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.)。     

多环芳烃降解菌的筛选与降解能力测定

从本溪多环芳烃(PAHs)污染土壤中经富集培养筛选出8株PAHs降解菌,研究了8株菌及其等比例混合培养对菲、芘和苯并[a]芘的降解能力。结果表明,在28℃,培养基中菲、芘和苯并[a]芘的浓度分别为50、50和5mg·L-1的复合底物条件下,培养28d后,菌株B3的降解效果最好,对菲、芘和苯并[a]芘的降解率分别为88.4%、54.0%和68.4%,8株菌的混合培养对菲、芘和苯并[a]芘的降解率分别为87.7%、35.3%和42.0%;经生理生化实验和16SrRNA序列比对,初步鉴定B3菌为假单胞菌属(Pseudomonas sp.)。     

多环芳烃降解菌X20的鉴定及降解特性

从多环芳烃降解高效的混合菌群中分离筛选到1株多环芳烃降解菌X20,经形态观察和16SrRNA序列分析,属于假单胞菌(Pseudomonas sp.)。采用室内摇瓶培养的方法,研究了该菌在不同环境条件下对菲和芘的降解。结果表明:弱碱环境有利于菌株X20对菲和芘的降解,最适pH为8.0;葡萄糖对菲芘降解率的影响呈抛物线变化,当葡萄糖浓度为0.2%时,X20对菲和芘的降解达到最高;X20对菲和芘的降解率随其初始浓度的上升而降低,菲和芘在初始浓度为10、20和40mg.L-1时的7d降解率分别为56.3%、39.25%、29.75%和41.8%、29.55%、23.50%,芘对X20降解的抑制强度高于菲。本研究结果将为构建高效的多环芳烃降解菌群,提高多环芳烃原位污染土壤的生物修复效果奠定基础。     

分枝杆菌TZh51菌株的分离鉴定及其生物修复污染土壤的特性

[目的]为获得降解芘的微生物菌株,并用其生物修复被多环芳烃污染的土壤.[方法]芘降解菌的分离采用平板升华法.根据表型观察、生理生化特性和16S rDNA的序列同源性分析,对菌株进行分类学鉴定.通过活菌计数、HPLC测定多环芳烃的残留量,研究菌株在固体、液体无机盐培养基以及在污染土壤中降解多环芳烃(polycyclic aromatic hydrocarbons,PAHs)的能力.[结果]分离到4株能降解芘的菌株TZh51、TZh52、TG42和TG52.实验结果表明,TZh51降解PAHs的能力强于其余3株菌.TZh51被鉴定为分枝杆菌属(Mycobacterium sp.),但与已发表的分枝杆菌菌株M11为不同的种.TZh51接种在芘膜的固体无机盐培养基上,测定获得最大芘降解量的条件是培养温度为3512和芘膜厚度为130 ng/mm2.在芘浓度为50、100 mg/L的液体无机盐培养基中培养,6天时TZh51的芘降解率分别达到91.9%、71.8%,10天时菌体数量分别达到最大值为2.0、6.0×108cfu/mL;TZh51降解芘的效果强于M11.在种植作物的处理中,到第6周时TZh51的菌体数量达到每克干土含7.2×108个菌落数,到第8周时菲、荧蒽和芘的降解率分别达到91.4%、86.9%和85.8%;[结论]TZh51具有很强降解PAHs的能力;另外,TZh51与作物联合生物修复污染土壤的效果明显.     

多环芳烃降解菌的筛选、鉴定及降解特性

【目的】多环芳烃(PAHs)是一类普遍存在于环境中且具有高毒性的持久性有机污染物,高效降解菌的筛选对利用生物修复技术有效去除环境中的多环芳烃具有重要意义。研究拟从供试菌株中筛选多环芳烃高效降解菌,并分析其降解特性,为多环芳烃污染环境的微生物修复提供资源保障和科学依据。【方法】采用平板法从25株供试菌株中筛选出以菲和芘为唯一碳源和能源的高效降解菌,经16S rRNA基因序列进行初步鉴定,通过单因素实验法分析其在液体培养基中的降解特性。【结果】筛选出的3株多环芳烃高效降解菌SL-1、02173和02830经16S rRNA基因序列分析,02173和02830分别与假单胞菌属中的Pseudomonas alcaliphila和Pseudomonas corrugate同源性最近,SL-1为本课题组发表新类群Rhizobium petrolearium的模式菌株;降解实验表明,菌株SL-1 3 d内对单一多环芳烃菲(100 mg/L)和芘(50 mg/L)的降解率分别达到100%和48%,5 d后能够降解74%的芘;而其3 d内对混合PAHs中菲和芘的降解率分别为75.89%和81.98%。菌株02173和02830 3 d内对混合多环芳烃中萘(200 mg/L)、芴(50 mg/L)、菲(100 mg/L)和芘(50 mg/L)的降解率均分别超过97%。【结论】筛选出的3株PAHs降解菌SL-1、02173和02830不仅可以高效降解低分子量PAHs,还对高分子量PAHs具有很好的降解潜力。研究表明,由于共代谢作用低分子量多环芳烃可促进高分子量多环芳烃的降解,而此时低分子量多环芳烃的降解将受到抑制。     

一株高分子量多环芳烃降解菌的筛选、鉴定及降解特性研究

采用富集培养方法从多环芳烃污染土壤中筛选分离得到1株能以苯并[a]芘(B[a]P)为唯一碳源和能源生长的菌株.形态特征观察和16S rDNA序列分析结果表明,该菌株为副球菌属(Paracoccus sp.),编号为HPD-2.HPD-2在3.0 mg/L的B[a]P液体培养基中生长较慢,培养5 d后B[a]P的降解率为89.7%.同时,该菌株对四环的芘和荧蒽也具有较好的降解能力,培养7 d后芘和荧蒽的降解率分别达到47.2%和84.5%.可见,该菌株对高分子量PAHs具有很好的降解潜力.     

盐渍化土壤翅碱蓬根际促生细菌的筛选及对多环芳烃的降解特性

为了强化多环芳烃污染盐渍化土壤的原位植物-微生物修复的应用,获得促进植物降解多环芳烃的高效菌种资源,本研究采用富集培养的方法,从多环芳烃污染的大港油田翅碱蓬根际分离到1株能以菲、芘为唯一碳源同时分泌1-氨基环丙烷~(-1)-脱氨酶的优势菌株B~(-1),通过形态观察和16S rRNA序列分析鉴定该菌株,并对其潜在的促生能力和菲、芘的降解特性进行分析。16S rRNA序列分析结果表明,该菌株为动性球菌属(Planococcus sp.),可产生3-吲哚乙酸,且具有溶磷能力。同时对菲、芘的降解具有较广泛的p H值和盐浓度范围,在菲和芘浓度均为50 mg·L~(-1),p H 8.0,盐度2%时,7 d对菲、芘的降解率为66.6%和52.0%。表面活性剂烷基糖苷的添加使菲、芘降解效率分别提高至94.2%和78.8%。     

3株多环芳烃高效降解菌株的分离鉴定及降解特性

筛选分离降解多环芳烃(PAHs)的优势菌种对开展多环芳烃污染生态系统修复具有重要的现实意义。本研究以焦化厂周围受多环芳烃污染的土壤为菌源,经过富集培养驯化和平板分离,获得11株能降解多环芳烃的菌株。通过形态观察、生理生化特征及16S rRNA序列比对对菌株进行鉴定,筛选出3株PAHs高效降解菌,分别命名为DJ-3、DJ-8、DJ-10。经16S rRNA序列分析鉴定,DJ-3为假单胞菌属、DJ-8为克雷伯氏菌属、DJ-10为芽孢杆菌属。对菌株降解能力的研究表明,3株菌(DJ-3、DJ-8、DJ-10)培养7 d后对混合多环芳烃中菲(200 mg·L^-1)、芘(200 mg·L^-1)和萘(160 mg·L^-1)的降解率分别为48.9%～65.9%、38.9%～43.1%和57.6%～64.9%。3株菌对多环芳烃混合样品(1200 mg·L^-1)的降解率分别为49.1%、44.5%、53.9%,远高于其他8株筛选菌,为PAHs高效降解菌株。3种菌株两两之间和三者组合均无拮抗关系。研究结果将为构建高效的多环芳烃降解菌群、提高多环芳烃原位污染土壤的生物修复效果奠定基础。     

一株高效降解芘的细菌分离、鉴定及其降解效果

摘要：【目的】获得高效降解高分子量多环芳烃的细菌,并研究其对多环芳烃的降解能力。【方法】利用富集培养和芘升华平板方法,从焦化厂污染土壤中分离多环芳烃降解细菌,对分离菌株通过形态特征、16S rRNA基因和gyrb基因序列相似性分析进行鉴定,并研究该菌对高分子量多环芳烃（HMW-PAHs）的降解效果。【结果】筛选到一株能以芘、苯并蒽、屈、苯并芘、茚并芘、苯并苝、荧恩为碳源和能源生长并降解这些底物的菌株HBS1,该菌株的16S rRNA基因和gyrb基因序列与Gordonia amicalis的相应基因的相似     

三株降解芘的戈登氏菌鉴定及其降解能力

从沈抚灌区多环芳烃污染土壤中筛选出的芘降解菌D44、D82S和D82Q,经形态观察、生理生化试验和16S rDNA序列分析确定均为戈登氏菌属(Gordonia sp.).3株菌的最适生长pH值均为7,当pH值低于5或高于9时,生长均受到明显抑制.降解试验表明,3株菌能以芘、苯并芘、蒽、萘、菲和荧蒽为唯一碳源和能源生长.经过7 d的培养,3株菌对初始浓度为100 mg.L-1的芘的降解率均在65%以上,对初始浓度为50 mg.L-1的苯并芘的降解率分别为79.6%、91.3%和62.8%.通过PCR检测发现D82Q和D82S含有烷烃单加氧酶基因alkB.     

焦化厂地肤根内解芘细菌的筛选及促生潜力

从多环芳烃耐受植物根内分离具多环芳烃降解功能的内生细菌并研究其促生特性,为内生菌协同宿主植物修复多环芳烃污染土壤提供基础.以长期受多环芳烃污染的焦化厂区生长的地肤为材料,从其根内分离出以芘和1-氨基环丙烷-1-羧酸(ACC)为唯一碳源和氮源的内生细菌8株.通过芘降解试验,筛选得到3株高效芘降解内生细菌KSE4、KSE7和KSE8,经鉴定分别为芽孢杆菌属、假单胞菌属和鞘氨醇菌属.通过液体培养试验,研究了3株菌在芘胁迫下产ACC脱氨酶的能力和对地肤种子萌发的影响.结果表明: 随着芘浓度(0~15 mg·L^-1)的升高,ACC脱氨酶活性降低,其中KSE7的效果最好,在芘浓度为15 mg·L^-1时,地肤发芽率和芽长分别比对照提高了44.8%和61.1%,在地肤-微生物修复焦化厂污染土壤的修复中具有一定的应用潜力.     

Optimized cultivation of highly-efficient degradation bacterial strains and their degradation ability towards pyrene

Two bacterial strains,Pyl and Py4,have been tamed and isolated through long cultivation with polycyclic aromatic hydrocarbon-pyrene as the single carbon source.It has been proven that they are both highly-efficient pyrene degrading bacteria and both Bacillus sp..The pyrene degradation ability of separated Pyl,Py4 and the consortium of equal Pyl and Py4 was studied in this project.It is shown that pyrene degradation rates were 88% in 10hr by Py1,84% in 14hr by Py4,and 88% in 8hr by the consortium.It was also determined that the best degradation temperatures were 37℃ and pH 7.0 respectively.The influence of different nutrient substrates added in the degradation experiments was also studied.It was shown that sodium salicylate,sodium acetate and yeast exuact had obvious simulative effect,but glucose had no obvious effect.     

Physiological characterization of Mycobacterium sp. strain 1B isolated from a bacterial culture able to degrade high-molecular-weight polycyclic aromatic hydrocarbons

AIM: The aim of this study was to further characterize a bacterial culture (VUN 10,010) capable of benzo[a]pyrene cometabolism. METHODS AND RESULTS: The bacterial culture, previously characterized as a pure culture of Stenotrophomonas maltophilia (VUN 10,010), was found to also contain another bacterial species (Mycobacterium sp. strain 1B), capable of degrading a similar range of PAH substrates. Analysis of its 16S rRNA gene sequence and growth characteristics revealed the strain to be a fast-growing Mycobacterium sp., closely related to other previously isolated PAH and xenobiotic-degrading mycobacterial strains. Comparison of the PAH-degrading characteristics of Mycobacterium sp. strain 1B with those of S. maltophilia indicated some similarities (ability to degrade phenanthrene and pyrene), but some differences were also noted (S. maltophilia able to degrade fluorene, but not fluoranthene, whereas Mycobacterium sp. strain 1B can degrade fluoranthene, but not fluorene). Unlike the S. maltophilia culture, there was no evidence of benzo[a]pyrene degradation by Mycobacterium sp. strain 1B, even in the presence of other PAHs (ie pyrene) as co-metabolic substrates. Growth of Mycobacterium sp. strain 1B on other organic carbon sources was also limited compared with the S. maltophilia culture. CONCLUSIONS: This study isolated a Mycobacterium strain from a bacterial culture capable of benzo[a]pyrene cometabolism. The Mycobacterium strain displays different PAH-degrading characteristics to those described previously for the PAH-degrading bacterial culture. It is unclear what role the two bacterial strains play in benzo[a]pyrene cometabolism, as the Mycobacterium strain does not appear to have endogenous benzo[a]pyrene degrading ability. SIGNIFICANCE AND IMPACT OF THE STUDY: This study describes the isolation and characterization of a novel PAH-degrading Mycobacterium strain from a PAH-degrading culture. Further studies utilizing this strain alone, and in combination with other members of the consortium, will provide insight into the diverse roles different bacteria may play in PAH degradation in mixed cultures and in the environment.     

Effect of rhamnolipids on degradation of anthracene by two newly isolated strains, Sphingomonas sp. 12A and Pseudomonas sp. 12B

Anthracene is a PAH that is not readily degraded, plus its degradation mechanism is still not clear. Thus, two strains of bacteria-degrading bacteria were isolated from longterm petroleum-polluted soil and identified as Sphingomonas sp. 12A and Pseudomonas sp. 12B by a 16S rRNA sequence analysis. To further enhance the anthracene-degrading ability of the two strains, the biosurfactants produced by Pseudomonas aeruginosa W3 were used, which were characterized as rhamnolipids. It was found that these rhamnolipids dramatically increased the solubility of anthracene, and a reverse-phase HPLC assay showed that the anthracene degradation percentage after 18 days with Pseudomonas sp. 12B was significantly enhanced from 34% to 52%. Interestingly, their effect on the degradation by Sphingomonas sp. 12A was much less, from 35% to 39%. Further study revealed that Sphingomonas sp. 12A also degraded the rhamnolipids, which may have hampered the effect of the rhamnolipids on the anthracene degradation.     

The strategy of strain selection for a mixed culture performing rapid conversion of a mixture of polyaromatic compounds

The strain Sphingomonas sp. VKM V-2434 converts the mixture of seven polyaromatic compounds (PACs): fluorene, dibenzothiophene, carbazole, phenanthrene, anthracene, fluoranthene, and pyrene. The effect of each of the above PACs on the rate of mixture conversion was determined. The following two strains, which utilize the substances inhibiting the studied process, were added to the culture: strain FON-11 utilizing 9-fluorenone (fluorene metabolite) and strain CBZ-21 utilizing carbazole. In the case of the mixed culture of three strains, conversion rates were 1.5 and 1.2–3.8 times higher for the PAC mixture and its individual components, respectively, than the rates for Sphingomonas sp. VKM V-2434 monoculture. The degree of degradation of PAC conversion products increased from 32 to 44%. The rate of PAC conversion by the mixed culture exceeded the sum of conversion rates for the individual component strains; this cooperative effect was particularly marked for anthracene and pyrene.     

Isolation and characterization of heavy polycyclic aromatic hydrocarbon-degrading bacteria adapted to electrokinetic conditions

Polycyclic aromatic hydrocarbon (PAH)-degrading bacteria capable of growing under electrokinetic conditions were isolated using an adjusted acclimation and enrichment procedure based on soil contaminated with heavy PAHs in the presence of an electric field. Their ability to degrade heavy PAHs under an electric field was individually investigated in artificially contaminated soils. The results showed that strains PB4 (Pseudomonas fluorescens) and FB6 (Kocuria sp.) were the most efficient heavy PAH degraders under electrokinetic conditions. They were re-inoculated into a polluted soil from an industrial site with a PAH concentration of 184.95 mg kg^?1. Compared to the experiments without an electric field, the degradation capability of Pseudomonas fluorescens and Kocuria sp. was enhanced in the industrially polluted soil under electrokinetic conditions. The degradation extents of total PAHs were increased by 15.4 and 14.0 % in the electrokinetic PB4 and FB6 experiments (PB4 + EK and FB6 + EK) relative to the PB4 and FB6 experiments without electrokinetic conditions (PB4 and FB6), respectively. These results indicated that P. fluorescens and Kocuria sp. could efficiently degrade heavy PAHs under electrokinetic conditions and have the potential to be used for the electro-bioremediation of PAH-contaminated soil, especially if the soil is contaminated with heavy PAHs.     

Using population dynamics analysis by DGGE to design the bacterial consortium isolated from mangrove sediments for biodegradation of PAHs

There are many PAH-degrading bacteria in mangrove sediments and in order to explore their degradation potential, surface sediment samples were collected from a mangrove area in Fugong, Longhai, Fujian Province of China. A total of 53 strains of PAH-degrading bacteria were isolated from the mangrove sediments, consisting of 14 strains of phenanthrene (Phe), 13 strains of pyrene (Pyr), 13 strains of benzo[a]pyrene (Bap) and 13 strains of mixed PAH (Phe + Pyr + Bap)-degrading bacteria. All of the individual colonies were identified by 16S rDNA sequencing. Based on the information of bacterial PCR-DGGE profiles obtained during enrichment batch culture, Phe, Pyr, Bap and mixed PAH-degrading consortia consisted of F1, F2, F3, F4 and F15 strains, B1, B3, B6, B7 and B13 strains, P1, P2, P3, P5 and P7 strains, M1, M2, M4, M12 and M13 strains, respectively. In addition, the degradation ability of these consortia was also determined. The results showed that both Phe and mixed PAH-degrading consortia had the highest ability to degrade the Phe in a liquid medium, with more than 91% being degraded in 3 days. But the biodegradation percentages of Pyr by Pyr-degrading consortium and Bap by Bap-degrading consortium were relatively lower than that of the Phe-degrading consortium. These results suggested that a higher degradation of PAHs depended on both the bacterial consortium present and the type of PAH compound. Moreover, using the bacterial community structure analysis method, where the consortia consist of different PAH-degrading bacteria, the information from the PCR-DGGE profiles could be used in the bioremediation of PAHs in the future.     

Bioremediation of a polyaromatic hydrocarbon contaminated soil by native soil microbiota and bioaugmentation with isolated microbial consortia

Biodegradation of a mixture of PAHs was assessed in forest soil microcosms performed either without or with bioaugmentation using individual fungi and bacterial and a fungal consortia. Respiratory activity, metabolic intermediates and extent of PAH degradation were determined. In all microcosms the low molecular weight PAH’s naphthalene, phenanthrene and anthracene, showed a rapid initial rate of removal. However, bioaugmentation did not significantly affect the biodegradation efficiency for these compounds. Significantly slower degradation rates were demonstrated for the high molecular weight PAH’s pyrene, benz[a]anthracene and benz[a]pyrene. Bioaugmentation did not improve the rate or extent of PAH degradation, except in the case of Aspergillus sp. Respiratory activity was determined by CO₂ evolution and correlated roughly with the rate and timing of PAH removal. This indicated that the PAHs were being used as an energy source. The native microbiota responded rapidly to the addition of the PAHs and demonstrated the ability to degrade all of the PAHs added to the soil, indicating their ability to remediate PAH-contaminated soils.     

东北旱田土壤中Anabaena伴生细菌的分离与鉴定

[背景]鱼腥藻(Anabaena)在农田土壤中广泛分布,具有固碳和固氮功能。明确伴生细菌与蓝细菌的关系,对提高农田土壤中Anabaena的功能具有重要意义。[目的]从东北不同旱田土壤中分离Anabaena sp.PCC7120的伴生细菌,初步鉴定伴生细菌的分类归属,推测伴生细菌的功能,为明确旱田土壤蓝细菌与伴生细菌的关系提供数据支撑。[方法]采用平板分离、PCR-DGGE、克隆测序技术测定并分析不同旱田土壤中伴生细菌的16S rRNA基因序列,确定伴生细菌的分类地位。[结果]PCR-DGGE图谱显示东北旱田14个土样中分离获得Anabaena sp.PCC7120伴生细菌数量和种类不同;PCR-克隆测序获得伴生细菌的16S rRNA基因序列37条,可鉴定到种水平的菌株36条,主要归为鞘氨醇盒菌属(Sphingopyxis)、贪噬菌属(Variovorax)、黄杆菌属(Flavobacterium)和红球菌属(Rhodococcus)等,推测这些伴生细菌具有适应寡营养、富集微量元素、清除毒素等功效。[结论]东北旱田不同土壤中Anabaena sp.PCC7120伴生细菌种类和数量各异,这些伴生细菌主要隶属于Sphingopyxis、Variovorax、Flavobacterium和Rhodococcus等属。     

炔草酯降解菌Sphingopyxis sp. WP68的分离鉴定与降解特性

【背景】炔草酯可以高效防除麦田恶性杂草,但炔草酯的生产和使用也对环境造成了破坏,对动物和人类健康造成了威胁。【目的】分离筛选炔草酯高效降解菌株,研究其降解特性,为炔草酯污染生物修复提供优良菌种资源。【方法】采集农药厂活性污泥样品,通过富集培养和含有炔草酯的LB培养基进行炔草酯降解菌株的分离,通过形态和生理生化特性以及16S rRNA基因序列分析确定其分类学地位,通过单因素试验从温度、pH、接种量和底物浓度等方面考察菌株对炔草酯的降解特性,并利用UPLC-MS分析降解产物。【结果】筛选出一株炔草酯高效降解菌株WP68,经鉴定为鞘氨醇盒菌(Sphingopyxis sp.),该菌株在37°C和pH值为8.0时,10 h内可将200 mg/L的炔草酯降解98.26%。利用UPLC-MS鉴定菌株WP68降解炔草酯的产物为炔草酸。确定了该菌株降解炔草酯的最适温度、pH值、接种量、底物浓度分别是37°C、8.0、5%、200mg/L。菌株WP68还能降解氰氟草酯和精喹禾灵。【结论】Sphingopyxis sp. WP68对炔草酯有较强的降解能力和较高耐受性,在炔草酯污染土壤修复中具有潜在的应用前景。