生物反应器法处理PAHs污染土壤的研究

利用自行设计的生物泥浆反应器研究了多环芳烃 (PAHs)污染土壤生物修复技术 .结果表明 ,在相同环境条件下 ,污染物自身的理化性质是影响生物修复的关键因素 ,苯环越多、分子量越大 ,越难以被微生物利用 ,故菲 (PHE)比芘 (PY)具有更高的污染可修复性 .温度、空气流量是重要的调控因子 .本实验中 ,生物泥浆反应器处理PAHs污染土壤选择的最佳运行工艺参数是 :温度 2 0～ 30℃ ,水土比 2∶1,空气流量8L·h-1·L-1,接种量 5 0g·kg-1.该工艺参数为生物泥浆反应器技术实用化及其他相关研究工作的深入开展提供了理论依据     

土壤中高环多环芳烃微生物降解的研究进展

微生物修复是去除土壤中多环芳烃(PAHs)的主要措施。本文以微生物修复PAHs污染土壤的理论基础及其难点为主线,全面综述了土壤中高环PAHs的微生物降解机理。近年来,富集分离得到的以高环PAHs为唯一碳源和能源的优势降解菌逐渐增多,其中,主要是代谢降解四环PAHs的单株降解菌,一些降解菌还能以共代谢方式利用五环PAHs。高环PAHs污染土壤修复的一个难点是其低生物可利用性,微生物通过释放生物表面活性剂、形成生物膜以及分泌胞外多糖提高高环PAHs的生物可利用性,从而加速其降解。真菌和细菌联合作用能增强污染土壤实地修复的效果。因此,通过微生物修复技术来去除土壤中PAHs具有环境友好性、经济适用性以及可持续应用性。     

土壤中高分子量PAHs微生物降解机理及影响因素研究进展

高分子量多环芳烃( HMW PAHs)分子结构复杂,疏水性强,是环境中广泛存在的难降解的有机污染物.微生物降解是去除HMW PAHs的主要途径.本文介绍了PAHs降解菌株的种类和降解机理,以及不同环境因子(营养元素、pH值、土壤结构、通气状况和复合污染)对HMW PAHs降解的影响,提出HMW PAHs污染土壤的进一步研究的方向与重点,旨在为HMW PAHs污染修复研究和微生物降解机理研究提供参考.     

土壤中多环芳烃的微生物降解及土壤细菌种群多样性

利用室内模拟方法,研究中、低浓度多环芳烃(PAHs)污染土壤的微生物修复效果,阐明土壤微生物（接种和土著）与PAHs降解的关系.结果表明：投加PAHs高效降解菌可以促进土壤中PAHs的降解,2周内效果显著;典型PAHs降解的难易程度依据为：菲<蒽<芘<苯并(a)芘和屈;细菌种群丰度和多样性均与PAHs降解呈负相关关系,同一处理细菌种群结构随时间变化不大.对于中、低浓度PAHs原位污染土壤,增强土著菌的活性是提高土壤PAHs降解率的有效途径之一.     

高环多环芳烃降解菌的筛选及其降解特性

通过富集培养及平板升华法从本溪钢铁公司周边多环芳烃(PAHs)污染土壤中分离出7株PAHs降解菌。以芘和苯并[a]芘为底物进行摇瓶降解实验,结果表明:G1、G2和G3菌株对高环PAHs芘和苯并[a]芘均具有较强的降解能力。进一步研究此3株菌及混合菌对原状污染土壤中PAHs的降解能力,发现80 d时对总PAHs的降解顺序依次为:混合菌G2G1G3,其中混合菌对PAHs降解率较单菌分别提高了9.17%、11.49%和16.11%;4个处理对4~6环PAHs的降解率较对照组相比提高的倍数随着环数增加而增大;总PAHs的降解率与脱氢酶的活性呈正相关。电场影响G1、G2和G3菌株对PAHs降解,在1.0 V·cm~(-1)电场条件下,4环、5环及6环PAHs降解率较单纯微生物修复提高12.13%、13.35%和14.52%,说明3株菌具有较强的电场适应能力,可在高环PAHs污染土壤的电动-微生物修复中应用。形态学观察及16S rRNA序列比对分析表明,G1、G2、G3菌株分别为鞘氨醇单胞菌属(Sphingomonas sp.)、苍白杆菌属(Ochrobactrum sp.)和无色杆菌属(Achromobacter sp.)。     

多环芳烃污染土壤生物修复研究进展

多环芳烃 (Polycyclic aromatic hydrocarbons,PAHs) 是一类广泛分布于环境中的持久性污染物,结构稳定、难以降解,对生态环境和生物具有“三致”毒害性,其环境去除和修复备受关注。绿色、安全、经济的生物修复技术被广泛应用于PAHs污染土壤的修复。本文从土壤中PAHs的来源、迁移、归趋和污染水平总结了目前我国土壤多环芳烃污染的基本状况;归纳了具有PAHs降解作用的微生物、植物种类及机理;比较了微生物修复、植物修复和联合修复3类主要的生物修复技术。指出植物与微生物的互作机理的解析,抗逆菌株、植株的筛选与培育,实际应用的安全和效能评估应成为多环芳烃污染土壤修复领域未来的研究方向。     

油田区多环芳烃污染盐碱土壤活性微生物群落结构解析

多环芳烃(Polycyclic aromatic hydrocarbons,PAHs)是土壤中广泛存在的、美国环保总署(USEPA)优先控制的一类有毒(致癌、致突变)的持久性污染物,主要来源于人类活动。土壤微生物多样性是表征土壤质量变化的敏感指标之一。磷脂脂肪酸(PLFAs)分析方法是基于活性微生物细胞膜的PLFAs组分的生化检测技术,克服了传统培养方法只能分离出少量微生物(1%)的缺点。采用PLFAs方法,解析了土壤活性微生物对PAHs污染胁迫的反应。结果表明,土壤微生物分布情况可分为4种类型:Ⅰ型,微生物PLFAs种类最多,占该区土壤微生物PLFAs种类总数的57.7%,PAHs对变量的解释量最小;Ⅱ型,微生物PLFAs占PLFAs总数的30.8%,PAHs对变量的解释量较小;Ⅲ型,微生物PLFAs种类占总数的7.68%,PAHs对变量的解释量较大;Ⅳ型,微生物PLFAs的种类仅占总数的3.85%,PAHs对变量的解释量最大。相关性分析表明:土壤微生物PLFAs的种类、生物量和生态多样性指数与土壤中萘(Nap)、芴(Flu)、蒽(Ant)、苯并[K]荧蒽(Bkf)、苯并[a]芘(Bap)、茚并[1,2,3-cd]芘(Ind)的相对含量呈负相关关系;与苊(Ace)、菲(Phe)、荧蒽(Fla)、芘(Pyr)、苯并[a]蒽(Baa)的相对含量呈正相关关系;与PAHs的种类和浓度呈负相关关系。结果将为开展PAHs污染土壤的生态风险评价和微生物生物修复技术研究提供理论依据。     

植物-固定化菌剂联合修复多环芳烃污染土壤

以火凤凰根际土壤中发现的3种优势菌[分枝杆菌(Ⅰ)、产黄纤维单胞菌(Ⅱ)、少动鞘氨醇单胞菌(Ⅲ)]构建的多菌剂体系为供试菌剂,针对大港油田原油污染土壤,将固定化供试菌剂接种于修复植物火凤凰根际,探讨供试菌剂强化火凤凰修复多环芳烃(PAHs)污染土壤的效果。结果表明: 处理ⅠⅢ(有效活菌数为10⁹ cfu·mL^-1)和ⅠⅡⅢ(有效活菌数为10⁷ cfu·mL^-1)对PAHs的降解有促进作用,PAHs降解率分别为32.2%和41.4%,均显著高于相应对照处理。此外,处理ⅠⅡⅢ对火凤凰的地下生物量有明显促进作用,比对照处理增加了31.2%。表明由3种优势菌构建的多菌剂ⅠⅡⅢ可以作为火凤凰修复PAHs污染土壤的强化手段,为微生物强化植物修复技术提供了新的修复思路及方法。     

多环芳烃(PAHs)微生物降解的原位表征方法

多环芳烃(polycyclic aromatic hydrocarbons,PAHs)是一类在环境中广泛存在的持久性有机污染物,微生物降解是去除环境中多环芳烃污染的主要途径。传统的有关PAHs微生物降解的研究主要依靠分离培养技术,难以准确认识PAHs微生物降解的原位过程及机制。近年来发展起来的原位表征方法可以在基因及单细胞水平研究PAHs在复杂环境中的微生物降解过程,能够原位表征具有PAHs降解功能的微生物及其功能基因和代谢活性,是阐明PAHs原位降解过程及分子机制的强有力的手段。该文综述了宏基因组技术(meta-genomics)、稳定同位素探针技术(stable isotope probe,SIP)、荧光原位杂交技术(fluorescence in situ hybridization,FISH)、拉曼光谱技术(Raman spectra)以及二次离子质谱技术(secondary ion mass spectrometry,SIMS)等原位表征技术在PAHs微生物降解研究领域的应用及其存在的问题和发展趋势等。PAHs微生物降解过程及机制的原位表征将为缓解与修复PAHs污染提供科学基础。     

多环芳烃污染生物修复研究进展

多环芳烃(polycyclic aromatic hydrocarbon,PAHs)是一类对环境有严重危害的持久性有机污染物。具有高生物富集性、致癌性、致毒性和难降解性,修复治理PAHs污染环境备受国内外政府及学者的关注。目前主要采用物理、化学以及生物方法对多环芳烃污染的土壤和水体进行修复。其中生物修复是一种高效、经济和生态可承受的环保技术,具有成本低、无二次污染等优点。本文从植物修复、微生物修复以及植物-微生物联合修复方面,阐述了国内外生物修复PAHs污染的最新研究进展。指出了生物修复PAHs污染环境需要进一步解决的问题,并对未来发展趋势进行了展望。     

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…     

Phenanthrene stimulates the degradation of pyrene and fluoranthene by <Emphasis Type="Italic">Burkholderia</Emphasis> sp. VUN10013

Pyrene and fluoranthene, when supplied as the sole carbon source, were not degraded by Burkholderia sp. VUN10013. However, when added in a mixture with phenanthrene, both pyrene and fluoranthene were degraded in liquid broth and soil. The amounts of pyrene and fluoranthene in liquid media (initial concentrations of 50 mg l⁻¹ each) decreased to 42.1% and 41.1%, respectively, after 21 days. The amounts of pyrene and fluoranthene in soil (initial concentrations of 75 mg kg⁻¹ dry soil each) decreased to 25.8% and 12.1%, respectively, after 60 days. None of the high molecular weight (HMW) polycylic aromatic hydrocarbons (PAHs) tested adversely affected phenanthrene degradation by this bacterial strain and the amount of phenanthrene decreased rapidly within 3 and 15 days of incubation in liquid broth and soil, respectively. Anthracene also stimulated the degradation of pyrene or fluoranthene by Burkholderia sp. VUN10013, but to a lesser extent than phenanthrene. The extent of anthracene degradation decreased in the presence of these HMW PAHs.     

Characterization of a Polycyclic Aromatic Hydrocarbon-Degrading Microbial Consortium from a Petrochemical Sludge Landfarming Site

Anthracene, phenanthrene, and pyrene are polycyclic aromatic hydrocarbon (PAHs) that display both mutagenic and carcinogenic properties. They are recalcitrant to microbial degradation in soil and water due to their complex molecular structure and low solubility in water. This study presents the characterization of an efficient PAH (anthracene, phenanthrene, and pyrene)-degrading microbial consortium, isolated from a petrochemical sludge landfarming site. Soil samples collected at the landfarming area were used as inoculum in Warburg flasks containing soil spiked with 250 mg kg^-1 of anthracene. The soil sample with the highest production of CO₂-C in 176 days was used in liquid mineral medium for further enrichment of anthracene degraders. The microbial consortium degraded 48%, 67%, and 22% of the anthracene, phenanthrene, and pyrene in the mineral medium, respectively, after 30 days of incubation. Six bacteria, identified by 16S rRNA sequencing as Mycobacterium fortuitum, Bacillus cereus, Microbacterium sp., Gordonia polyisoprenivorans, two Microbacteriaceae bacteria, and a fungus identified as Fusarium oxysporum were isolated from the enrichment culture. The consortium and its monoculture isolates utilized a variety of hydrocarbons including PAHs (pyrene, anthracene, phenanthrene, and naftalene), monoaromatics hydrocarbons (benzene, ethylbenzene, toluene, and xylene), aliphatic hydrocarbons (1-decene, 1-octene, and hexane), hydrocarbon mixtures (gasoline and diesel oil), intermediary metabolites of PAHs degradation (catechol, gentisic acid, salicylic acid, and dihydroxybenzoic acid) and ethanol for growth. Biosurfactant production by the isolates was assessed by an emulsification index and reduction of the surface tension in the mineral medium. Significant emulsification was observed with the isolates, indicating production of high-molecular-weigh surfactants. The high PAH degradation rates, the wide spectrum of hydrocarbons utilization, and emulsification capacities of the microbial consortium and its member microbes indicate that they can be used for biotreatment and bioaugumentation of soils contaminated with PAHs.     

PAH Degradation Capacity of Soil Microbial Communities—Does It Depend on PAH Exposure?

Polycyclic aromatic hydrocarbons (PAHs) are ubiquitous pollutants of the environment. But is their microbial degradation equally wide in distribution? We estimated the PAH degradation capacity of 13 soils ranging from pristine locations (total PAHs ≈ 0.1 mg kg^?1) to heavily polluted industrial sites (total PAHs ≈ 400 mg kg^?1). The size of the pyrene- and phenanthrene-degrading bacterial populations was determined by most probable number (MPN) enumeration. Densities of phenanthrene degraders reflected previous PAH exposure, whereas pyrene degraders were detected only in the most polluted soils. The potentials for phenanthrene and pyrene degradation were measured as the mineralization of ¹⁴C-labeled spikes. The time to 10% mineralization of added ¹⁴C phenanthrene and ¹⁴C pyrene was inversely correlated with the PAH content of the soils. Substantial ¹⁴C phenanthrene mineralization in all soils tested, including seven unpolluted soils, demonstrated that phenanthrene is not a suitable model compound for predicting PAH degradation in soils. ¹⁴C pyrene was mineralized by all Danish soil samples tested, regardless of whether they were from contaminated sites or not, suggesting that in industrialized areas the background level of pyrene is sufficient to maintain pyrene degradation traits in the gene pool of soil microorganisms. In contrast, two pristine forest soils from northern Norway and Ghana mineralized little ¹⁴C pyrene within the 140-day test period. Mineralization of phenanthrene and pyrene by all Danish soils suggests that soil microbial communities of inhabited areas possess a sufficiently high PAH degradation capacity to question the value of bioaugmentation with specific PAH degraders for bioremediation.     

Ex situ bioremediation of pyrene contaminated soil in bio-slurry phase reactor operated in periodic discontinuous batch mode: Influence of bioaugmentation

Ex situ treatment of simulated pyrene-contaminated soil was studied in bio-slurry phase reactors operated in periodic discontinuous batch mode under anoxic–aerobic–anoxic–anoxic microenvironment. Experiments were performed in six different bio-slurry phase reactors (retention time of 120 h; soil loading rate of 20 kg soil/m³-day; operating temperature at 28±2 °C) by varying substrate concentration (substrate loading rate (SLR), 0.12, 0.24 and 0.36 g pyrene/kg soil-day) and bioaugmentation application (domestic sewage inoculum; CFU—2×10⁶). The performance of slurry phase reactors was found to be dependent on the applied SLR and application of bioaugmentation (domestic sewage as augmented inoculum). Control reactor (killed control) showed only 6% of pyrene degradation while the non-augmented reactor showed an efficiency of 34% (substrate degradation rate (SDR)—0.0165 g pyrene/kg soil-day). In the case of augmented reactors, the system operated with low SLR showed a pyrene degradation efficiency of almost 90% (SDR—0.04 g pyrene/kg soil-day) and the reactor with high SLR showed 50% (SDR—0.025 g pyrene/kg soil-day) of pyrene degradation indicating the dependence of performance on the substrate concentration. Colony forming units (CFUs) variation was in good agreement with the performance of the reactors with respect to pyrene degradation. On the whole, pyrene degradation rate was greater in the augmented reactors compared to non-augmented reactors.     

接种功能内生细菌Diaphorobacter sp.Phe15减少蔬菜亚细胞菲积累的体外试验研究

[目的]土壤中的多环芳烃(polycyclic aromatic hydrocarbons, PAHs)可被蔬菜根系吸收并在可食部分积累进而通过食物链威胁人群健康。接种功能内生细菌能有效减低蔬菜中PAHs的积累,而关于其对蔬菜亚细胞组分中PAHs积累的影响却鲜有报道。[方法]采用体外实验,研究了接种具有菲降解功能的菌株Diaphorobacter sp. Phe15对空心菜茎叶亚细胞组分中菲积累的影响及PAHs代谢相关酶活性的响应。[结果]接种Phe15可以可加速空心菜茎叶亚细胞中菲的降解,显著削减空心菜亚细胞组分中菲的含量,接菌后空心菜亚细胞组分中菲降解率达90%以上。此外,接种功能菌Phe15可以影响空心菜亚细胞组分中PAHs代谢相关酶系的活性,空心菜亚细胞水平POD、PPO、C230活性整体得到提高,且酶系活性与空心菜体内菲积累呈负相关关系。[结论]接种具有菲降解功能的菌株Phe15增加了空心菜亚细胞水平PAHs代谢相关酶系活性,进而降低空心菜体内菲的积累,研究结果为利用功能内生细菌削减蔬菜中多环芳烃污染提供了一定的参考和理论依据。     

乳白耙齿菌F17对单一和复合多环芳烃的降解差异解析

[目的] 针对菲、蒽、荧蒽多环芳烃（PAHs）污染物,利用乳白耙齿菌F17,研究单一和复合PAHs污染物的生物降解规律。[方法] 采用气相色谱-质谱法（GC-MS）分析降解过程中PAHs的浓度,并采用准一级反应动力学模型对降解结果进行拟合。[结果] 对于单一PAHs,第15天时菲、蒽、荧蒽的降解率由高到低依次为菲（97.8%） > 蒽（89.3%） > 荧蒽（81.5%）。菲、蒽和荧蒽的降解过程具有准一级反应动力学特征,菲的生物降解速率最快,其次是蒽,荧蒽的降解速率最慢。与单一PAHs的降解相比,在复合PAHs的降解过程中,乳白耙齿菌F17的生长和锰过氧化物酶的合成均表现出不同的特征。此外,水溶性极可能是复合污染物降解的重要控制因子,三者水溶性为：菲 > 荧蒽 > 蒽。因此,在菲或荧蒽加入条件下,微生物能优先降解这些污染物,抑制了污染物蒽的降解;同时,蒽或菲的存在对荧蒽的降解也有抑制作用;然而外源加入水溶性较差的蒽和荧蒽,则对菲的生物降解无显著影响。[结论] 复合PAHs的生物降解主要表现为相互竞争的特点,通过GC-MS分析了PAHs的生物降解途径。     

The development of phenanthrene catabolism in soil amended with transformer oil

Polycyclic aromatic hydrocarbons (PAHs) are ubiquitous environmental contaminants frequently associated with light non-aqueous-phase liquids (LNAPLs) in soil. Microbial degradation comprises a major loss process for PAHs in the environment. Various laboratory studies, using known degraders, have shown reduced or enhanced mineralisation of PAHs when dissolved in different LNAPLs. Effects due to the presence of LNAPLs on indigenous micro-organisms, however, are not fully understood. A pristine pasture soil was spiked with [14C]phenanthrene and transformer oil to 0, 0.01 and 0.1%, and incubated for 180 days. The catabolic potential of the soil towards phenanthrene was assessed periodically during ageing. The extent of the lag phase (prior to >5% mineralisation), maximum rates and overall extents of mineralisation observed during the course of a 14-day bioassay appeared to be dependent upon phenanthrene concentration, the presence of transformer oil, and soil-contaminant contact time. Putatively, transformer oil enhanced acclimation and facilitated the development of measurable catabolic activity towards phenanthrene in a previously uncontaminated pasture soil. Exact mechanisms for the observed enhancement, longer-term fate/degradation of the oil and residual phenanthrene, and effects of the presence of the oil on the indigenous microbes over extended time frames warrant further investigation.     

Microbial degradation of phenanthrene and pyrene in a two-liquid phase-partitioning bioreactor

A study was conducted to determine the potential of two-liquid phase-bioreactors for the treatment of (polycyclic aromatic hydrocarbons) PAHs. Phenanthrene and pyrene were supplied two times at a concentration of 100 mg/l of reactor broth, either as crystals or dissolved in silicone oil. Complete phenanthrene biodegradation was achieved within 3 days after each addition to the biphasic-inoculated reactor. Its concentration in the monophasic reactors dropped by 93% within 4 days, but remained incomplete for the duration of the experiment. Pyrene removal occurred to a limited extent only in the presence of phenanthrene. Significant pollutant losses were recorded in the monophasic reactors, most likely caused by volatilization. Pollutant degradation was improved upon repeated phenanthrene amendment to the biphasic system. Biphasic reactors allow the fast and complete degradation of PAHs and prevent their hazardous disappearance. The use of biphasic reactors for the degradation of poorly soluble pollutants should become more beneficial when the substrate-interface uptake mechanism is operating. Thus, biphasic reactors should be integrated into the microbial enrichment procedure.