Bioaugmentation strategy to enhance cypermethrin degradation by immobilized Pseudomonas aeruginosa GF31

doi:10.3969/j.issn.0438-1157.2013.06.042

CIESC Journal ›› 2013, Vol. 64 ›› Issue (6): 2219-2226.DOI: 10.3969/j.issn.0438-1157.2013.06.042

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Bioaugmentation strategy to enhance cypermethrin degradation by immobilized Pseudomonas aeruginosa GF31

LI Qingyun¹, ZHOU Maozhong¹, LIU Youyan^1,2, TANG Aixing¹, QIN Yimin¹, LIANG Siting¹, WEI Yingjun³

1. School of Chemistry and Chemical Engineering, Guangxi University, Nanning 530004, Guangxi, China;
2. Guangxi Key Laboratory of Biorefining, Nanning 530003, Guangxi, China;
3. Plant Protection Station of Guangxi, Nanning 530022, Guangxi, China

Received:2012-10-15 Revised:2013-03-05 Online:2013-06-05 Published:2013-06-05
Supported by:
supported by the National Natural Science Foundation of China(21066001).

固定化铜绿假单胞菌GF31对氯氰菊酯降解的强化作用

李青云¹, 周茂钟¹, 刘幽燕^1,2, 唐爱星¹, 覃益民¹, 梁思婷¹, 韦滢军³

1. 广西大学化学化工学院,广西南宁530004;
2. 广西生物炼制重点实验室,广西南宁 530003;
3. 广西植保总站,广西南宁 530022

通讯作者: 刘幽燕
作者简介:李青云(1978—),女,讲师。
基金资助:
国家自然科学基金项目(21066001);广西科学基金项目(桂科自0728047)。

Abstract

Abstract: The immobilization of Pseudomonas aeruginosa GF31 and its enhancement of biodegradation of cypermethrin were investigated.Zeolite was chosen as a suitable support for the immobilization by taking into account the properties of cypermethrin and mass transfer in the bioremediation.Scanning electron microscope (SEM) images demonstrated that strain GF31 grew well in the pore of the zeolite.After immobilization,cypermethrin removal efficiency was improved significantly from 37% to 61.4% at initial cypermethrin concentration of 100 mg ·L^-1 in 6 d.The specific degradation rate of free cells and immobilized cells were 487 and 917 mg·[L·d· (g dry biomass) ]^-1 respectively, at 300 mg·L^-1 cypermethrin.It was also found that the immobilized cells exhibited higher tolerance to pH and cypermethrin concentration, keeping its activities even at pH 10 or higher cypermethrin concentration up to 800 mg·L^-1.The results of actual soil remediation by the immobilized cells showed that cypermethrin degradation could be well described by a first-order reaction rate equation.As compared to natural degradation, cypermethrin half life (t_1/2) was shortened from 34.3 d to 8.02 d, which illustrated a good result of bioaugmented remediation by the immobilized Pseudomonas aeruginosa GF31.

Key words: cypermethrin, immobilized cell, biodegradation, Pseudomonas aeruginosa, bioaugmentation

摘要： 研究了沸石固定化铜绿假单胞菌GF31的氯氰菊酯降解特性及强化修复效果。综合考虑氯氰菊酯特性及其传质等因素,选择沸石为载体进行固定化,电镜扫描结果显示,菌株GF31能较好地生长于沸石载体孔隙中。固定化后菌株GF31的去除率和比降解速率提高,6 d对100 mg·L^-1氯氰菊酯的去除率由37%提高至61.4%,游离细胞和固定化细胞对于300 mg·L^-1的氯氰菊酯的平均比降解速率分别为487和917 mg·[L·d·(g细胞干重)]^-1。固定化细胞对pH和高浓度氯氰菊酯的耐受性显著增强,在pH 10或者菊酯浓度为800 mg·L^-1时仍能保持一定的降解活力。投加固定化细胞对实际土壤进行生物强化修复,其降解过程可用一级动力学方程来描述。与自然降解相比,氯氰菊酯的半衰期t_1/2由34.3 d缩短至8.02 d,显示出固定化细胞良好的强化修复效果。

关键词: 氯氰菊酯, 固定化细胞, 生物降解, 铜绿假单胞菌, 强化作用

CLC Number:

X53
X592

LI Qingyun, ZHOU Maozhong, LIU Youyan, TANG Aixing, QIN Yimin, LIANG Siting, WEI Yingjun. Bioaugmentation strategy to enhance cypermethrin degradation by immobilized Pseudomonas aeruginosa GF31[J]. CIESC Journal, 2013, 64(6): 2219-2226.

李青云, 周茂钟, 刘幽燕, 唐爱星, 覃益民, 梁思婷, 韦滢军. 固定化铜绿假单胞菌GF31对氯氰菊酯降解的强化作用[J]. 化工学报, 2013, 64(6): 2219-2226.

References 20

[1]	Li Xiaobin(李晓斌),SunYujiao(孙寓姣),Wang Hongqi(王红旗),Ding Aizhong(丁爱中).Analysis of PAHs-degrading bacteria from contaminated soil at a coking plant[J].CIESC Journal(化工学报), 2010,61(2):476-483
[2]	Garcia Frutos F J, Escolano O, Garcia S, Babin M, Fernandez M D.Bioventing remediation and ecotoxicity evaluation of phenanthrene-contaminated soil[J].Journal of Hazardous Materials, 2010,183(1/2/3):806-813
[3]	Tallur P N, Megadi V B, Ninnekar H Z.Biodegradation of cypermethrin by Micrococcus sp.strain CPN1[J].Biodegradation, 2008,19(1):77-82
[4]	Kim I S, Park J S, Kim K W.Enhanced biodegradation of polycyclic aromatic hydrocarbons using nonionic surfactants in soil slurry[J].Applied Geochemistry, 2001,16(11/12):1419-1428
[5]	Mehler W T, Li Huizhen, Lydy M J, You Jing.Identifying the causes of sediment-associated toxicity in urban waterways of the Pearl River Delta,China[J].Environmental Science &Technology,2011,45:1812-1819
[6]	Grant R J, Betts W B.Biodegradation of the synthetic pyrethroid cypermethrin in used sheep dip[J].Letters in Applied Microbiology, 2003,36(3):173-176
[7]	Xu Yuxin(许育新),Li Xiaohui(李晓慧),Zhang Mingxing(张明星),Cui Zhongli(崔中利),Li Shunpeng(李顺鹏).Characters and pathway for degradation of cypermethrin by Rhodococcus sp.strain CDT3[J].China Environmental Science(中国环境科学), 2005,25(4):399-402
[8]	Manohar S,Kim C K,Karegoudar T B.Enhanced degradation of naphthalene by immobilization of Pseudomonas sp.strain NGK1 in polyurethane foam[J].Applied Microbiology and Biotechnology, 2001,55(3):311-316
[9]	Li Qingyun(李青云),Gu Baoqun(顾宝群),Liu Youyan(刘幽燕),Zhou Maozhong(周茂钟),Li Chan(李婵),Qin Yimin(覃益民),Zhong Shanjin(钟善锦).Isolation, identification and characteristics of a cypermethrin-degrading bacterium GF31[J].Microbiology(China)(微生物学通报), 2009,36(9):1334-1339
[10]	Goring C A I,Laskowski D A,Hamaker J W, et al. Principles of pesticide degradation in soil//Haque R, Freed V H.Environmental Dynamics of Pesticides[M].New York:Plenum Press, 1975:135-172
[11]	Moussavi G, Talebi S, Farrokhi M, Sabouti R M.The investigation of mechanism, kinetic and isotherm of ammonia and humic acid co-adsorption onto natural zeolite[J].Chemical Engineering Journal, 2011,171(3):1159-1169
[12]	Su D, Li P J, Frank S, Xiong X Z.Biodegradation of benzopyrene in soil by Mucor sp.SF06 and Bacillus sp.SB02 co-immobilized on vermiculite[J].Journal of Environmental Sciences, 2006,18(6):1204-1209
[13]	Malony S E, Maule A, Smith A R W.Purification and preliminary characterization of permethrinase from a pyrethroid-transforming strain of Bacillus cereus[J].Applied and Environmental Microbiology, 1993,59(7):2007-2013
[14]	Akdogan H A, Nurdan K P.Fluorene biodegradation by P.osteratus(Ⅱ):Biodegradation by immobilized cells in a recycled packed bed reactor[J].Process Biochemistry, 2011,46(4):840-846
[15]	Qu Jie(曲杰),Wang Haisheng(王海胜),Shi Yanhua(史延华),Li Kang(李康),Wang Shenghui(王圣惠),Yan Yanchun(闫艳春).Isolation, identification and characterization of cypermethrin-degrading strain L12[J].Acta Microbiologica Sinica(微生物学报), 2011,51(4):510-517
[16]	Jilani S, Altaf K M.Biodegradation of cypermethrin by Pseudomonas in a batch activated sludge process[J].International Journal of Environmental Science and Technology, 2006,3(4):371-380
[17]	Zita A, Hermansson M.Effects of bacterial cell surface structures and hydrophobicity on attachment to activated sludge flocs[J].Applied and Environmental Microbiology, 1997,63:1168-1170
[18]	Sun Xiaojing(孙小静),Ma Limin(马利民),Gong Bentao(龚本涛).The research for existence, behavior and analysis of cypermethrin in soil environment[J].Agrochemicals(农药), 2010,49(1):16-19
[19]	Rivelli V, Franzetti A, Gandolfi I, Cordoni S, Bestetti G.Persistence and degrading activity of free and immobilised allochthonous bacteria during bioremediation of hydrocarbon-contaminated soils[J].Biodegradation, 2012,23(2):77-82
[20]	Wang Xin(王鑫),Su Dan(苏丹),Li Haibo(李海波).Immobilization of combined bacteria and its degradation of benzopyrene in contaminated soil[J].Ecology and Environmental Sciences(生态环境学报), 2011,20(3):532-537

Bioaugmentation strategy to enhance cypermethrin degradation by immobilized Pseudomonas aeruginosa GF31

固定化铜绿假单胞菌GF31对氯氰菊酯降解的强化作用

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