抗旱转基因小麦(Triticum aestivum L.) 的杂草性评价

doi:10.3864/j.issn.0578-1752.2015.11.002

摘要/Abstract

摘要： 【目的】全球转基因作物商业化迅猛发展，包括杂草化在内的一系列生态风险评估和研究尤为重要。文章中系统评价抗旱转基因小麦MGX-L大面积推广种植可能带来的演化为杂草的生态风险，为转基因抗旱小麦的环境安全评价标准制定提供科学依据。【方法】通过比较荒地和栽培地上抗旱转基因小麦、受体小麦和当地常规品种的农艺性状，评价转基因小麦的生存竞争能力；并比较荒地上生存的转基因小麦与受体的繁殖系数，评价转基因小麦群体在野外的生存能力。比较转基因小麦和受体品种的自生苗比率、种子落粒性、及深埋和浅埋地下种子萌发情况，评价转基因小麦的自然延续能力。比较转基因小麦和受体品种的花粉活力、花粉大小和花粉育性，评价转基因小麦的自然繁育能力。综合分析以上各项评价结果，评价抗旱转基因小麦演变为杂草的可能性。【结果】转基因小麦在栽培地上种植，其株高、总穗数和穗粒数与受体品种相比，没有显著差异，而转基因小麦的产量、千粒重显著高于受体品种。但和其他非转基因当地主栽小麦品种相比，或没有显著差异，或低于其他非转基因小麦品种，因此，转基因小麦与其非转基因小麦对照相似,在栽培地种植没有更强的生存竞争能力。在荒地环境下，转基因小麦生存竞争能力和受体品种没有显著差异。在荒地上种植且成熟的转基因小麦，单位面积内收获的总籽粒数少于上一年种下的种子粒数，其繁殖系数低于1。转基因小麦群体不可能在野外环境中自然维持下去。转基因小麦种子的落粒性和产生自生苗比率与受体品种相比没有显著差异。深埋20 cm以下土层的转基因小麦和受体品种的种子全部腐烂；浅埋3 cm土层的转基因小麦和受体品种的种子或者腐烂或者出苗，没有发现未萌发且保存完好能够保持活力继续发芽的种子,二者的种子腐烂或出苗的比率没有显著差异，说明转基因小麦和受体品种种子的延续能力低且无显著差异。【结论】转基因抗旱小麦MGX-L与其受体对照品种济麦22及其他非转基因当地主栽品种相似，耐旱性状的引入不会增加小麦的杂草化潜势。

关键词: 抗旱转基因小麦, 杂草性, 安全性评价

Abstract: 【Objective】 Genetically modified (GM) plants have been widely used in both agriculture and food industry. A scientifically sound environmental risk assessment, including weediness risk, is required for crops derived from genetically modified prior to unrestricted release into the environment. The objective of this study was to assess the potential ecological risk for weediness of transgenic drought-tolerant wheat MGX-L, and to provide scientific data for the formulation of evaluation standard of environmental safety assessment of transgenic wheat in China. 【Method】 In the cultivated lands and abandoned lands, the surviving competition ability of transgenic drought-tolerant wheat MGX-L, recipient variety and conventional wheat varieties were comparatively evaluated by investigating their agricultural traits. The propagation coefficient of wheat planted in abandoned lands was compared and the survival ability in abandoned lands was evaluated. Volunteer possibility, seed shattering and persisting possibility of transgenic drought-tolerant wheat MGX-L were analyzed and compared with the wild type for evaluating the ability of life continuous. The reproducing ability was evaluated by comparing the pollen viability, pollen diameter and sterility of MGX-L with the wild type. The weediness potential of MGX-L was evaluated based on the above results.【Result】There were no significant differences between transgenic wheat MGX-L and the wild type in plant height, spike number per hectare and per spike grain. The 1000-grain weight and yield of the transgenic wheat MGX-L were higher than that of the recipient variety Jimai 22. However, the 1000-grain weight and yield of the transgenic wheat MGX-L were lower than that of conventional wheat varieties or no significant difference. There were no significant differences between transgenic wheat MGX-L and the wild type in survival ability in the cultivated lands. Some wheat seeds could geminate and obtain seeds of next generation in abandoned lands. However, its propagation coefficient was less than 1 and the population size of transgenic wheat declined after the first year as a result of increased competition from native perennial plants. The transgenic wheat population couldn’t persist in abandoned lands like its conventional counterpart. There were no significant differences in seed shattering ability and volunteer plants rate between the transgenic wheat and the wild type. When buried under soil 20 cm, the seeds of transgenic wheat and the wild type were all rotted. When buried under soil 3 cm, the seeds of transgenic wheat and the wild type were rotted or sprouted. There were no intact seeds buried under soil. So there was no significant difference between the transgenic wheat and the wild type in seed persisting ability. 【Conclusion】 It was concluded that the transgenic drought-tolerant wheat MGX-L had the lowest potential weediness like the non-transgenic wheat varieties, based on the assessment of survival ability, seed shattering ability, volunteer plants rate and seed persisting ability.

Key words: transgenic drought-tolerant wheat, weediness, safety assessment

姜奇彦，李新海，胡正，马有志，张辉，徐兆师. 抗旱转基因小麦(Triticum aestivum L.) 的杂草性评价[J]. 中国农业科学, 2015, 48(11): 2096-2107.

JIANG Qi-yan, LI Xin-hai, HU Zheng, MA You-zhi, ZHANG Hui, XU Zhao-shi . Safety Assessment of Weediness of Transgenic Drought-Tolerant Wheat (Triticum aestivum L.)[J]. Scientia Agricultura Sinica, 2015, 48(11): 2096-2107.

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参考文献

[1] James C. Global Status of Commercialized Biotech/GM Crops: 2014. ISAAA Briefs no. 47. ISAAA, Ithaca, New York.

[2] James K. Could transgenic super crops one day breed super weeds. Science, 1996, 274(5285): 180-181.

[3] 陆群峰, 肖显静. 转基因作物环境风险争论综述. 山东科技大学学报: 社会科学版, 2009, 11(5): 8-15.

Lu Q F, Xiao X J. A summary oil the debates of environmental risks of genetically modified crops. Journal of Shandong University of Sciences & Technology: Social Science, 2009, 11(5): 8-15. (in Chinese)

[4] Ellstrand N C, Heredia S M, Leak-Garcia J A, Heraty J M, Burger J C, Yao L, Nohzadeh-Malakshah S, Ridley C E. Crops gone wild: Evolution of weeds and invasives from domesticated ancestors.Evolutionary Applications, 2010, 3(5/6): 494-504.

[5] Wozniak C A, Martinez J C. U.S. EPA regulation of plant-incorporated protectants: Assessment of impacts of gene flow from pest-resistant plants. Journal of Agricultral Food Chemistry, 2011, 59(11): 5859-5864.

[6] 贾士荣. 转基因植物的环境及食品安全性. 生物工程进展, 1997, l17(6): 36-42.

Jia S R. Environment and food biosafety assessment of transgenic plants. Progress in Technology, 1997, 117(6): 36-42. (in Chinese)

[7] Yang X, Xia H, Wang W, Wang F, Su J, Snow A A, Lu B R. Transgenes for insect resistance reduce herbivory and enhance fecundity in advanced generations of crop-weed hybrids of rice. Evolutionary Applications , 2011, 4(5): 672-684.

[8] 宋小玲, 强胜, 彭于发. 抗草甘膦转基因大豆（Glycine mac (L.) Merri）杂草性评价的试验实例. 中国农业科学, 2009, 42(1): 145-153.

Song X L, Qiang S, Peng Y F. An experimental case of safety assessment of weediness of transgenic glyphosate-resistant soybean (Glycine mac (L.) Merri). Scientia Agricultura Sinica, 2009, 42(1): 145-153. (in Chinese)

[9] Conner A J, Glare T R, Nap J P. The release of genetically modified crops into the environment: Part II. Overview of ecological risk assessment. The Plant Journal, 2003, 33: 19-46.

[10] Hall L, Topinka K, Huffman J, Davis L, Good A. Pollen flow between herbicide-resistant Brassica napus is the cause of multiple-resistant B. napus volunteers. Weed Science, 2000, 48: 688-694.

[11] Beckie H J, Hall L M, Warwick S I. Impact of herbicide-resistant crops as weeds in Canada. Proceedings Brighton Crop Protection Conference - Weeds, 2001, 1: 135-142.

[12] Orson J. Gene stacking in herbicide tolerant oilseed rape: Lessons from the North American experience. English Nature Research Reports, 2002, 443: 1-17.

[13] Crawley M J, Brown S L, Hails R S, Kohn D D, Rees M. Transgenic crops in natural habitats. Nature, 2001, 409(6821): 682-683.

[14] 郑庆伟. 中国农业科学院培育出抗旱节水转基因小麦新品种. 农药市场信息, 2014, 19: 41.

Zheng Q W. Chinese Academy of Agricultural Science made new progress in drought-tolerant transgenic wheat research. Pesticide Market News, 2014, 19: 41. (in Chinese)

[15] 李博, 陈家宽, 沃金森AR. 植物竞争研究进展. 植物学通报, 1998, 15(4): 18-29.

Li B, Chen J K, Watkinson AR. A literature review on plant competition. Chinese Bulletin of Botany, 1998, 15(4): 18-29. (in Chinese)

[16] 彭少麟, 向言词. 植物外来种入侵及其对生态系统的影响. 生态学报, 1999, 19(1): 561-569.

Peng S L, Xiang Y C. The invasion of exotic plants and effects of ecosystems. Acta Ecologica Sinica, 1999, 19(1): 561-569. (in Chinese)

[17] 周骏, 王长永, 陈建群. 转基因植物入侵性评价指标初探. 农村生态环境, 2003, 19(2): 61-64.

Zhou J, Wang C Y, Chen J Q. Indexes for assessment of genetically modified plants invasiveness. Rural Eco-Environment, 2003, 19(2): 61-64. (in Chinese)

[18] Yang Y,He J,Dong B,Xu H,Fu Q,Zheng X, Lin Y, Lu Z. Effects of twoBtrice lines T2A-1 and T1C-19 on the ecological fitness and detoxification enzymes of Nilaparvata lugens(Hemiptera: Delphacidae) from different populations.Journal of Economic Entomology, 2013, 106: 1887-1893.

[19] Jiang Q Y, Hou J, Hao C Y, Wang L F, Ge H M, Dong Y S, Zhang X Y. The wheat (T. aestivum) sucrose synthase 2 gene (TaSus2) active in endosperm development is associated with yield traits. Funct Integr Genomics, 2011, 11: 49-61.

[20] 强胜. 杂草学. 北京: 中国农业出版社, 2000: 8-14.

Qiang S. Weed Science. Beijing: China Agriculture Press, 2000: 8-14. (in Chinese)

[21] Cai H W, Morishima H. Genomic regions affecting seed shattering and seed dormancy in rice. Theoretical and Applied Genetics, 2000, 100(6): 840-846.

[22] Baker H G. The evolution of weeds. Annual Review of Ecology and Systematics, 1974, 5: 1-24.

[23] Andrsson L, Milberg P, Schutz W, Steinmetz O. Germination characteristics and emergence time of annual Bromus species of differing weediness in Sweden. Weed Research, 2002, 42: 135-147.

[24] 刘谦, 朱鑫泉. 生物安全. 北京: 科学出版社, 2002: 67-73.

Liu Q, Zhu X Q. Biosafety. Beijing: Science Press, 2002: 67-73. (in Chinese)

[25] Lu Z B, Liu Y E, Han N S, Tian J C, Peng Y F, Hu C, Guo Y Y, Ye G Y. Transgenic cry1C or cry2A rice has no adverse impacts on the life-table parameters and population dynamics of the brown planthopper, Nilaparvata lugens (Hemiptera: Delphacidae). Pest Management Science, 2014, doi: 10.1002/ps.3866.