Diaphorobacter sp.J5-51降解酚类污染物的特性

为强化酚污染的生物治理,提高酚类污染物的去除效率,采用单因素实验方法研究1株Diaphorobacter细菌(命名为J5-51)降解酚类物质的特性.结果显示,菌株J5-51在pH为6.0-9.0、温度为25-35℃的情况下均能较好地降解对氯酚;添加0.2 mmol/L的Ca~(2+)能够促进、而添加相同浓度的Co~(2+)和Ni~(2+)则抑制对氯酚的降解;菌株降解对氯酚的速度与对氯酚的初始浓度呈负相关关系;除对氯酚外,菌株还能降解吡啶、苯酚、2-甲酚、3-甲酚和4-甲酚.在优化的条件下,菌株可在72 h内完全降解焦化废水中约400 m g/L的苯酚和100 mg/L的甲酚;同时,对菌株J5-51进行固定化有利于其降解酚类化合物.综上认为,菌株J5-51在处理酚类化合物共污染环境的生物修复中具有一定的应用潜力.(图6参13)     

驯化的活性污泥强化降解土壤中氯酚的研究

以接种驯化的活性污泥为生物强化手段,在小型生物泥浆反应器中,研究了受氯酚污染土壤的修复情况.考查了添加驯化活性污泥对土壤中氯酚降解的强化效果,并对土壤中邻氯苯酚(2-CP)、对氯苯酚(4-CP)和2,4-二氯酚(2,4-DCP)在单一污染体系中的降解情况进行了研究.结果表明,在生物泥浆反应器中添加用邻氯苯酚(2-CP)驯化的活性污泥可以明显地促进土壤泥浆中2-CP的降解,是一种有效的强化手段.该方法对土壤中的4-CP和2,4-DCP也有较好的降解效果,对三种氯酚的降解速率由大到小的顺序为2-CP,4-CP,2,4-DCP.反应结束时,泥浆体系中剩余的氯酚基本都残留在土壤中,固液分离后的水相可以直接排放或者在土壤修复过程中循环利用.     

酚类化合物抑制斜生栅藻生长的毒性效应

本文运用评价化学品对藻类毒性的标准实验方法,得出苯酚,邻氯苯酚、２,４－二氯苯酚和五氯酚抑制斜生栅藻生长的９６ｈ－ＥＣ５０分别为３４１．８５,２５和１．５ｍｇ·１＾－１,实验结果表明,在３００,３５０和４００ｍｇ·ｌ＾－１三种本酚初始浓度下,斜生栅藻都不具备降解苯酚的能力,即使在培养基中基本没有无机碳源的情况下,斜生栅藻仍不具备降解苯酚的能力。     

氯代二恶英微生物降解性的初步探讨

本研究通过分离和筛选，从氯苯生产车间附近土壤和施用五氯酚除草剂的湖泊底泥中选出八支菌株，均能降解一氯代二恶英，３周内最多可降解４５％，但随氯取代数的增加而降解能力减弱，多数菌株不能降解三氯代二恶英，选择邻二氯苯为共代谢物的初级营养物，４１号株３周内可降解３３％三氯代苯基二恶英，说明选择适当的共代谢物，可改善微生物对高氯代二恶英的降解性。     

苯酚降解酵母Pd6的分离及对酚类化合物的降解

从炼油厂污染的污水和土壤中,筛选分离出一株具有很高苯酚降解能力的酵母菌Pd6.通过生理生化方法并结合26S rRNA序列比对,将其初步鉴定为麦芽糖假丝酵母(Candida maltosa).该酵母菌能以苯酚为唯一碳源和能源,对苯酚的最大降解浓度为1500mg/L,添加有机碳和有机氮可显著提高其对苯酚的降解率.在外加碳源的条件下,菌株Pd6还具有降解其它9种取代酚的能力.此外,关于苯酚和氯酚共代谢的研究表明,酵母菌Pd6可以利用苯酚为唯一碳源降解对氯酚和间氯酚.表明该菌在苯酚及其衍生物的生物降解和水污染治理方面可起到重要作用.     

五氯酚生物降解机理与外生菌根真菌对五氯酚可降解性

五氯酚是氯酚族中最具毒性和最难降解的有机污染物。不同种类的微生物由于其降解污染物的生化机制不同,使得五氯酚的降解途径多样化。文章通过综述好氧与厌氧微生物降解五氯酚的降解菌和降解途径,认为五氯酚首先通过脱氯转化为低氯代化合物后再开环,因此脱氯就成为五氯酚降解的关键步骤。参与脱氯的关键酶系主要包括过氧化物酶和酚氧化酶。外生菌根真菌可降解多种难降解有机污染物,并具有生成过氧化物酶和酚氧化酶的机制,因此外生菌根真菌具有降解五氯酚的潜力与优势。这些信息将为进一步开展五氯酚生物降解机理研究,应用微生物—植物复合系统修复污染土壤提供基础。     

甲基对硫磷降解菌DLL-1的分离、鉴定及降解性研究

从长期施用甲基对硫磷的污染土壤中分离到一株能以甲基对硫磷为唯一碳源生长且能将其完全矿化的细菌 Ｄ Ｌ Ｌ－ １ ,经鉴定,为邻单胞菌（ Ｐｌｅｓｉｏｍｏｎａｓ ｓｐ ．） ．该菌株３ ｈ 内对５０ ｍｇ／ Ｌ甲基对硫磷的降解率为９３ ％ ,２４ｈ 内对５０ ｍｇ／ Ｌ甲基对硫磷的降解率为９５ ％ 以上．在葡萄糖铵盐培养基中, Ｄ Ｌ Ｌ１ 对甲基对硫磷的耐受浓度和降解速度均增大．降解曲线表明延滞期内,菌体依靠上一生长阶段分泌的酶类对甲基对硫磷进行降解,一旦菌体开始生长,则检测不到中间代谢产物对硝基苯酚的存在．生长情况和粗酶液试验均显示 Ｄ Ｌ１ 优良的降解性状     

单甲脒农药对土壤微生物种群和土壤酶活性的影响

研究了单甲脒（Ｎ＇－２，４－二甲苯基－Ｎ－甲基甲脒，简称ＤＭＡ）对土壤微生物种群和土壤酶活性的影响．田间试验表明，喷洒单甲脒盐酸盐（ＤＭＡＨ）于棉花植株对土壤微生物种群和土壤酶活性无明显影响．实验室试验表明，投加ＤＭＡＨ于土壤对土壤微生物种群有不同的抑制作用；当ＤＭＡＨ在土壤中的浓度为２０ｍｇ／ｇ时，好氧异养菌总量开始降低，硝化细菌和放线菌、真菌的土壤ＤＭＡＨ抑制浓度分别为０．５ｍｇ／ｇ和０．１ｍｇ／ｇ．ＤＭＡＨ对土壤酶活性的影响亦不相同，脱氢酶对土壤中ＤＭＡＨ含量为１０ｍｇ／ｇ时其活性即有明显的减弱，而过氧化氨酶对ＤＭＡ的耐受性相当高，其活性的抑制浓度达５００ｍｇ／ｇ．试验还证明了土壤中ＤＭＡ的微生物降解作用．当ＤＭＡ在土壤中的浓度为５０～５００ｇ／ｇ时，其消解速率可从８．７５ｍｍ·ｋｇ－１·ｄ－１提高到４８ｍｇ·ｋｇ－１·ｄ－１．     

进水PCP和CODCr质量浓度对厌氧反应器运行效能的影响

应用以氯酚驯化污泥接上流式厌氧消化反应器（ＵＡＤ）连续处理含五氯酚（ＰＣＰ）废水的试验结果表明，在一定的水力负荷下，试验反应器可稳定地处理ρ（ＣＯＤＣｒ）１２５０－１０００ｍｇ．Ｌ＾－１和ρ（ＰＣＲ）≤１８０ｍｇ．Ｌ＾－１的有毒有机废水，ＣＯＤＣｒ去除率大于９０％，ＰＣＰ去除率大于９９．５％，出水ρ（ＰＣＰ）小于０．５ｍｇ．Ｌ＾－１，维持试验反应器正常运行所必需的最低进水ρ（ＰＣＰ）有关，且进水ρ     

LHG1菌株的分离和降解环己烷的研究

通过选择性培养从石油废水污染的土壤中分离出一株以环己烷为唯一碳源和能源的降解菌株 Ｌ Ｈ Ｇ１ ,对 Ｌ Ｈ Ｇ１ 菌株的降解特性进行了研究．确定 Ｌ Ｈ Ｇ１ 菌株最适培养条件为：培养时间６０ ～１００ ｈ 、环己烷浓度４６０ ～７７０ ｍｇ／ Ｌ、ｐ Ｈ６ ～８ 、ρ（ Ｎａ Ｃｌ） ＝ １０ ｇ Ｌ－ １ 、θ＝ ２５ ～４０ ℃． Ｌ Ｈ Ｇ１ 菌株能够利用环烷烃代谢的中间产物环己酮和环戊酮．此外, Ｌ Ｈ Ｇ１ 菌株还能降解液体石蜡、固体石蜡、萘和苯酚等链烃、芳香烃和酚类     

间苯二酚的微生物降解研究

从土壤中筛选的一株降解活性较高的细菌Ｔ１，当以间苯二酚为唯一碳源时，降解率可达９８％，研究表明，菌体接种量的大小对间苯二酚降解速度有一定的影响；降解酶为胞内酶，经鉴定，Ｔ１菌为黄单胞菌，其某些特性与已知菌种有差异，需进一步研究。     

基于环境背景值的重金属污染地块划定——以浙东沿海某典型固体废物拆解区污染土壤为例

通过对浙江东部沿海某典型固体废物拆解区污染土壤的调查与分析,评价了其土壤重金属的污染程度。结果表明,与土壤环境背景值相比,研究区土壤污染较为严重,Cd、Cu中等程度以上污染土壤均在50%以上。在此基础上,重点对重金属污染土壤的划定进行了探讨,提出了适合土地质量差别化管护的污染土壤表达方法。     

阿特拉津在土壤中的生物降解研究

运用恒温培养法研究了阿特拉津在河北省白洋淀地区农田土壤中的生物降解动力学,并从中分离鉴定了土壤中降解阿特拉津的优势菌种,研究结果表明,该土壤对阿特拉津具有一定的降解能力,非生物＋生物的降解、非生物降解和生物降解的速率分别为０．０２６２ｄ＾－１,０．００５５４８ｄ＾－１和０．００８１９４ｄ＾－１,半衰期分别为２６ｄ,１２５ｄ和８５ｄ,发现土壤中降解阿特拉津的优势菌种为蜡状芽孢杆菌（Ｂａｃｉｌｌｕｓ     

Degradation of methyl-phenanthrene isomers during bioremediation of soil contaminated by residual fuel oil

Phenanthrene and methyl-phenanthrenes are major aromatic pollutants originating in particular from fuel oil. Phenanthrene is usually degraded faster than methyl-phenanthrenes under geological and environmental conditions. Here, we report a preferential and accelerated biodegradation of methyl-phenanthrenes versus phenanthrene in soil contaminated by fuel oil. The polluted soil was mixed with sawdust and sand to form a homogenized biopile. The biopile was continuously sprayed with microbial consortia isolated from crude oil?Ccontaminated soil and treated by biosurfactants and nutritive substances for biostimulation. During a 6-month bioremediation experiment, a steady increase in the relative abundance of phenanthrene compared to methyl-phenathrenes was observed by gas chromatography?Cmass spectrometry. The increase was the highest for trimethyl-phenanthrenes, with a phenanthrene/trimethyl-phenanthrenes ratio increasing from 0.42 to 2.45. By contrast, the control, non-stimulated samples showed a ratio decrease from 0.85 to 0.11. Moreover, the results showed that the level of degradability depends on the number of methyl groups.     

生物表面活性剂与蒽降解菌的协同降解效应

对蒽生物降解中铜绿假单胞菌S6分泌的生物表面活性剂的作用进行了研究.结果表明,在接种蒽降解菌A10之前1d及与接种A10同时投加60mg.l-1的生物表面活性剂能够最大程度地促进蒽降解,相比于未添加表面活性剂的样品,降解率分别提高了16.50%和18.03%.过高浓度的生物表面活性剂会在一定程度上抑制蒽的降解.对蒽降解过程的分析表明,提前投加生物表面活性剂能明显促进蒽的降解且一直保持较好的降解效果.蒽降解过程中,生物表面活性剂能够被微生物利用,具有生物可利用性,是一种环境友好的生物制剂.     

垃圾渗滤液浇灌对红壤原生动物群落的影响

采用“非浸没培养皿法”（non-flooded petri dish method)培养,对李坑垃圾填埋汤垃圾渗液淋灌的土壤中的原生动物群落进行了分析。实验发现4属4种纤毛虫：膨胀肾形虫（Colpoda inflata)、有肋薄咽虫（Leptopharynx costatus)、莫式拟肾形虫（Paracolpoda maupasi)、恼斜板虫（Plagiocampa difficils)。随淋灌中垃圾渗滤液浓度的上升,出现的纤毛虫种类呈递减趋势,从定量实验的结果来看,即使是较低浓度的垃圾渗滤液,也对土壤原生动物群落造成了较大的伤害。25％浓度的垃圾渗滤液淋灌的土样中,原生动物数量仅为CK组的30％;超过50％浓度的渗滤液稀释液淋灌土样,则仅为CK组的10％左右。数据表明污染本身并没有被降解,而是全部（或至少大部分）转移到了受渗滤液影响的土壤中,从而导致土壤中的原生动物群落的结构无论是从数量上还是从种类上均曹到相当大的破坏。表4参15     

水-硅油双相体系对多环芳烃降解菌的筛选及鉴定

选用水-硅油双相体系驯化筛选降解多环芳烃的优势菌株。筛选体系为：50mL无机盐溶液＋10mL硅油。从74瓶富集液中,对降解效果明显的富集液进行多环芳烃降解率的液相色谱定量测定。对蒽的降解率最高为45%;对荧蒽的降解率最高为99%,几乎全部降解,对苯并[a]芘的降解率为27%。筛选到一株能够高效降解蒽、菲、芘、荧蒽的菌株,编号LD29,鉴定结果为矢野口鞘氨醇杆菌LD29（Sphingobium yanoikuyae LD29）。富集液Y12对5种多环芳烃的降解效果同样很明显。     

Influence of environmental factors on biodegradation of quinalphos by <Emphasis Type="Italic">Bacillus thuringiensis</Emphasis>

Background

The extensive and intensive uses of organophosphorus insecticide—quinalphos in agriculture, pose a health hazard to animals, humans, and environment because of its persistence in the soil and crops. However, there is no much information available on the biodegradation of quinalphos by the soil micro-organisms, which play a significant role in detoxifying pesticides in the environment; so research is initiated in biodegradation of quinalphos.

Results

A soil bacterium strain, capable of utilizing quinalphos as its sole source of carbon and energy, was isolated from soil via the enrichment method on minimal salts medium (MSM). On the basis of morphological, biochemical and 16S rRNA gene sequence analysis, the bacterium was identified as to be Bacillus thuringiensis. Bacillus thuringiensis grew on quinalphos with a generation time of 28.38 min or 0.473 h in logarithmic phase. Maximum degradation of quinalphos was observed with an inoculum of 1.0 OD, an optimum pH (6.5–7.5), and an optimum temperature of 35–37 °C. Among the additional carbon and nitrogen sources, the carbon source—sodium acetate and nitrogen source—a yeast extract marginally improved the rate of degradation of quinalphos.

Conclusions

Display of degradation of quinalphos by B. thuringiensis in liquid culture in the present study indicates the potential of the culture for decontamination of quinalphos in polluted environment sites.

     

Bepflanzung einer Tankstelle mit Weiden

In Axelved, Denmark, an abandoned gas filling station serves as a test field for phytoremediation. Laboratory studies accompany the project. The toxicity of fresh and weathered gasoline and diesel to willow and poplar trees was studied by use of a tree transpiration toxicity test. The correlation between diesel content in soil and decrease in willow tree transpiration (Salix viminalis x schwerinii) was highly significant (r ²=0.81, n=19). the EC₅₀ (50% inhibition of transpiration) for the sum of hydrocarbons (HC) was determined to be 3910 mg/kg (95% confidence interval from 2900 to 5270 mg/kg). The EC₁₀ was 810 mg/kg (95% confidence interval 396 to 1660 mg/kg). The results were verified with artificially mixed diesel and gasolinecontaminated soils and two willow and one poplar species (S. viminalis, S. alba andPopulus nigra). The degradation of radiolabeledm-xylene was studied with and without willows. The compound was readily degraded. Willow trees accelerated the elimination, but mainly due to the volatilization ofm-xylene. Model studies provided the result that biodegradation in soil is the fastest elimination process at the site, but it is limited by the availability of electron acceptors. The pollutants are almost persistent in the groundwater, but in aerated soil, 10000 mg/kg hydrocarbons at 1 m depth are degraded within 13 years. The main effect of willows on the pollutants’ persistence is that willows transpire water, lower the groundwater level and aerate the soil, hereby speeding up biodegradation.