, after which crude oil biodegradation was evaluated. To estimate microbial abundance, total cell counts were obtained by DAPI staining and microbial community structure was characterized by ARISA. Culturable hydrocarbon degraders were determined using a modified most probable number protocol. Total petroleum hydrocarbons concentrations were analysed by Fourier Transform Infrared Spectroscopy after their extraction by sonication, and metal contents were determined by atomic absorption spectrometry. The results obtained showed that microbial communities had the potential to degrade petroleum hydrocarbons, with a maximum of 32 % degradation obtained for sandy sediments. Both crude oil and metals changed the microbial community structure, being the higher effect observed for Cu. Also, among the studied metals, only Cu displayed measurable deleterious effect on the hydrocarbons degradation process, as shown by a decrease in the hydrocarbon degrading microorganisms abundance and in the hydrocarbon degradation rates. Both degradation potential and metal influence varied with sediment characteristics probably due to differences in contaminant bioavailability, a feature that should be taken into account in developing bioremediation strategies for co-contaminated estuarine sites.     

Removal of hydrocarbons from liquid media by Aspergillus niger van Tieghem

This study investigated the abiliy of Aspergillus niger van Tieghem to utilize crude oil and kerosene. Hydrocarbons are molecules that pose serious environmental problem because of their toxic, carcinogenic or teratogenic properties. The fate of these pollutants in the environment is mainly governed by the biodegradation process. The existence of these phenomena depends on the inherent biodegradability of the pollutant but also the presence of microflora-degrading competent.The microbial strain were isolated and identified from industrial wastewater samples from Sonatrach Skikda (North-east of Algeria), we selected them for their ability to grow in the presence of hydrocarbons. To test the ability to biodegrade the two selected hydrocarbons in 6 days, the study of the evolution of such parameters as the microbial kinetics, pH, the final dry weight of the population, oxygen concentration, and finally, biodegradation rate of crude oil and kerosene was conducted by high performance liquid chromatography (HPLC). A control test was performed to quantify the losses caused by abiotic factors.The filamentous fungus was found to degrade crude oil and kerosene, when previously grown mycelium was incubated 6 days in the Galzy and Slonimski media containing hydrocarbon. The results showed that these organisms were able to utilize crude oil more than kerosene and the degradation rate was 52.01% and 32.67%, respectively. Thus Aspergillus niger van Tieghem plays a major role in the detoxification of polluted natural environments and these capabilities could be explored in bioremediation processes.