石油烃类的微生物降解

石油作为重要能源之一已被世界各国广泛使用,由于在石油的开采、储存、运输、加工和石化产品生产等过程中的漏油以及突发性泄油事故致使大量的石油进入环境造成污染。石油污染的危害主要表现在对土壤生态系统的结构和功能的破坏,严重影响土壤的透气性和渗水性,导致土壤板结、肥力下降;在水体表面形成油膜,致使水中溶氧量急剧下降,造成水生生物的大量死亡,破坏水生生态环境和渔业资源;还可进入地下水系,直接污染地下水源,影响居民用水和农田灌溉;石油中的一些致畸致癌物质还可通过食物链的生物富集作用而直接危害人类健康。随着人们对环境问题的日益关注,石油烃类的微生物降解研究工作也不断得以深入。近十年来这一领域又有许多研究和相关报道,本文对相关工作进行了综述。     

石油烃类有机污染物对海洋浮游动物存活力的影响研究

浮游动物是各种经济鱼类的重要饵料,也是人们寻找渔场的标志,对渔业生产有很大的作用。石油等烃类有机物在人类的生产生活中扮演着重要的角色,然而其在开采、运输中发生的泄漏事故,给自然环境带来严重污染,并通过食物网传递、扩大,给生物带来巨大的伤害。本项目以沿岸海域常见浮游桡足类为研究对象,通过分析石油烃类有机污染物对其生殖的影响,来评价有机污染对海洋食物链及生态环境的破坏,为保护海洋环境,维持生态平衡提供理论支持。     

低温微生物修复石油烃类污染土壤研究进展

耐冷菌、嗜冷菌等低温微生物广泛存在于极地、高山以及高纬度等土壤环境中,是石油烃类污染物在低温条件下降解与转化的重要微生物资源.利用低温微生物的独特优势,石油污染土壤的低温生物修复技术的研究成为当前热点领域.本文系统综述了低温石油烃降解菌的分类及冷适机制,低温微生物对不同类型石油烃组分的降解特征和降解机理,低温环境中接种降解菌、添加营养物质和表面活性剂等强化技术在石油污染土壤中生物修复的应用.以及微生物分子生物学技术在低温微生物降解石油烃的研究现状,为拓展我国石油污染土壤生物修复技术提供参考.     

微生物强化修复石油污染土壤的研究进展

微生物修复被认为是去除石油污染物和修复石油污染土壤的一种经济、高效且无二次污染的绿色清洁技术。受土壤环境条件和石油污染物性质等因素制约,土壤中土著石油降解微生物常存在数量不足、活性偏低、生长缓慢等问题,导致修复效果不佳、修复周期偏长。微生物强化修复技术可有效提高微生物降解效能,通过投加具有降解效能的功能菌株或菌剂、营养物质、表面活性剂、生长基质及固定化微生物等手段,可改善提升土著微生物对石油污染土壤的修复效果。文中梳理了已报道的石油降解微生物的种类,总结了微生物修复石油污染土壤的主要影响因素,阐述了微生物强化修复石油土壤的多种有效策略,提出了微生物强化修复石油污染的未来发展方向。     

胜利油田采油区土壤石油污染状况及其微生物群落结构

基于不同开采年代新油井(2011—)和老油井(1966—2003年)周边土壤的调查取样,研究了采油区土壤石油污染状况,利用PCR-DGGE和克隆测序技术,探讨了新、老油井周边土壤微生物的群落结构.结果表明:油井周边土壤均受到不同程度的石油污染,其石油烃含量大多高于土壤石油污染临界值(500 mg·kg^-1),且老油井周边土壤污染水平更高.污染土壤石油烃含量与土壤有机碳、全氮和速效钾含量呈显著正相关.老油井周边土壤微生物群落多样性指数随污染水平的增大而减小,新油井则呈相反的趋势.DGGE图谱优势条带测序结果表明,油井周边土壤均存在明显的优势菌,大多为石油烃相关菌和烃类降解菌,如微杆菌属、链霉菌属、迪茨氏菌属、黄杆菌属及α、γ变形菌等.
     

生物反应器法处理油泥污染土壤的研究

采油过程产生的油泥是整个石油烃污染源的重点。在陆地生态环境中 ,烃类的大量存在往往对植物的生物学质量产生不利影响 ,更重要的是石油中的一些多环芳烃是致癌和致突变物质 ,这些致癌和致突变的有机污染物进入农田生态系统后 ,在动植物体内逐渐富集 ,进而威胁人类的生存和健康[1 ,1 1 ] 。大量的废弃油泥 ,不仅污染农田 ,同时也给石油行业带来巨大的经济损失。污染土壤的治理主要有物理、化学和生物 (生物修复 )方法 ,生物修复方法被认为最有生命力。污染土壤生物修复技术主要有 3种 ,即原位处理、挖掘堆置处理和反应器处理。反应器处理是…     

微生物勘探技术在能源勘探中的应用

<正>目前流行的石油、天然气和铀矿开采技术,主要是基于地质科学和地球物理科学的勘探技术。而基于微生物技术的烃类气体勘探技术则较为少用。烃类气体勘探技术的基础是烃类气体能够通过油气藏储层结构的土壤缝隙向地表迁移。早期的石油和天然气勘探就是通过甲烷或原油的地表面微渗漏发     

烃降解菌株T7-2产生的生物乳化剂及其理化性质研究

从石油污染海域海底泥中筛选到的1株低温石油烃降解菌, 经鉴定为红平红球菌(Rhodococcus erythropolis), 命名为T7-2。该菌株能以十六烷为碳源代谢产生一种对柴油等烃类具良好乳化作用的生物乳化剂。研究表明, 该乳化剂主要由糖类、脂类和蛋白质组成, 其比例为55.43:31.24:12.65。进一步研究证实, 该乳化剂糖类的单糖组成为甘露糖和鼠李糖; 脂类由十碳、十二碳、十六碳及十八碳脂肪酸组成; 蛋白质由16种氨基酸构成。本文还对乳化剂的理化性质进行了分析, 发现它是一种性能稳定、乳化效率高、适应范围较为广泛的生物乳化剂, 对海洋污染生物修复及石油开采都具有潜在的应用价值。     

土壤与水体有机污染的生物修复及其应用研究进展

系统论述了土壤、水有机污染物的主要来源、特点、有机污染生物修复的概念、应用范围、成功实例与研究进展等,特别是对于泄漏石油污染的生物成功降解方法、效果,土壤中易爆炸物如ＴＮＴ、废水中有机污染的有效降解等,评价了生物修复所具有突出优势,对有机、无机污染物降解过程中植物、微生物筛选、基因修饰、分子克隆与转基因植物方面近年来所取得的惊人成果与突破性进展,无疑正激励着人们开拓更大的应用范围。预计不久的将来,更多具有环境净化与生物修复功能的商业性综合技术与高效性工程生物将投入应用。     

石油烃类化合物降解菌的研究概况

综述了国内外艰石油烃类化合物的微生物降解的研究情况,分别就石油烃类化合物各组分微生物降解率、不同组分的微生物代谢途径、降解菌各类、降解性质粒、工程菌以及修复方法进行了介绍,以期全面反映此领域的研究,为研究工作提供一定参考依据。     

Microwave-Assisted Process (MAPTM) for the Extraction of Contaminants from Soil

Laboratory-scale tests were performed to evaluate the use of Environment Canada's patented Microwave-Assisted Process (MAP_TM) for the extraction of petroleum hydrocarbons from contaminated soil. The purpose of these tests was to determine the potential for using the process for large-scale processing of contaminated soil. Tests were performed using three soil types: a certified sediment and certified soil, both contaminated with polycyclic aromatic hydrocarbons (PAHs), and spiked peat soil contaminated with long-chain petroleum hydrocarbons. The test methods used were based on existing MAP techniques that have been proven for the sample preparation of contaminated soils for analytical purposes. The parameters evaluated concentrated on those that are amenable to a continuous large-scale process running at atmospheric pressures. This meant using solvents that are inexpensive and readily available in large volumes, low solvent to material ratios, and optimized energy inputs. In general, it was found that microwaves could be used to enhance the solvent extraction of the contaminants from the soil and that the properties of the soil greatly affected the extent to which the contaminants were removed.     

Effect of salinity on the bioremediation of petroleum hydrocarbons in a saline-alkaline soil

Aims: The aim of this paper is to check the effect of salinity on the bioremediation process of petroleum hydrocarbons in the saline‐alkaline soil. Methods and Results: In this study, soil salinity was adjusted to different levels by water leaching method and the bioremediation process was conducted for 28 days. Soil pH increased after leaching and decreased during bioremediation process. At initial time, moderate salinity enhanced the biodegradation and addition of microbial consortium was not effective in enhancing degradation rate of petroleum hydrocarbons. At day of 28 days, higher degradation rate was found in treatments with more leaching times with a maximum value of 42·36%. Dehydrogenase activity increased with the progress of bioremediation and positive correlation was found between dehydrogenase activity and degradation rate of petroleum hydrocarbons. Denaturing gradient gel electrophoresis analysis result showed decreased microbial community diversity with increased salt content. Conclusions: The result suggested that salinity had great impact on bioremediation, and leaching and addition of inoculated consortium were effective in enhancing biodegradation of petroleum hydrocarbons in the saline‐alkaline soil. Significance and Impact of the Study: The result of this study is important for understanding the bioremediation process of petroleum in contaminated soil. New remediation method of petroleum contaminated soil can be developed based on this study.     

Profiling of plants at petroleum contaminated site for phytoremediation

The paucity of information in the literature on the characteristics of plants that could be used for phytoremediation of petroleum hydrocarbons (PHC)-contaminated sites was the principal reason for this study. The aim of the study was to identify indigenous plants growing in PHC-impacted soil in Umuahia in eastern-Nigeria that have the ability to phytoremediate soils contaminated with hydrocarbons under tropical monsoon climate conditions. A total of 28 native plant species from different families growing in and around hydrocarbon-impacted soil in the vicinity of vandalized pipelines carrying petroleum products were collected and studied for their ability to grow in a hydrocarbon-impacted soil and remove the PHC from the impacted soil. Some of the plants demonstrated the ability to grow in soil with high levels of the total petroleum hydrocarbons (TPH), which shows that they may be tolerant to hydrocarbons in soil and could potentially phytoremediate a hydrocarbon-contaminated soil. Chromolaena odorata, Aspilia africana, Chloris barbata, Pasparlum vaginatum, Bryophyllum pinnatum, Paspalum scrobiculatum, Cosmos bipinnatus, Eragrostis atrovirens, Cyperus rotundus, and Uvaria chamae showed tendencies to phytoremediate contaminated soil. By using bioaccumulation coefficient (BAC) as a measure of phytoremediation, results showed that C. odorata, A. africana, and U. chamae demonstrated the highest potentials to phytodegrade hydrocarbons in soil.     

不同类型原油污染土壤生物修复技术研究

对不同类型原油污染土壤在实用规模的预制床上采用堆制技术进行生物修复 .通过投加肥料、菌剂、控制水分和pH ,可使微生物获得较好的生态环境 .当稀油、高凝油、特稠油和稠油污染的土壤中原油总量为 2 5 .8～ 77.2 g·kg-1土时 ,经过近 2个月的运行 ,石油总量的去除率可达 38.37%～ 5 6 .74 % .石油中芳烃、沥青和胶质混合物是制约石油快速降解的主要因素 .在处理过程中筛选出石油降解的优势菌株 ,其中有 6株真菌、6株细菌和 1株放线菌 .研究结果为石油污染土壤异位生物修复技术实用化提供了理论依据 .     

Comparative Mesocosm Study of Biostimulation Efficiency in Two Different Oil-Amended Sub-Antarctic Soils

Biological treatment has become increasingly popular as a remediation method for soils and groundwater contaminated with petroleum hydrocarbon, chlorinated solvents, and pesticides. Bioremediation has been considered for application in cold regions such as Arctic and sub-Arctic climates and Antarctica. Studies to date suggest that indigenous microbes suitable for bioremediation exist in soils in these regions. This paper reports on two case studies at the sub-Antarctic Kerguelen Island in which indigenous bacteria were found that were capable of mineralizing petroleum hydrocarbons in soil contaminated with crude oil and diesel fuel. All results demonstrate a serious influence of the soil properties on the biostimulation efficiency. Both temperature elevation and fertilizer addition have a more significant impact on the microbial assemblages in the mineral soil than in the organic one. Analysis of the hydrocarbons remaining at the end of the experiments confirmed the bacterial observations. Optimum temperature seems to be around 10 degrees C in organic soil, whereas it was higher in mineral soil. The benefit of adding nutrients was much stronger in mineral than in the organic soil. Overall, this study suggests that biostimulation treatments were driven by soil properties and that ex situ bioremediation for treatment of cold contaminated soils will allow greater control over soil temperature, a limiting factor in cold climates.     

Enhancing Degradation of Total Petroleum Hydrocarbons and Uptake of Heavy Metals in a Wetland Microcosm Planted with Phragmites Communis by Humic Acids Addition

The effects of humic acid (HA) on heavy-metal uptake by plants and degradation of total petroleum hydrocarbons (TPHs) in a wetland microcosm planted with Phragmites communis were evaluated by comparing waterlogged soils and water-drained upland soils. Experiments were conducted on soils artificially contaminated with heavy metals (Pb, Cu, Cd, Ni) and diesel fuel. HA showed a positive influence on biomass increase for all conditions, but more for belowground than aboveground biomass, and lower in contaminated than uncontaminated soil. The bioavailability and leachability factor (BLF) for all heavy metals except Ni increased with HA addition in both the control and the P. communis planted microcosms, suggesting that more heavy metals could be potentially phytoavailable for plant uptake. Microbial activities were not affected by both heavy metals and TPH contamination, and HA effects on stimulating microbial activities were much greater in the contaminated soil than under uncontaminated conditions. HA addition enhanced the degradation of TPH and n-alkane in waterlogged conditions. The results show that HA can increase the remedial performance in P. communis dominated wetlands simultaneously contaminated with heavy metals and petroleum hydrocarbons and thus prevent contamination of groundwater or other adjacent ecosystems.     

Crude petroleum-oil biodegradation efficiency of Bacillus subtilis and Pseudomonas aeruginosa strains isolated from a petroleum-oil contaminated soil from North-East India

The efficiency of Bacillus subtilis DM-04 and Pseudomonas aeruginosa M and NM strains isolated from a petroleum contaminated soil sample from North-East India was compared for the biodegradation of crude petroleum-oil hydrocarbons in soil and shake flask study. These bacterial strains could utilize crude petroleum-oil hydrocarbons as sole source of carbon and energy. Bioaugmentation of TPH contaminated microcosm with P. aeruginosa M and NM consortia and B. subtilis strain showed a significant reduction of TPH levels in treated soil as compared to control soil at the end of experiment (120 d). P. aeruginosa strains were more efficient than B. subtilis strain in reducing the TPH content from the medium. The plate count technique indicated expressive growth and biosurfactant production by exogenously seeded bacteria in crude petroleum-oil rich soil. The results showed that B. subtilis DM-04 and P. aeruginosa M and NM strains could be effective for in situ bioremediation.     

Screening Plant Species for Growth on Weathered,Petroleum Hydrocarbon-Contaminated Sediments

Rapid and cost-effective techniques are needed to select plant species and genotypes for use in phytoremediation, vegetative capping, or revegetation at hazardous waste sites. A greenhouse screening procedure to aid the selection of plant materials would help increase success and decrease the cost. Twenty-nine vascular plant species were compared for growth in weathered sediments contaminated with petroleum hydrocarbons. An uncontaminated reference soil was used to estimate relative seedling growth in stressed and unstressed conditions. Plants were grown in a greenhouse and harvested at 60 and 180 days after planting to estimate variation in seedling growth and full-season growth. Plant growth characteristics measured included height, aboveground biomass, root biomass, root diameter, root-length density, and root surface area density. Concentration of total petroleum hydrocarbons (TPH) was estimated at the final harvest. Considerable variation existed among species for all characteristics except TPH concentration. Under the conditions and length of this trial, no variations in rates of TPH degradation were detected. In general, plant growth was stunted in the contaminated soil compared with the uncontaminated soil; however, differences among plant species for relative seedling growth indicated that they varied in their tolerance to the petroleum hydrocarbon-contaminated soil. For example, tall fescue, Festuca arundinacea, seemed tolerant to the contaminated soil, whereas barley, Hordeum vulgare, seemed sensitive. Comparison of results from the 60- and 180-day harvests suggested that a short-season greenhouse screening could aid selection of species for planting in contaminated soil, if plant growth results are interpreted along with information on the life history characteristics of the species under consideration.     

Biostimulation of micro-organisms from sugarcane bagasse pith for the removal of weathered hydrocarbon from soil

AIMS: In this study we studied the biostimulation of micro-organisms associated with sugarcane bagasse pith for the removal of total petroleum hydrocarbon from a soil contaminated with weathered hydrocarbon. METHODS AND RESULTS: Carbon, nitrogen and phosphorus were added at a ratio of 100 : 10 : 1, water content of 40%, and soil : bagasse ratio of 49 : 1. A significant positive difference (P < 0.05) was observed in total petroleum hydrocarbon removal (38 and 48%) by micro-organisms associated with bagasse and native soil micro-organisms, respectively. In addition, total petroleum hydrocarbon removal increased to 60% in a system where both autochthonous soil and bagasse micro-organisms were present. CONCLUSIONS: Micro-organisms from sugarcane bagasse pith can be stimulated for removal of weathered hydrocarbon from contaminated tropical soils, without they being inhibited by indigenous soil micro-organisms. SIGNIFICANCE AND IMPACT OF THE STUDY: Soil of with hydrocarbons can be diminished by stimulation of autochthonous microflora present in soil and agricultural residues. This work contributes to the microbiology of composting, as low amounts of bulking agents for hydrocarbon removal from soil, can be used.