[1] Ishiwata S. On a kind of severe flacherie (sotto disease)[J]. Dainihon Sanshi Kaiho, 1901, 114(1):5. [2] Berliner E. Über die Schlaffsucht der Mehlmottenraupe (Ephestia kühniella Zell.) und ihren erreger Bacillus thuringiensis n. sp[J]. Zeitschrift für Angewandte Entomologie, 1915, 2(1):29-56. [3] Soberon M, Gill S S, Bravo A. Signaling versus punching hole:how do Bacillus thuringiensis toxins kill insect midgut cells?[J].Cellular and Molecular Life Sciences, 2009, 66:1337-1349. [4] Bravo A, Likitvivatanavong S, Gill S, et al. Bacillus thuringiensis:A story of a successful bioinsecticide[J]. Insect Biochemistry and Molecular Biology, 2011, 41:423-431. [5] James C. Global Status of Commercialized Biotech/GM Crops:2018. ISAAA Brief No.54[M]. Ithaca, NY:ISAAA, 2019 [6] Arthurs S, Dara S K. Microbial biopesticides for invertebrate pests and their markets in the United States[J]. Journal of Invertebrate Pathology, 2019, 165:13-21. [7] 张文君. 美国生物农药登记管理情况[J]. 农药科学与管理, 2002, 23(2):43-44. [8] 施天柱, 张碧海, 林艳, 等. 苏云金杆菌杀虫剂的特点及应用[J]. 新疆农垦科技, 2006(4):50-51. [9] 刘志勇, 李启富, 周银平, 等. 苏云金杆菌的急性毒性及致敏实验观察[J]. 上海实验动物科学, 2004(3):35-37. [10] 黄光全, 陈国英, 李松增, 等. 苏云金杆菌以色列变种"187"株对哺乳动物急性安全试验[J]. 公共卫生与预防医学, 2000(2):35-36. [11] 陈国英, 黄光全, 李松增, 等. 苏云金杆菌以色列变种187株对哺乳动物亚急性毒性试验[J]. 公共卫生与预防医学, 1999(6):59-60. [12] 黄光全, 徐博钊, 李松增, 等. 苏云金杆菌以色列变种187株对鱼类及水生动物毒性试验[J]. 湖北预防医学杂志, 2000(1):39-40. [13] 陈波, 谷明娟, 朱遥, 等. 苏云金芽胞杆菌BtZ01对小鼠胚胎和胚后发育的影响[J]. 生态毒理学报, 2015, 10(2):325-331. [14] Xu W, Cao S, He X, et al. Safety assessment of Cry1Ab/Ac fusion protein[J]. Food and Chemical Toxicology, 2009, 47(7):1459-1465. [15] Wang G, Zhang J, Song F, et al. Engineered Bacillus thuringiensis G033A with broad insecticidal activity against Lepidopteran and Coleopteran pests[J]. Applied Microbiology and Biotechnology, 2006, 72:924-930. [16] 张杰. 转cry3Aa基因苏云金芽胞杆菌G033A的安全证书申报书. 2019. [17] Mancebo A, Molier T, González B, et al. Acute oral, pulmonary and intravenous toxicity/pathogenicity testing of a new formulation of Bacillus thuringiensis var israelensis SH-14 in rats[J]. Regulatory Toxicology and Pharmacology, 2011, 59(1):184-190. [18] Wang C, Li W, Kessenich C R, et al. Safety of the Bacillus thuringiensis-derived Cry1A. 105 protein:Evidence that domain exchange preserves mode of action and safety[J]. Regulatory Toxicology and Pharmacology, 2018, 99:50-60. [19] EFSA Biohazard Panel. Risks for public health related to the presence of Bacillus cereus and other Bacillus spp. including Bacillus thuringiensis in foodstuffs[J]. EFSA Journal, 2016, 14:99. [20] Raymond B, Federici B A. In defense of Bacillus thuringiensis, the safest and most successful microbial insecticide available to humanity-a response to EFSA[J]. FEMS Microbiology Ecology, 2017, 93:7. [21] Siegel J P. The Mammalian safety of Bacillus thuringiensis-based insecticides[J]. Journal of Invertebrate Pathology, 2001, 77(1):13-21. [22] West A W, Burges H D, Dixon T J, et al. Survival of Bacillus thuringiensis and Bacillus cereus spore inoculation in soil:effects of pH, moisture, nutrient availability and indigenous microorganisms[J]. Soil Biology and Biochemistry, 1985, 17(5):657-665. [23] Petras S F, Casida L E. Survival of Bacillus thuringiensis spores in soil[J]. Applied and Environmental Microbiology, 1986, 50(6):1496-1501. [24] Pruett C J H, Burges H D, Wyborn C H. Effect of exposure to soil on potency and spore viability of Bacillus thuringiensis[J]. Journal of Invertebrate Pathology, 1980, 35(2):168-174. [25] 黄威, 张运红, 陈迪勤, 等. Bt蛋白在几种土壤中的降解与残留[J]. 华中农业大学学报, 2009, 28(2):51-55. [26] 黄冠辉, 邵冬梅, 王卫国, 等. 苏云金杆菌芽胞在作物叶面和土壤中的存活期研究[J]. 微生物学通报, 1981(1):7-9. [27] Wang X, Xue Y, Han M, et al. The ecological roles of Bacillus thuringiensis within phyllosphere environments[J]. Chemosphere, 2014, 108:258-264. [28] Schoenly K G, Cohen M B, Barrion A T, et al. Effects of Bacillus thuringiensis on non-target herbivore and natural enemy assemblages in tropical irrigated rice[J]. Environmental Biosafety Research, 2003, 2(3):181-206. [29] Stefan R, Eva S, Heinz H, et al. Diabrotica-resistant Bt maize DKc5143 event MON88017 has no impact on the field densities of the leafhopper Zyginidia scutellaris[J]. Environmental Biosafety Research, 2010, 9:87-99. [30] Dutton A, Klein H, Romeis J, et al. Prey-mediated effects of Bacillus thuringiensis spray on the predator Chrysoperla carnea in maize[J]. Biological Control, 2003, 26(2):209-215. [31] Romeis J, Dutton A, Bigler F. Bacillus thuringiensis toxin (Cry1Ab) has no direct effect on larvae of the green lacewing Chrysoperla carnea (Stephens) (Neuroptera:Chrysopidae)[J]. Journal of Insect Physiology, 2004, 50(2-3):175-183. [32] 王广君. 高效广谱苏云金芽孢杆菌工程菌的构建及杀虫晶体蛋白的研究[D]. 北京:中国农业科学院, 2005. [33] Lu H, Rajamohan F, Dean D H. Identification of amino acid residues of Bacillus thuringiensis delta-endotoxin CryIAa associated with membrane binding and toxicity to Bombyx mori[J]. Journal of Bacteriology, 1994, 176(17):5554-5559. [34] Liu Y, Zhou Z, Wang Z, et al. Replacement of loop2 and 3 of Cry1Ai in domain II affects specificity to the economically important insect Bombyx mori[J]. Journal of invertebrate pathology, 2020, 169:107296. [35] Jiao Y, Yang Y, Meissle M, et al. Comparison of susceptibility of Chilo suppressalis and Bombyx mori to five Bacillus thuringiensis proteins[J]. Journal of Invertebrate Pathology, 2016, 136:95-99. [36] 赵旭, 叶幸, 张燕, 等. 3种典型微生物农药对家蚕的毒性研究[J]. 生态毒理学报, 2017, 12(4):219-226. [37] 袁志东, 姚洪渭, 叶恭银, 等. 转Bt基因水稻花粉对家蚕不同品种幼虫的生存分析[J]. 蚕桑通报, 2006, 3:23-27. [38] Babendreier D, Kalberer N M, Fluri P, et al. Influence of Bt-transgenic pollen, Bt-toxin and protease inhibitor (SBTI) ingestion on development of the hypopharyngeal glands in honeybees[J]. Apidologie, 2005, 36:585-594. [39] Sims S R. Bacillus thuringiensis var. kurstaki CryIA (c) protein expressed in transgenic cotton:effects on beneficial and other non-target insects[J]. Southwestern Entomology, 1995, 20:493-500. [40] Malone L A, Burgess E P J, Gatehouse H S, et al. Effects of ingestion of a Bacillus thuringiensis toxin and a trypsin inhibitor on honey bee flight activity and longevity[J]. Apidologie, 2001, 32(1):57-68. [41] 田岩, 张永军, 吴孔明, 等. 转Bt-cry1Ab玉米花粉对意大利蜜蜂生长发育及体内酶活性的影响[J]. 农业生物技术学报, 2006, 14(6):990-991. [42] Babendreier D, Joller D, Romeis J, et al. Bacterial community structures in honeybee intestines and their response to two insecticidal proteins[J]. FEMS Microbiology Ecology, 2007, 59:600-610. [43] Dai P, Wang M, Geng L, et al. The effect of Bt Cry9Ee toxin on honey bee brood and adults reared in vitro, Apis mellifera (Hymenoptera:Apidae)[J]. Ecotoxicology and Environmental Safety, 2019, 181:381-387. [44] Jiang W, Geng L, Dai P, et al. The Influence of Bt-transgenic maize pollen on the bacterial diversity in the midgut of Chinese honeybees, Apis cerana cerana[J]. Journal of Integrative Agriculture, 2013, 12(3):474-482. [45] Geng L, Cui H, Dai P, et al. The influence of Bt-transgenic maize pollen on the bacterial diversity in the midgut of Apis mellifera ligustica[J]. Apidologie, 2013, 44:198-208. [46] Dhillon M K, Sharma H C. Effects of Bacillus thuringiensis δ-endotoxins Cry1Ab and Cry1Ac on the coccinellid beetle, Cheilomenes sexmaculatus (Coleoptera, Coccinellidae) under direct and indirect exposure conditions[J]. Biocontrol Science and Technology, 2009, 19(4):407-420. [47] Duan J J, Head G, McKee M J, et al. Evaluation of dietary effects of transgenic corn pollen expressing Cry3Bb1 protein on a non-target ladybird beetle, Coleomegilla maculate[J]. Entomologia Experimentalis et Applicata, 2002, 104:271-280. [48] Koskella J, Stotzky G. Larvicidal toxins from Bacillus thuringiensis subspp. kurstaki, morrisoni, (strain tenebrionis), and israelensis, have no microbicidal or microbiostatic activity against selected bacteria, fungi, and algae in vitro[J]. Canadian Journal of Microbiology, 2002, 48(3):262-267. [49] 韩美哲, 王小显, 刘常宏, 等. 苏云金芽胞杆菌菌剂对棉花根际土壤细菌数量及多样性的影响[J]. 中国生态农业学报, 2013, 21(10):109-115. [50] 冯书亮, 范秀华, 王容燕, 等. 苏云金杆菌在华北果园土壤中消长动态的研究[J]. 中国病毒学, 2000(S1):110-114. [51] Li Z, Bu N, Chen C, et al. Soil incubation studies with Cry1Ac protein indicate no adverse effect of Bt crops on soil microbial communities[J]. Ecotoxicology and Environmental Safety, 2018, 152:33-41. [52] Tan F, Wang J, Feng Y, et al. Bt corn plants and their straw have no apparent impact on soil microbial communities[J]. Plant & Soil, 2010, 329(s1-2):349-364. [53] 任馨, 吴伟祥, 叶庆富, 等. 转Bt基因克螟稻秸杆对淹水土壤细菌群落的影响[J]. 环境科学学报, 2004, 24(5):871-877. [54] Vivas A, Marulanda A, Gómez M, et al. Physiological characteristics (SDH and ALP activities) of arbuscular mycorrhizal colonization as affected by Bacillus thuringiensis inoculation under two phosphorus levels[J]. Soil Biology and Biochemistry, 2003, 35(7):987-996. [55] Armada E, Azcón R, López-Castillo O M, et al. Autochthonous arbuscular mycorrhizal fungi and Bacillus thuringiensis from a degraded Mediterranean area can be used to improve physiological traits and performance of a plant of agronomic interest under drought conditions[J]. Plant Physiology Biochemstry, 2015, 90:64-74. [56] 熊鹂, 刘培磊, 徐琳杰, 等. 浅析转基因舆情[J]. 生物安全学报, 2014, 23(4):305-308. [57] Melo A L A, Soccol V T, Soccol C R. Bacillus thuringiensis:mechanism of action, resistance, and new applications:a review[J]. Critical Reviews in Biotechnology, 2016, 36(2):317-326. [58] Tabashnik B E, Cushing N L, Finson N, et al. Field development of resistance to Bacillus thuringiensis in diamondback moth (Lepidoptera:Plutellidae)[J]. Journal of Economic Entomology, 1990, 83(5):1671-1676. [59] 戴承镛, 殷向东, 徐熙, 等. 小菜蛾对苏云金杆菌制剂的抗药性及其对策[J]. 中国生物防治学报, 1994, 10(2):62-66. [60] Tabashnik B E, Gassman A J, Crowdwer D W, et al. Insect resistance to Bt crops:evidence versus theory[J]. Nature Biotechnology, 2008, 26:199-202. [61] 袁善奎, 刘亮, 王以燕, 等. 农药非法添加隐性成分及其风险分析[J]. 农药, 2016, 7:480-482. |