Chinese Journal of Applied Ecology ›› 2002, Vol. ›› Issue (4): 491-494.
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WANG Jianwu, FENG Yuanjiao, LUO Shiming
Received:
2001-09-03
Revised:
2001-12-11
Online:
2002-04-15
CLC Number:
WANG Jianwu, FENG Yuanjiao, LUO Shiming . Effects of transgenic crops on soil ecosystem[J]. Chinese Journal of Applied Ecology, 2002, (4): 491-494.
[1] Angle JS.1994.Release of transgenic plants:Biodiversity and population-le vel considerations.Mol Ecol,3:45~50 [2] Beringer JE.2000.Releasing genetically modified organisms:Will any harm ou tweigh and advantage? J Appl Ecol,37:207~214 [3] Colwell RK,Norse EA,Pimentel D,et al.1985.Genetic engineering in agricult ure.Science,229:111~112 [4] Crecchio C,Stotzky G.1998.Insecticidal activity and biodegradation of the toxin from Bt bound to humic acids from soil.Soil Biol Biochem,30(4):463~470 [5] Digiovanni GD,Watrud LS,Seidler RJ,et al.1999.Comparison of parental and transgenic alfalfa rhizosphere bacterial communities using Biolog GN metabolic f ingerprinting and enterobacterial repetitive intergenic consensus sequence-PCR(ERIC-PCR).Microb Ecol,37:129~139 [6] Digiovanni GD,Watrud LS,Seidler RJ,et al.1999.Fingerprinting of mixed bac terial strains and Biolog gram negative(GN) substrate communities by enterobacte rial repetitive intergenic consensus sequence-PCR(ERIC-PCR).Curr Microbiol,38:217~223 [7] Ding Z-Y(丁志勇),Xu C-R(许崇任),Wang R-J(王戎疆).2001.Comparison of several important isoenzymes between Bt cotton and regular cotton.Acta Ecol Si n(生态学报),21(2):332~336(in Chinese) [8] Donegan KK,Palm CJ,Fieland VJ,et al.1995.Changes in levels,species,and DNA fingerprints of soil microorganisms associated with cotton expressing the Bacillus thuringiensis var.kurstaki endotoxin.Appl Soil Ecol,2:111~124 [9] Donegan KK,Schaller DL,Stone JK,et al.1996.Microbial populations,fungal species diversity and plant pathogen levels in field plots of potato plants expr essing the Bacillus thuringiensis var.tenbrionls endotoxin.Transgenic Res,5:25~35 [10] Donegan KK,Seidler RJ,Doyle JD,et al.1999.A field study with genetically engineered alfalfa inoculated with recombinant Sinorhizobium meliloti:Effec ts on the soil ecosystem.J Appl Ecol,36:9 20~936 [11] Donegan KK,Seidler RJ,Fieland VJ,et al.1997.Decomposition of genetically engineered tobacco under field conditions:Persistence of the proteinase inhibi tor I product and effects on soil microbial respiration and protozoa,nematode a nd microarthropod populations.J Appl Ecol,34:767~777 [12] Grayston SJ,Wang S,Campbell CD,et al.1998.Selective influence of plant s pecies on microbial diversity in the rhizosphere.Soil Biol Biochem,30:369~378 [13] Griffiths BS,Geoghegan IE,Robertson WM.2000.Testing genetically engineere d potato,producing the lectins GNA and Con A,on non-target soil organisms and processes.J Appl Ecol,37:159~170 [14] Heuer H,Smalla K.1997.Application of denaturing gradient gel electrophores is and temperature gradient gel electrophoresis for studying soil microbial comm unities.In:van Elsas JJ,Trevors JT,Wellington EMH eds.Modern Soil Microbiol ogy.New York:Marcel Dekker.353~373 [15] Ingham RE,Trofymow JA,Ingham ER,et al.1985.Interactions of bacteria,fun gi,and their nematode grazers:Effects of nutrient cycling and plant growth.Ecol Mono,55:119~140 [16] Jepson PC,Croft BA,Pratt GE.1994.Test systems to determine the ecologica l risks posed by toxin release from Bacillus thuringiensis genes in crop pla nts.Mol Ecol,3:81~89 [17] Lottmann J,Heuer H,Smalls K,et al.1999.Influence of transgenic T4-lysozy me-producing potato plants on potentially beneficial plant -associated bacteri a.FEMS Microbiol Ecol,29:365~377 [18] Lottmann J,Heuer H,Vries J,et al.2000.Establishment of introduced antagon istic bacteria in the rhizosphere of transgenic potatoes and their effect on the bacterial community.FEMS Microbiol Ecol,33 :41~49 [19] Lukow T,Dunfield PF,and Liesack W.2000.Use of the T-RFLP technique to as sess spatial and temporal changes in the bacterial community structure within an agricultural soil planted with transgenic and non-transgenic potato plants.FEMS Microbiol Ecol,32:241~247 [20] McManus MT,White DWR,McGregor PG.1994.Accumulation of a chymotrypsin inhi bitor in transgenic tobacco can affect the growth of insect pests.Transgenic Res,3:50~58 [21] Morra MJ.1994.Assessing the impact of transgenic plant products on soil org anisms.Mol Ecol,3:53~55 [22] Oger P,Petit A,Dessaux Y.1997.Genetically engineered plants producing opi ns alter their biological environment.Nature Biotechnol,15 :369~372 [23] Qian Y-Q(钱迎倩),Ma K-P(马克平).1998.Progress in the studies on genetica lly modified organisms,and the impact of its release on environment.Acta Ecol Sin(生态学报),18(1):1~9(in Chinese) [24] Qian Y-Q(钱迎倩),Tian Y(田彦) & Wei W(魏伟).1998.Ecological risk assessme nt of transgenic plants.Acta Phytoecol Sin (植物生态学报),22(4):289~299(in Chinese) [25] Qian Y-Q(钱迎倩),Wei W(魏伟),Sang W-G(桑卫国) & Ma K-P(马克平).2001.Ef fect of transgenic crops on biodiversity.Acta Ecol Sin(生态学报),21(3):337~343(in Chinese) [26] Savka MA,Farrand SK.1997.Modification of rhizobacterial populations by eng ineering bacterium utilization of a novel plant-produced resource.Nature Biotechnol,15:363~368 [27] Saxena D,Stotzky G.2000.Insecticidal toxin from Bacillus thuringiensis is released from roots of transgenic Bt corn in vitro and in situ.FEMS Micr obiol Ecol,33:35~39 [28] Saxena D,Stotzky G.2001.Bacillus thuringiensis (Bt) toxin released from root exudates and biomass of Bt corn has no apparent effect on earthworms,nemat odes,protozoa,bacteria,and fungi in soil.Soil Biol Biochem, 33:1225~1230 [29] Saxena D,Flores S,Stotzky G.1999.Insecticidal toxin in root exudates from Bt corn.Nature,402:480 [30] Seidler RJ,Levin M.1994.Potential ecological and nontarget effects of tran sgenic plant gene products on agriculture,silviculture,and natural ecosystems: General introduction.Mol Ecol,3:1~3 [31] Sims SR,Holden LR..1996.Insect bioassay or determining soil degradation of Bacillus thuringiensis ssp.kurstaki CryIA(b) protern in corn tissue.Environ Entomol,25:659~664 [32] Sims SR,Ream JE.1997.Soil inactivation of the Bacillus thuringiensis ssp. kurstaki cryIIA insecticidal protein within transgenic cotton tissue:Laborat ory microcosm and field studies.J Agrc Food Chem,45 :1502~1505 [33] Snow AA,Palma PM.1997.Commercialization of transgenic plants:Potential ec ological risks.Bioscience,47(2):86~96 [34] Stotzky G.2000.Persistence and biological activity in soil of insecticidal proteins from Bacillus thuringiensis and of bacterial DNA bound on clays and humic acids.J Environ Qual,29:691~705 [35] Tapp H,Stotzky G.1995.Dot blot enzyme-linked immunoabsorbent assay for mo nitoring the fate of insecticidal toxins from Bacillus thuringiensis in soil.Appl Environ Microbiol,61:602~609 [36] Tapp H,Stotzky G.1998.Persistence of the insecticidal toxin from Bacillus thuringiensis subsp.kurstaki in soil.Soil Biol Biochem,30(4):471~476 [37] Tiedje JM,Colwell RK,Grossman YL,et al.1989.The planned introduction of g enetically engineered organisms:Ecological considerations and recommendations. Ecology,70:298~315 [38] Trevors JT,Kuikman P,Watson B.1994.Transgenic plants and biogeochemical c ycles.Mol Ecol,3:57~64 [39] US EPA.2000b.Bacillus thuringiensis Plant-pestcides Registration Action Do cument:Preliminary Risks and Benefits Sections.U.S.Environmental Protection Ag ency,Office of Pesticide Programs,Washington,DC.(http://www.epa.gov/pestici des/biopesticides/ news/news-bt-corps-sap-oct.htm) [40] Watrud LS,Seidler RJ.1998.Nontarget ecological effects of plant,microbial,and chemical introductions to terrestrial systems. Soil Chemistry and Ecosyst em Health.Special Publication 52.Soil Science Society of America,Madison,Wisco nsin.313~340 [41] Wei W(魏伟),Qian Y-Q(钱迎倩) & Ma K-P(马克平).1999.Pests resistance to t ransgenic Bt crops and their management strategies.Chin J Appl Environ Biol(应用与环境生物学报),5(2):215~222(in Chin ese) [42] Wei W(魏伟),Qian Y-Q(钱迎倩),Ma K-P(马克平).1999.Gene flow between tran sgenic crops and their wild related species.Acta Bot Sin(植物学报),41(4):343~348(in Chinese) [43] Wolfenbarger LL,Phifer PR.2000.The ecological risks and benefits of geneti cally engineered plants.Science,290:2088~2093 [44] Yu I,Berry RE,Coroft BA.1997.Effects of Bacillus thuringiensis toxin in t ransgenic cotton and potato on Folsomia candida (Collembda:Isotomodae) and Oppia nitens (Acavi:Orbatidae).J Econ Entomol,90(1):113~118 |
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