光谱学与光谱分析 |
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Effects of Mepiquat Chloride on Inorganic Elements Contents in Seeds of Transgenic Insect-Resistant Cotton Determined by ICP-MS |
FAN Xi-feng, TIAN Xiao-li, LI Zhao-hu, HE Zhong-pei, ZHAI Zhi-xi, DUAN Liu-sheng* |
Key Laboratory of Crop Cultivation and Farming System of the Ministry of Agriculture, College of Agronomy and Biotechnology, China Agricultural University, Beijing 100094, China |
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Abstract To evaluate the effects of a worldwide used plant growth regulator mepiquat chloride on the nutrition value and safety of seeds of transgenic Bt cotton, inorganic element components and contents in seeds of Bt cotton (Gossypium hirsutum cv. Guoxin 6) under field condition were determined using ICP-MS. In Bt cotton seeds, 54 kinds of inorganic elements were identified by ICP-MS, and 5 kinds of major elements, K, P, Mg, Ca and Na, were in range from 138.3 to 13 835.1 μg·g-1. The contents of 14 kinds of microelements were determined as in descending order of Si, B, Mn, Sr, Zn, Ni, Cu, Mo, Fe, Co, Se, V, I and Sn, in the range from 14.2 ng·g-1 to 81.7 μg·g-1. Five kinds of heavy metals were detected with the contents from 0.14 to 55.3 ng·g-1,and their order from high to low is Pb, Cd, Cr, As and Hg. Other 30 kinds of elements were also detected in Bt cotton seeds by ICP-MS, including Rb, Be, La, Ce, Pr, Nd, Sm, Gd, Ge, Rh, Ag, Sb, W, U and Y. Foliar application of mepiquat chloride significantly reduced the contents of Ca, Fe, Si, Mn, Co, Ni, Cu and I, and remarkably decreased heavy metals Pb, Cd and Cr in the cotton seeds, by 68%, 67% and 54% respectively. While mepiquat chloride did not change the contents of most major and micro elements, it heightened 8 kinds, but lowered 7 kinds of the other 30 trace elements. This research indicated that mepiquat chloride application strengthened the security regarding the cotton seed as the material of cooking oil.
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Received: 2008-02-08
Accepted: 2008-05-12
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Corresponding Authors:
DUAN Liu-sheng
E-mail: duanlsh@cau.edu.cn
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[1] LI Zhi-qiang, TANG Jin-quan, GU Dong(李志强,唐金泉,顾 东). Chinese Journal of Animal Science(中国畜牧杂志), 2005, 41(2): 47. [2] TANG Mao-zhi, HUANG Kun-lun, ZHOU Ke, et al(唐茂芝,黄昆仑,周 可,等). Food Science(食品科学), 2006, 27(6): 216. [3] SUN Ji-zhong, CHEN Bu-sheng(孙济中,陈布圣). Cotton Culture(棉作学), 1998. 439. [4] CAO Zhi(曹 智). Agricultural Outlook(农业展望), 2007, 3(2): 22. [5] DING Xu-guang, HOU Dong-yan, HUI Rui-hua, et al(丁旭光,侯冬岩,回瑞华,等). Chinese Journal of Analysis Laboratory(分析实验室), 2005, 24(11): 57. [6] HAN Ju, WANG Chun-fang, XU Rong-qi(韩 菊,王春芳,徐荣旗). Hebei Journal of Industrial(河北工业科技), 2000, 17(2): 27. [7] HAN Ju, WEI Fu-xiang, PANG Jin-xia, et al(韩 菊,魏福祥,庞津霞,等). China Oils and Fats(中国油脂), 2003, 28(10): 58. [8] MIN Xiang-jia, LIU Qi, HE Zhong-pei, et al(闵祥佳,刘 启,何钟佩,等). Acta Agriculturae Universitatis Pekingensis(北京农业大学学报), 1991, 17(supplement): 27. [9] HE Zhong-pei, MIN Xiang-jia, LI Pi-ming, et al(何钟佩,闵祥佳,李丕明,等). Acta Agronomica Sinica(作物学报), 1990, 16(3): 252. [10] RUI Yu-kui, HAO Yan-ling, ZHANG Fu-suo, et al(芮玉奎,郝彦玲,张福锁,等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2007,27(10): 2111. [11] YAN Ping-mei, WANG Wen-ya, RUI Yu-kui, et al(燕平梅,王文雅,芮玉奎,等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2007, 27(8): 1629. [12] RUI Yu-kui, GUO Jing, HUANG Kun-lun, et al(芮玉奎,郭 晶,黄昆仑,等). Spectroscopy and Spectral Analysis(光谱学与光谱分析), 2007, 27(4): 796. [13] ZHANG Jin-sheng, ZHAO Shuang, LI Li-hua, et al(张金生,赵 爽,李丽华,等). Modern Instruments(现代仪器), 2005, 11(5): 26. [14] LI Li-hua, ZHANG Li-jing, ZHANG Jin-sheng, et al(李丽华,张丽静,张金生,等). Soybean Science(大豆科学), 2007, 26(2): 240. [15] DONG Hong-xia, ZHAO Xiao-song, SUN An-na, et al(董洪霞,赵晓松,孙安娜,等). Journal of Jilin Agricultural University(吉林农业大学学报), 2005, 27(1): 79. [16] Costa Moreira-josino. The Science of the Total Environment, 1996, 188: 61. |
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