茶叶上拟除虫菊酯类农药降解菌的分离及其特性

生物修复对降解污染基质中的农药是一种对环境有益的方法。目标是要寻找能够降解在茶叶生产中使用的拟除虫菊酯类农药的降解菌。最终在福州某茶园经农药处理过的茶叶中分离降解菌。首先在富集培养基中筛选,接着在以农药为唯一碳源的基础培养基中连续筛选。结果发现,其中一株标号为c1f6的菌株生长的特别良好,经AMS-VITEK120全自动微生物分析系统鉴定,为假单胞菌属的一个未知种。采用HP6890气相色谱仪测定菌株对拟除虫菊酯类农药联苯菊酯、甲氰菊酯和氯氰菊酯的降解率。在pH7.0的基础培养基发酵液中,以各加100mg·L-1这3种农药为唯一碳源,30℃振荡培养,接种c1f6后3d,这3种农药的降解率分别为55.64%、44.56%和52.19%。采用光密度测定的菌株生长值和农药降解率的关系曲线表明,在基础培养基中,农药降解和菌株生长成正相关,说明菌株能以拟除虫菊酯类农药为唯一碳源和能源进行生长。采用同样的方法测定表明,菌株c1f6对有机磷农药也有一定的降解力,3d对甲胺磷和毒死蜱的降解率分别为27.67%和12.35%。因此,假单胞菌c1f6是一株较广谱的农药降解菌,有望用于生物修复过程,以减少茶叶栽培过程中的产品和环境污染。     

一株毒死蜱降解细菌的分离鉴定及其在土壤修复中的应用

从蔬菜大棚土壤中分离到一株能以毒死蜱为唯一碳源和能源生长的菌株DSP3,该菌在含毒死蜱（100mg/L）的酵母膏和蛋白胨与同样毒死蜱含量而无酵母膏蛋白胨的无机盐培养基中,18d对毒死蜱的降解率分别为986%和762%;在土壤实验中20d对毒死蜱（100mg/kg）的降解率接近100%,加入DSP3菌在蔬菜大棚新鲜土壤中能有效促进毒死蜱在土壤中的降解。根据生理生化特征、16S rDNA序列分析、（G+C）mol%测定和DNA同源性分析,将菌株DSP3鉴定为粪产碱杆菌（Alcaligenes faecalis）。     

枯草芽胞杆菌降解毒死蜱特性研究

研究生物量、pH、毒死蜱浓度和温度对枯草芽胞杆菌3374菌株(编号为GU086422)在水溶液中降解毒死蜱特性,考察该菌株对白菜上毒死蜱残留的降解特性。结果表明,在毒死蜱质量浓度为240 mg/L、pH7.0、温度30℃的适宜条件下,枯草芽胞杆菌3374菌株对毒死蜱的降解率达到92.48%。该菌株能够有效提高白菜叶面上毒死蜱残留的降解速度,表明其在白菜上具有有效降解毒死蜱的能力,在无公害农产品生产中具有广阔的应用潜力。     

三唑磷降解菌株GS-1的分离鉴定及其降解特性的研究

从有机磷农药污水处理池污泥中分离到一株能高效降解三唑磷的菌株GS-1, 通过生理生化实验和16S rDNA序列同源性分析, 将该菌株鉴定为Diaphorobacter sp.。菌株GS-1能以三唑磷为唯一碳源生长, 能在12 h内降解100 mg/L的三唑磷至检测不出的水平。菌株GS-1降解三唑磷的过程中会产生中间代谢产物苯唑醇(1-苯基-3-羟基-1,2,4-三唑), 36 h后苯唑醇被完全转化。菌株GS-1降解三唑磷的最适pH值为8.0, 最适温度为30°C, 且对杀螟硫磷、辛硫磷、毒死蜱和甲基对硫磷     

敌敌畏降解菌的分离鉴定及降解特性研究

目的:从受有机磷农药污染的土壤中分离能降解DDVP的菌株,对其进行鉴定和降解特性研究.方法:采用DDVP为惟一碳源和能源的无机盐培养基,通过富集培养、平板划线分离得到一株优势菌,编号为DDW-1,采用形态学、生理生化和16S-rDNA序列分析对其进行鉴定,采用气相色谱测定菌株DDW-1对DDVP的降解能力,并进行底物广谱性测试和降解酶定位实验.结果:该菌株鉴定为甲基杆菌属(Methylobacterium sp.).降解特性试验结果表明,其最佳生长条件为温度28℃,初始pH为7.0,在该条件下,500mg·L-> DDVP经过DDW-1菌株代谢3d后,降解率达63.7%.结论:菌株DDW-1能降解DDVP,该菌株产胞内酶.     

污染土壤中有机磷农药降解菌的分离及其多样性

采用添加有机磷农药的选择性培养基,在长期受有机磷农药污染的土壤中分离到7株有机磷农药降解菌,经生理生化鉴定和系统发育分析,菌株mp-1鉴定为Pseudaminobactersp.,菌株mp-2为Alcaligenessp.,菌株mp-7为Brucellasp.,其他菌株为Ochrobactrumsp.。16SrDNA序列同源性比较、系统发育分析和染色体ERIC-PCR指纹图谱扩增表明有机磷农药长期污染的土壤中有机磷农药降解菌具有丰富的多样性。     

耐盐性毒死蜱降解菌HY-1 的产酶培养基及发酵条件优化

为了明确生化处理和微生物降解的关系,通过增加耐盐菌的比例可以提高农药废水生化处理效果。从农药厂废水中分离到1株耐盐性毒死蜱降解菌——蜡状芽孢杆菌(Bacillus cereus HY-1),以从该菌中提取到的降解酶比活力为指标,进行产酶培养基和发酵条件的优化研究。通过单一因素试验和正交试验,对细菌HY-1的产酸培养基和发酵条件进行了优化。运用SPSS软件进行结果分析,所获优化培养基配方为:葡萄糖6.0 g/L,胰蛋白胨2.2 g/L,K2HPO4 2.0 g/L,KH2PO4 0.2 g/L,MgSO4.7H2O 0.1 g/L,NaCl 0.1 g/L和微量元素溶液2 mL/L。得到菌株发酵培养的最佳优化条件为:种子液培养时间为16 h,发酵培养时间为18 h,接种量为1%(V/V),发酵培养基初始pH值为7.0。氯化钠浓度为0?30 g/L时降解酶比活力不受影响,这是已报道的耐盐性最强的一株毒死蜱降解菌。     

relA基因敲除对克雷伯氏菌CPK降解毒死蜱的影响

目的:敲除毒死蜱降解菌Klebsiella sp.CPK菌中的relA基凶,研究其对毒死蜱降解的影响.方法:采用同源重组技术敲除了Klebsiella sp.CPK菌中魔斑合成酶编码基因relA,通过PCR及RT-PCR扩增对其敲除进行了验证,分别采用分光光度法和气相色谱检测了该突变体对毒死蜱的耐受性和对毒死蜱的降解.结果:获得了一株relA基因敲除菌株△relA.在毒死蜱胁迫下,△ relA菌株的耐受能力和对毒死蜱的降解能力均弱丁野生型的CPK菌株.在初始降解的第一天,两者的降解速率相差最大,CPK菌株对毒死蜱的降解率高达50%以上,而△relA菌株对毒死蜱的降解率却低于15%.结论:relA基因的产物魔斑参与调控了Klebsiella sp.CPK菌在毒死蜱胁迫下的严谨反应,可能以此增强了该菌株对毒死蜱的耐受性并促进了它对毒死蜱的降解.     

尼古丁降解菌SCUEC1菌株的分离及其降解基因

【目的】分离并鉴定1株具有尼古丁降解能力的细菌,研究其尼古丁降解特性并对其降解基因进行分析,为尼古丁微生物降解提供基础。【方法】从烟草种植地土壤中分离1株具有尼古丁降解能力的细菌,通过16S r RNA基因和生理生化特性对该菌株进行鉴定,检测该菌株尼古丁降解率与生长量的关系,并进一步对该菌株进行尼古丁浓度耐受性测定,采用高通量测序技术对菌株进行全基因组测序,BLAST比对分析尼古丁降解相关基因。【结果】筛选到1株具有尼古丁降解能力的细菌,经鉴定命名为根癌土壤杆菌(Agrobacterium tumerficience)SCUEC1菌株,根癌土壤杆菌SCUEC1菌株尼古丁降解率可达到94.81%,该菌株在尼古丁浓度为0.50–5.00 g/L范围内生长良好且有较高的尼古丁降解能力。对根癌土壤杆菌SCUEC1菌株全基因组序列进行BLAST比对分析,推测该菌株的尼古丁降解代谢途径与中间苍白杆菌SYJ1菌株的尼古丁降解途径相似。【结论】本研究揭示了Agrobacterium tumerficienceSCUEC1菌株具备尼古丁降解特性,初步推测出尼古丁降解相关基因和降解代谢途径,为尼古丁微生物降解提供基础。     

一株毒死蜱降解新菌株Sphingopyxis terrae R17的分离鉴定及降解特性

从农药厂排污沟污泥中分离到一株能降解毒死蜱的新菌株,命名为R17,经生理生化和16S rDNA序列同源性分析,鉴定为Sphingopyxis terrae.R17可以利用毒死蜱作为唯一碳源生长,该菌株的最适生长温度为35℃、最适pH为7～8,在此条件下培养28 h后,菌落浓度达9.18×108cfu/mL.研究了该菌在...     

Biosurfactant production by Pseudomonas sp. and its role in aqueous phase partitioning and biodegradation of chlorpyrifos

Aim:  To study the effect of biosurfactant on aqueous phase solubility and biodegradation of chlorpyrifos.
Methods and Results:  A Pseudomonas sp. (ChlD), isolated from agricultural soil by enrichment culture technique in the presence of chlorpyrifos, was capable of producing biosurfactant (rhamnolipids) and degrading chlorpyrifos (0·01 g l⁻¹). The partially purified rhamnolipid biosurfactant preparation, having a CMC of 0·2 g l⁻¹, was evaluated for its ability to enhance aqueous phase partitioning and degradation of chlorpyrifos (0·01 g l⁻¹) by ChlD strain. The best degradation efficiency was observed at 0·1 g l⁻¹ supplement of biosurfactant, as validated by GC and HPLC studies.
Conclusion:  The addition of biosurfactant at 0·1 g l⁻¹ resulted in more than 98% degradation of chlorpyrifos when compared to 84% in the absence of biosurfactant after 120-h incubation.
Significance and Impact of the Study:  This first report, to the best of our knowledge, on enhanced degradation of chlorpyrifos in the presence of biosurfactant(s), would help in developing bioremediation protocols to counter accumulation of organophosphates to toxic/carcinogenic levels in environment.     

Biodegradation of Chlorpyrifos and Its Hydrolysis Product 3,5,6-Trichloro-2-Pyridinol by a New Fungal Strain Cladosporium cladosporioides Hu-01

Intensive use of chlorpyrifos has resulted in its ubiquitous presence as a contaminant in surface streams and soils. It is thus critically essential to develop bioremediation methods to degrade and eliminate this pollutant from environments. We present here that a new fungal strain Hu-01 with high chlorpyrifos-degradation activity was isolated and identified as Cladosporium cladosporioides based on the morphology and 5.8S rDNA gene analysis. Strain Hu-01 utilized 50 mg·L⁻¹ of chlorpyrifos as the sole carbon of source, and tolerated high concentration of chlorpyrifos up to 500 mg·L⁻¹. The optimum degradation conditions were determined to be 26.8°C and pH 6.5 based on the response surface methodology (RSM). Under these conditions, strain Hu-01 completely metabolized the supplemented chlorpyrifos (50 mg·L⁻¹) within 5 d. During the biodegradation process, transient accumulation of 3,5,6-trichloro-2-pyridinol (TCP) was observed. However, this intermediate product did not accumulate in the medium and disappeared quickly. No persistent accumulative metabolite was detected by gas chromatopraphy-mass spectrometry (GC-MS) analysis at the end of experiment. Furthermore, degradation kinetics of chlorpyrifos and TCP followed the first-order model. Compared to the non-inoculated controls, the half-lives (t _1/2) of chlorpyrifos and TCP significantly reduced by 688.0 and 986.9 h with the inoculum, respectively. The isolate harbors the metabolic pathway for the complete detoxification of chlorpyrifos and its hydrolysis product TCP, thus suggesting the fungus may be a promising candidate for bioremediation of chlorpyrifos-contaminated water, soil or crop.     

Optimization of Chlorpyrifos Degradation by Assembled Bacterial Consortium Using Response Surface Methodology

Chlorpyrifos is a commonly used organophosphate pesticide. Its extensive use and associated serious soil and water contamination have gained increasing environmental concern. Biodegradation is a promising way to remediate chlorpyrifos contamination. There are many reports on various chlorpyrifos degrading microorganisms, but only a few on biodegradation of chlorpyrifos by consortia. Hence, the present study attempted to assemble a novel bacterial consortium C5 for the biodegradation of chlorpyrifos. The 16S rRNA gene-based molecular analysis revealed that the bacterial consortium consisted of Staphylococcus warneri CPI 2, Pseudomonas putida CPI 9 and Stenotrophomonas maltophilia CPI 15. Optimization of chlorpyrifos degradation by the consortium C5, using a Box–Behnken design, was carried out taking into account four important variables: temperature, pH, the initial concentration of chlorpyrifos and time of incubation. C5 is capable of giving 90% degradation of chlorpyrifos (125 ppm) in 8 days of incubation under optimized conditions of pH (7) and temperature (30°C). Growth curve and degradation study under optimized conditions confirmed that consortium could improve the biodegradation potential. From these results, we conclude that the novel consortium C5 of three species can be used to eliminate chlorpyrifos from various environmental compartments and can be implemented in bioreactors in a cost-effective, safe and environmentally friendly manner.     

Development of a Freeze-Dried Fungal Wettable Powder Preparation Able to Biodegrade Chlorpyrifos on Vegetables

Continuous use of the pesticide chlorpyrifos has resulted in harmful contaminations in environment and species. Based on a chlorpyrifos-degrading fungus Cladosporium cladosporioides strain Hu-01 (collection number: CCTCC M 20711), a fungal wettable powder preparation was developed aiming to efficiently remove chlorpyrifos residues from vegetables. The formula was determined to be 11.0% of carboxymethyl cellulose-Na, 9.0% of polyethylene glycol 6000, 5.0% of primary alcohol ethoxylate, 2.5% of glycine, 5.0% of fucose, 27.5% of kaolin and 40% of freeze dried fungi by response surface methodology (RSM). The results of quality inspection indicated that the fungal preparation could reach manufacturing standards. Finally, the degradation of chlorpyrifos by this fungal preparation was determined on pre-harvest cabbage. Compared to the controls without fungal preparation, the degradation of chlorpyrifos on cabbages, which was sprayed with the fungal preparation, was up to 91% after 7 d. These results suggested this freeze-dried fungal wettable powder may possess potential for biodegradation of chlorpyrifos residues on vegetables and provide a potential strategy for food and environment safety against pesticide residues.     

Biodegradation of Crude Oil by an Arctic Psychrotrophic Bacterium <Emphasis Type="Italic">Pseudoalteromomas</Emphasis> sp. P29

A psychrotrophic petroleum-degrading bacterium Pseudoalteromonas sp. P29 was isolated from marine sediment, which was collected during 2nd Chinese Arctic Scientific Expedition. The phenotypic character and biodegradation efficiency on mixed oil or vacuum oil were tested at low temperature. The strain Pseudoalteromonas sp. P29 grew in a range of temperature from 5 to 35°C and the optimum temperature was 25°C. Gas chromatography analysis indicated that the strain might preferentially metabolize shorter-chain alkanes. The biodegradation efficiency were nearly 90 and 80%, respectively, after incubation at 5°C for 28 days in the mineral medium supplement with mixed oil or vacuum oil as the sole carbon and energy source. The results showed a possible exploitation of the strain in future biotechnological processes especially in cold contaminated environments.     

Intensification of phenol biodegradation by humic substances

Phenol biodegradation was carried out in a batch system by the bacterial strain Cupriavidus metallidurans in the presence of potassium humate that was prepared by alkaline extraction from oxyhumolite. The experiments were focused on the assessment of the humate effect on biodegradation activity of the tested bacterial strain. The achieved results demonstrated that the humate has a positive influence on the biodegradation of phenol and reduces the incubation time necessary for phenol removal. Higher biodegradation rate and more intensive growth were observed during the cultivation in presence of humate in comparison to the cultivation without its addition. Adsorption of the humate on bacterial biomass was observed as well. Subsequently, a phenol biodegradation testing in a continuous-flow system using a biofilm reactor was also carried out. Although the reactor was inoculated by C. metallidurans only, the microbial composition under an aerobic non-aseptic condition during this long-term cultivation changed. The phenol removal efficiency obtained in the biofilm reactor was higher than 92% when phenol concentration in a treated medium was 1200 mg l⁻¹.     

一株刚果红降解菌的筛选、鉴定和性质的初步研究

通过稀释划线的方法,从土壤中分离到一株能降解刚果红的菌株(T1),从菌落和孢子形态来判断该菌为放线菌的链霉菌属。T1菌在含刚果红(100 mg.L-1)高氏液体培养基中培养6 d后,脱色率高达90%。对培养液进行200~800 nm波长扫描的结果表明,培养基中部分刚果红被T1菌降解,其余部分被菌体吸附。活菌体对染料的吸附效率比死菌体高。T1菌对刚果红的脱色主要是通过生物降解和菌体吸附作用来完成。     

利用微藻固定烟道气中CO2的实验研究

为获得能适合于烟道气条件下生长的微藻 ,找到一种高效的温室气体固定的方法 ,利用配置烟道气 (CO2 和O2 的浓度分别为 15 %和 2 %)驯化稻田微藻混合试样 ,分离出对高浓度CO2 条件有很强适应力的微藻ZY 1,并研究了在不同培养条件下微藻ZY 1的生长情况 .微藻ZY 1在CO2 浓度从 10 %～ 15 %的范围内有较高生长力 ,在CO2 浓度为 10 %时 ,生长最好 .微藻ZY 1对温度、气体流速、pH值等物理条件也有很宽的适应范围 ,在温度为 2 5～ 30 .C、流速为 0 2 5～ 0 75L·min-1、pH4～ 6范围内 ,生长基本稳定 .在培养条件为 10 %CO2 、2 5 .C、pH5 0时 ,微藻ZY 1的生长率最高 ,CO2 的固定率平均值为 0 397%.可以认为 ,利用该藻固定烟道气温室气体具有一定的可行性 .     

Isolation and characterization of alkalotolerant <Emphasis Type="Italic">Pseudomonas</Emphasis> sp. strain ISTDF1 for degradation of dibenzofuran

An alkalotolerant Pseudomonas strain was enriched and isolated from effluent of the pulp and paper industry. This strain was able to degrade dibenzofuran and utilize it as a sole source of energy and carbon. The GC–MS based detection of various intermediary metabolites of biodegradation suggested the involvement of angular as well as lateral pathway of dibenzofuran biodegradation. The GC–MS based detection of various intermediary metabolites of biodegradation suggested the involvement of angular as well as lateral pathway of dibenzofuran biodegradation. This diverse dioxygenation property of the strain allowed it to utilize various recalcitrant chlorinated xenobiotics and PAHs compounds. This strain showed optimum utilization (~85%) of dibenzofuran (200 mg l⁻¹) within 36 h at pH 10 at 40°C. The growth of the strain was supported by a wide range of environmental conditions such as temperature, pH, and concentration of dibenzofuran, suggesting that it can be used for in situ bioremediation of dioxin-like compound.