Crops ›› 2016, Vol. 32 ›› Issue (1): 62-68.doi: 10.16035/j.issn.1001-7283.2016.01.012

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Effects of Cry1Ie on Soil Macrofauna Diversity in Transgenic Corn IE09S034 Fields

Liu Xinying1,Wang Baifeng2,Zhou Lin1,Feng Shudan1,Song Xinyuan2   

  1. 1 Harbin Normal University,Harbin 150025,Heilongjiang,China
    2 Jilin Academy of Agricultural Sciences,Changchun 130033,Jilin,China
  • Received:2015-12-11 Revised:2016-01-05 Online:2016-02-15 Published:2018-08-25
  • Contact: Shudan Feng

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Abstract:

IE09S034 is a genetically modified corn variety with Cry1Ie insect-resistant gene and independent intellectual property rights in China. Hand-sorting and pitfall traps methods were used to investigate the effects of IE09S034 cultivation on community composition, community structure and dynamics of dominant groups of soil macrofauna in corn fields.The results showed community composition,species richness, Shannon-wiener diversity index and Pielou index and dynamics of dominant groups did not significantly been changed in IE09S034 compared to the non-transgenic corn Zong 31. It is indicated that no environmental risk of IE09S034 cultivation on soil macrofauna were found in corn filed.

Key words: Genetically modified corn, Soil macrofauna, Bt-cry1Ie gene, Community diversity

Table 1

Individual number of soil animals of hand-sorting method in corn field"

类群Groups IE09S034 综31(CK)
鞘翅目幼虫Coleoptera larvae 2.16±0.29a 2.36±0.26a
石蜈蚣目Lithobiomorpha 0.04±0.03a 0.04±0.03a
地蜈蚣目Geophilomorpha 0.47±0.16a 0.69±0.16a
单向蚓目Haplotaxida 1.18±0.24a 1.11±0.21a
鞘翅目成虫Coleoptera adult 0.91±0.21a 0.58±0.14a
蚁科Formicidae 0.09±0.05a 0.04±0.03a
鳞翅目幼虫Lepidoptera larvae 0.02±0.02a 0.11±0.05b
蜘蛛目Araneae 0.40±0.12a 0.49±0.14a
蟋蟀科Gryllidae 0.18±0.07a 0.18±0.07a
直翅目幼虫Orthoptera larvae 0.16±0.06a 0.13±0.05a
蠼螋科Labiduridae 0.02±0.02a 0.02±0.02a
半翅目Hemiptera 0.16±0.05a 0.16±0.05a
啮虫目Psocoptera 0.13±0.06a 0.13±0.06a
瓢甲科Coccinellidae 0.36±0.10a 0.36±0.10a
总计Total 6.28±1.48a 6.40±1.37a

Fig.1

Species richness of soil macrofauna of hand-sorting method"

Fig.2

Individual number of soil macrofauna of hand-sorting method"

Fig.3

Shannon-wiener diversity index of soil macrofauna of hand-sorting method"

Fig.4

Pielou evenness index of soil macrofauna of hand-sorting method"

Fig.5

Population dynamics of Coleoptera larvae of hand-sorting method"

Fig.6

Population dynamics of Haplotaxida of hand-sorting method"

Fig.7

Population dynamics of Coleoptera adult of hand-sorting method"

Table 2

Individual number of soil animals of pitfall traps method in corn field"

类群Groups IE09S034 综31(CK)
弹尾目Collembola 6.30±1.37a 5.93±1.12a
缨翅目Thysanoptera 0.43±0.12a 0.33±0.09a
蚁科Formicidae 2.86±0.47a 2.67±0.49a
鞘翅目幼虫Coleoptera larvae 0.60±0.21a 0.67±0.17a
蜘蛛目Araneae 0.47±0.11a 0.37±0.09a
鞘翅目成虫Coleoptera adult 0.33±0.11a 0.47±0.15a
石蜈蚣目Lithobiomorpha 0.07±0.05a 0.10±0.06a
蟋蟀科Gryllidae 0.43±0.12a 0.50±0.15a
啮虫目Psocoptera 0.07±0.05a 0.03±0.03a
蠼螋科Labiduridae 0.10±0.06a 0.07±0.05a
蜱螨目Acarina 0.07±0.05a 0.03±0.03a
总计Tatal 11.73±2.72a 11.17±2.43a

Fig.8

Species richness of soil macrofauna of pitfall traps method"

Fig.9

Individual number of soil macrofauna in pitfall traps method"

Fig.10

Shannon-wiener diversity index of soil macrofauna community in pitfall traps method"

Fig.11

Pielou evenness index of soil macrofauna community of pitfall traps method"

Fig.12

Population dynamics of Collembola of pitfall traps method"

Fig.13

Population dynamics of Formicidae of pitfall traps method"

[1] 数据基因农业网.ISAAA信息.生物技术通报, 2015(2):102.
[2] 刘慧, 何康来, 白树雄 , 等. 转cry1Ab基因玉米对瓢虫科天敌种群动态的影响. 生物安全学报, 2012,21(2):130-134.
[3] 刘俊峰, 邸宏, 曾兴 , 等. 转BcBCP1基因耐盐碱玉米对田间节肢动物群落的影响分析.玉米科学, 2013(3):35-39.
[4] Stephens E J, Losey J E, Allee L L , et al. The impact of Cry3Bb Bt-maize on two guilds of beneficial beetles.Agriculture, Ecosystems & Environment, 2012,156:72-81.
[5] 孙彩霞, 武志杰, 陈利军 , 等. 转Bt基因玉米的生态安全性研究进展. 生态学报, 2004,24(4):798-805.
[6] 吴立成, 李啸风, 叶庆富 , 等. 转cry1Ab基因水稻中毒蛋白的表达、分泌及其在土壤中的残留. 环境科学, 2004,25(5):116-121.
[7] Icoz I, Stotzky G . Fate and effects of insect-resistant Bt crops in soil ecosystems. Soil Biology & Biochemistry, 2008,40(3):559-586.
[8] 杨艳, 李云河, 曹凤勤 , 等. 转Bt基因抗虫作物对鳞翅目非靶标昆虫生态影响的研究进展. 生物安全学报, 2015,23(4):224-237.
[9] 袁一杨, 戈峰 . 转Bt基因作物对非靶标土壤动物的影响.应用生态学报, 2010(5):1339-1345.
[10] 尹文英 . 中国土壤动物检索图鉴.北京: 科学出版社, 1998.
[11] 钟觉民 . 幼虫分类学.北京: 农业出版社, 1990.
[12] 张巍巍, 李元胜 . 中国昆虫生态大图鉴.重庆: 重庆大学出版社, 2011.
[13] Yuan Y, Xin K, Chen F , et al. Decrease in catalase activity of Folsomia candida fed a Bt rice diet. Environmental Pollution, 2011,159(12):3714-3720.
doi: 10.1016/j.envpol.2011.07.015
[14] Cortet J, Griffiths B S, Bohanec M , et al. Evaluation of effects of transgenic Bt maize on microarthropods in a European multi-site experiment. Pedobiologia, 2007,51(3):207-218.
doi: 10.1016/j.pedobi.2007.04.001
[15] Vaufleury A D, Kramarz P E, Binet P , et al. Exposure and effects assessments of Bt-maize on non-target organisms (gastropods, microarthropods,mycorrhizal fungi) in microcosms. Pedobiologia, 2007,51(3):185-194.
doi: 10.1016/j.pedobi.2007.04.005
[16] Birch A N E, Griffiths B S, Caul S , et al. The role of laboratory,glasshouse and field scale experiments in understanding the interactions between genetically modified crops and soil ecosystems:A review of the ECOGEN project. Pedobiologia, 2007,51(3):251-260.
doi: 10.1016/j.pedobi.2007.04.008
[17] Bing Y, Hui C, Liu X , et al. Bt cotton planting does not affect the community characteristics of rhizosphere soil nematodes. Applied Soil Ecology, 2014,73(1):156-164.
doi: 10.1016/j.apsoil.2013.09.001
[18] Saxena D, Stotzky G . Bacillus thuringiensis (Bt) toxin released from root exudates and biomass of Bt corn has no apparent effect on earthworms,nematodes,protozoa,bacteria,and fungi in soil. Soil Biology & Biochemistry, 2001,33(1):1225-1230.
[19] Zeilinger A R, Andow D A, Zwahlen C , et al. Earthworm populations in a northern U.S.Cornbelt soil are not affected by long-term cultivation of Bt maize expressing Cry1Ab and Cry3Bb1 proteins. Soil Biology & Biochemistry, 2010,42(8):1284-1292.
[20] Weber M, Nentwig W . Impact of Bt corn on the diplopod Allajulus latestriatus. Pedobiologia, 2006,50(4):357-368.
doi: 10.1016/j.pedobi.2006.06.004
[21] Floate K D, Cárcamo H A, Blackshaw R E , et al. Response of ground beetle (Coleoptera:Carabidae) field populations to four years of Lepidoptera-specific Bt corn production. Environmental Entomology, 2007,36(5):1269-1274.
doi: 10.1603/0046-225X(2007)36[1269:ROGBCC]2.0.CO;2
[22] Manachini B . Ground beetle assemblages (Coleoptera,Carabidae) and plant dwelling non-target arthropods in isogenic and transgenic corn crops. Bollettino Di Zoologia Agraria E Di Bachicoltura, 2000,32:181-198.
[23] Twardowski J, Beres P, Hurej M , et al. A quantitative assessment of the unintended effects of Bt-maize (MON 810) on rove beetle (Coleoptera,Staphylinidae) assemblages. Polish Journal of Environmental Studies, 2014,23(1):215-220.
[24] 祝向钰, 李志毅, 常亮 , 等. 转Bt水稻土壤跳虫群落组成及其数量变化. 生态学报, 2012,32(11):3546-3554.
doi: 10.5846/stxb201105170640
[25] Chang L, Liu X, Ge F . Effect of elevated O3 associated with Bt cotton on the abundance,diversity and community structure of soil Collembola. Applied Soil Ecology, 2011,47(1):45-50.
doi: 10.1016/j.apsoil.2010.10.013
[26] 郭井菲, 张聪, 袁志华 , 等. 转cry1Ie基因抗虫玉米对田间节肢动物群落多样性的影响. 植物保护学报, 2014,41(4):482-489.
[27] 王培, 王应伦, 王振营 , 等. 转cry1Ac基因玉米对玉米田非靶标节肢动物群落多样性的影响.植保科技创新与病虫防控专业化——中国植物保护学会2011年学术年会论文集.北京: 中国农业科学技术出版社, 2011: 814.
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