转基因作物对土壤酶活性影响的研究进展-《江苏农业科学》

参考文献/References:

［1］张丽娜，于勇，韩冰，等. 甜瓜连作对土壤肥力及酶活性的影响［J］. 黑龙江农业科学，2016(6)：79-81.
［2］Kulandaivelu V，Desouza B. Impact of transgenic Bt cotton on soil health［J］. CAB Reviews，2017，12：1-8.
［3］杨万勤，王开运. 森林土壤酶的研究进展［J］. 林业科学，2004，40(2)：152-159.
［4］刘根林. 转基因大豆对根际土壤微生物群落的影响及其多样性指数的度量［D］. 南京：南京大学，2012.
［5］Fliebach A，Messmer M，Nietlispach B，et al. Effects of conventionally bred and Bacillus thuringiensis (Bt) maize varieties on soil microbial biomass and activity［J］. Biology & Fertility of Soils，2012，48(3)：315-324.
［6］Motavalli P P，Kremer R J，Fang M，et al. Impact of genetically modified crops and their management on soil microbially mediated plant nutrient transformations［J］. Journal of Environmental Quality，2004，33(3)：816-824.
［7］Lupwayi N Z，Hanson K G，Harker K N，et al. Soil microbial biomass，functional diversity and enzyme activity in glyphosate-resistant wheat-canola rotations under low-disturbance direct seeding and conventional tillage［J］. Soil Biology & Biochemistry，2007，39(7)：1418-1427.
［8］郭文文，李建勇，诸葛玉平，等. 转基因作物对土壤生态安全的影响［J］. 山东农业科学，2009(10)：86-90.
［9］关松荫. 土壤酶及其研究法［M］. 北京：农业出版社，1986.
［10］Chen Z H，Wei K，Chen L J，et al. Effects of the consecutive cultivation and periodic residue incorporation of Bacillus thuringiensis(Bt) cotton on soil microbe-mediated enzymatic properties［J］. Agriculture Ecosystems & Environment，2017，239：154-160.
［11］Xie M，Zhang Y J，Peng D L，et al. No significant impact of transgenic Cry1Ab/1AC cotton on rhizosphere-soil enzyme activities and bacterial communities［J］. Agronomy Journal，2017，109(4)：1271-1279.
［12］Mina U，Chaudhary A，Kamra A. Effect of Bt cotton on enzymes activity and microorganisms in rhizosphere［J］. Journal of Agricultural Science，2011，3(1)：96-104.
［13］Tarafdar J C，Rathore I，Shiva V. Effect of Bt-transgenic cotton on soil biological health［J］. Applied Biological Research，2012，14(1)：15-23.
［14］Singh R J，Ahlawat I P，Singh S. Effects of transgenic Bt cotton on soil fertility and biology under field conditions in subtropical inceptisol［J］. Environmental Monitoring & Assessment，2013，185(1)：485-495.
［15］Zhang Y J，Xie M，Li C Y，et al. Impacts of the transgenic CrylAc and CpTI insect-resistant cotton SGK321 on selected soil enzyme activities in the rhizosphere［J］. Plant，Soil and Environment，2014，60(9)：401-406.
［16］Chen Z H，Chen L J，Zhang Y L，et al. Microbial properties，enzyme activities and the persistence of exogenous proteins in soil under consecutive cultivation of transgenic cottons (Gossypium hirsutum L.)［J］. Plant，Soil and Environment，2011，57(2)：67-74.
［17］Chen Z H，Chen L J，Wu Z J. Relationships among persistence of Bacillus thuringiensis and cowpea trypsin inhibitor proteins，microbial properties and enzymatic activities in rhizosphere soil after repeated cultivation with transgenic cotton［J］. Applied Soil Ecology，2012，53(2)：23-30.
［18］Luo J Y，Zhang S，Zhu X Z，et al. Effects of soil salinity on rhizosphere soil microbes in transgenic Bt cotton fields［J］. Journal of Integrative Agriculture，2017，16(7)：1624-1633.
［19］Jenkins M. Impact of glyphosate resistant corn and glyphosate applications under conventional and reduced tillage practices on exoenzyme activities and microbial community structure of bulk and rhizosphere soils［J］. Cancer Letters，2015，109(1)：91-99.
［20］de Oliveira C A，Calazans G M，Figueiredo J E F，et al. Microbial activities in soils cultivated with transgenic maize expressing Bacillus thuringiensis Cry1Ab and Cry1F genes［J］. Revista Brasileira de Milho e Sorgo，2015，14(3)：409-419.
［21］Zeng X，Zhou Y，Zhu Z J，et al. Effect on soil properties of BcWRKY1 transgenic maize with enhanced salinity tolerance［J］. International Journal of Genomics，2016(5)：1-13.
［22］van Wyk D A B，Adeleke R，Rhode O H J，et al. Ecological guild and enzyme activities of rhizosphere soil microbial communities associated with Bt-maize cultivation under field conditions in north west province of South Africa［J］. Journal of Basic Microbiology，2017，57(9)：781-792.
［23］Lee Z，Bu N，Cui J et al. Effects of long-term cultivation of transgenic Bt rice (Kefeng-6) on soil microbial functioning and C cycling［J］. Scientific Reports，2017，7(1)：4647.
［24］Fang H，Dong B，Hu Y，et al. Effect of vegetation of transgenic Bt rice lines and their straw amendment on soil enzymes，respiration，functional diversity and community structure of soil microorganisms under field conditions［J］. Journal of Environmental Sciences，2012，24(7)：1259-1269.
［25］Wei M，Tan F，Zhu H，et al. Impact of Bt-transgenic rice (SHK601) on soil ecosystems in the rhizosphere during crop development［J］. Plant，Soil and Environment，2012，58(5)：217-223.
［26］Li P，Dong J Y，Yang S F，et al. Impact of β-carotene transgenic rice with four synthetic genes on rhizosphere enzyme activities and bacterial communities at different growth stages［J］. European Journal of Soil Biology，2014，65：40-46.[HT]
［27］Nakatani A S，Fernandes M F，Souza R A D，et al. Effects of the glyphosate-resistance gene and of herbicides applied to the soybean crop on soil microbial biomass and enzymes［J］. Field Crops Research，2014，162：20-29.
［28］Bezirganoglu I，Uysal P. Impact of transgenic AFPCHI (Cucumis melo L. Silver Light) fungal resistance melon on soil microbial communities and enzyme activities［J］. Journal of Plant Biotechnology，2017，44：156-163.
［29］Wang B，Shen H，Yang X，et al. Effects of chitinase-transgenic (McChit1) tobacco on the rhizospheric microflora and enzyme activities of the purple soil［J］. Plant，Soil and Environment，2013，59(6)：241-246.
［30］Zhou D G，Xu L P，Gao S W，et al. Cry1Ac transgenic sugarcane does not affect the diversity of microbial communities and has no significant effect on enzyme activities in rhizosphere soil within one crop season［J］. Frontiers in Plant Science，2016，7：265.
［31］Wu J R，Yu M Z，Xu J H，et al. Impact of transgenic wheat with wheat yellow mosaic virus resistance on microbial community diversity and enzyme activity in rhizosphere soil［J］. PLoS One，2014，9(6)：e98394.
［32］Khan M S，Sadat S U，Jan A，et al. Impact of transgenic Brassica napus harboring the antifungal synthetic chitinase (NiC) gene on rhizosphere microbial diversity and enzyme activities［J］. Frontiers in Plant Science，2017，8：1307.
［33］王理德，王方琳，郭春秀，等. 土壤酶学研究进展［J］. 土壤，2016，48(1)：12-21.
［34］邵文山，李国旗. 土壤酶功能及测定方法研究进展［J］. 北方园艺，2016(9)：188-193.
［35］张丽莉，武志杰，陈利军，等. 转基因棉种植对土壤氧化还原酶活性的影响［J］. 土壤通报，2007，38(2)：277-280.
［36］Icoz I，Stotzky G. Fate and effects of insect-resistant Bt crops in soil ecosystems［J］. Soil Biology & Biochemistry，2008，40(3)：559-586.
［37］董斌. Bt水稻种植及秸秆还田对土壤酶、呼吸活性及土壤微生物功能和结构多样性的影响［D］. 杭州：浙江大学，2011.
［38］Caldwell B A. Enzyme activities as a component of soil biodiversity：a review［J］. Pedobiologia，2005，49(6)：637-644.
［39］Lahl K，Unger C，Emmerling C，et al. Response of soil microorganisms and enzyme activities on the decomposition of transgenic cyanophycin-producing potatoes during overwintering in soil［J］. European Journal of Soil Biology，2012，53(6)：1-10.
［40］Hussain S，Siddique T，Saleem M，et al. Impact of pesticides on soil microbial diversity，enzymes，and biochemical reactions［J］. Advances in Agronomy，2009，102(1)：159-200.
［41］俞明正，戴濡伊，吴季荣，等. 转TaDREB4基因抗旱小麦对其根际土壤速效养分、酶活性及微生物群落多样性的影响［J］. 江苏农业学报，2013，29(5)：938-945.
［42］马丽颖，崔金杰，陈海燕. 种植转基因棉对4种土壤酶活性的影响［J］. 棉花学报，2009，21(5)：383-387.
［43］陈愫惋. 转基因棉花的Bt毒素在土壤中的分布及对土壤酶活性的影响［D］. 武汉：华中农业大学，2008.
［44］乔琦，丁伟，李新海，等. 转基因抗旱大豆对土壤酶活性的影响［J］. 东北农业大学学报，2010，41(12)：11-14.

相似文献/References:

[1]刘雪艳,王从彦,王磊,等.入侵植物对土壤酶活性及土壤微生物群落影响的研究进展[J].江苏农业科学,2013,41(04):304.
[2]任旭琴,彭莉,章宇萍,等.邻苯二甲酸二丁酯对辣椒根系生理特性和土壤酶活性的影响[J].江苏农业科学,2015,43(12):191.
　Ren Xuqin,et al.Effects of dibutyl phthalate (DBP) on root physiological characteristics and soil enzyme activity of pepper[J].Jiangsu Agricultural Sciences,2015,43(14):191.
[3]刘会玲,沙晓晴,彭正萍.不同形态氮源对玉米幼苗生长及根际环境的影响[J].江苏农业科学,2016,44(06):135.
　Liu Huiling,et al.Effects of different forms of nitrogen source on seedling growth and rhizosphere environment of maize[J].Jiangsu Agricultural Sciences,2016,44(14):135.
[4]王华,胡锦珍,胡冬南,等.不同肥料对油茶林土壤微生物及酶活性的影响[J].江苏农业科学,2016,44(06):461.
　Wang Hua,et al.Effects of different fertilization treatments on soil microorganisms and enzyme activities in Camellia oleifera forest[J].Jiangsu Agricultural Sciences,2016,44(14):461.
[5]张月义,陈太义,宋明顺,等.转基因作物产业化动力机制——基于动态博弈的策略分析[J].江苏农业科学,2016,44(02):446.
　Zhang Yueyi,et al.Study on dynamic mechanism of GM crops industrialization—Based on strategic analysis of sequential game[J].Jiangsu Agricultural Sciences,2016,44(14):446.
[6]刘静,徐峥静茹,彭培好,等.旅游踩踏对鸡冠山森林公园土壤微生物数量及酶活性的影响[J].江苏农业科学,2016,44(02):398.
　Liu Jing,et al.Effects of tourism trampling on soil microbial quantity and soil enzyme activity in Jiguan Mountain Forest Park[J].Jiangsu Agricultural Sciences,2016,44(14):398.
[7]汤波,赵佐平,宋凤敏,等.汉江上游铅锌尾矿区土壤环境效应[J].江苏农业科学,2016,44(08):470.
　Tang Bo,et al.Soil environment effect of lead and zinc mining region in upstream of Hanjiang River[J].Jiangsu Agricultural Sciences,2016,44(14):470.
[8]任旭琴,陈伯清,彭莉,等.凹土和有益微生物菌液对淮安红椒连作土壤养分和酶活性的影响[J].江苏农业科学,2016,44(10):491.
　Ren Xuqin,et al.Effects of concave soil and beneficial microbial liquid on nutrients and enzyme activities in continuous cropping soil of Huaian red pepper[J].Jiangsu Agricultural Sciences,2016,44(14):491.
[9]乔继杰,马振朝,王玮,等.河北低平原夏玉米高产田土壤酶与肥力特征[J].江苏农业科学,2016,44(12):484.
　Qiao Jijie,et al.Analysis of soil enzymes and fertility characteristics of summer corn high yield field in Hebei low plain[J].Jiangsu Agricultural Sciences,2016,44(14):484.
[10]李春龙,韩春梅,叶少平,等.外源化感物质阿魏酸对紫云英幼苗生长、根际土壤酶活性、微生物数量及土壤养分的影响[J].江苏农业科学,2017,45(04):134.
　Li Chunlong,et al.Influences of ferulic acid on Astragalus sinicus seedling growth， rhizosphere soil enzyme activity，microbial population and soil nutrient[J].Jiangsu Agricultural Sciences,2017,45(14):134.

《江苏农业科学》[ISSN:1002-1302/CN:32-1214/S]

文章信息/Info

参考文献/References:

相似文献/References:

备注/Memo

常用功能

导航/Navigate

工具/Tools

统计/Statistics