Degradation and detection of transgenic Bacillus thuringiensis DNA and proteins in flour of three genetically modified rice events submitted to a set of thermal processes

文献类型: 外文期刊

第一作者: Wang, Xiaofu

作者: Wang, Xiaofu;Chen, Xiaoyun;Xu, Junfeng;Wang, Xiaofu;Dai, Chen;Shen, Wenbiao

作者机构:

关键词: Genetically modified;Insect-resistant rice;DNA degradation;Protein degradation;Thermal processing;GMO detection

期刊名称:FOOD AND CHEMICAL TOXICOLOGY ( 影响因子:6.023; 五年影响因子:5.844 )

ISSN:

年卷期:

页码:

收录情况: SCI

摘要: This study aimed to investigate the degradation of three transgenic Bacillus thuringiensis (Bt) genes (Cry1Ab, Cry1Ac, and Cry1Ab/Ac) and the corresponding encoded Bt proteins in KMD1, KF6, and TT51-1 rice powder, respectively, following autoclaving, cooking, baking, or microwaving. Exogenous Bt genes were more stable than the endogenous sucrose phosphate synthase (SPS) gene, and short DNA fragments were detected more frequently than long DNA fragments in both the Bt and SPS genes. Autoclaving, cooking (boiling in water, 30 min), and baking (200 degrees C, 30 min) induced the most severe Bt protein degradation effects, and Cry1Ab protein was more stable than Cry1Ac and Cry1Ab/Ac protein, which was further confirmed by baking samples at 180 degrees C for different periods of time. Microwaving induced mild degradation of the Bt and SPS genes, and Bt proteins, whereas baking (180 degrees C, 15 min), cooking and autoclaving led to further degradation, and baking (200 degrees C, 30 min) induced the most severe degradation. The findings of the study indicated that degradation of the Bt genes and proteins somewhat correlated with the treatment intensity. Polymerase chain reaction, enzyme-linked immunosorbent assay, and lateral flow tests were used to detect the corresponding transgenic components. Strategies for detecting transgenic ingredients in highly processed foods are discussed. (C) 2015 Elsevier Ltd. All rights reserved.

分类号: R99

  • 相关文献

[1]DNA degradation in genetically modified rice with Cry1Ab by food processing methods: Implications for the quantification of genetically modified organisms. Xing, Fuguo,Zhang, Wei,Selvaraj, Jonathan Nimal,Liu, Yang.

[2]Degradation of Endogenous and Exogenous Genes of Genetically Modified Rice with Cry1Ab during Food Processing. Zhang, Wei,Xing, Fuguo,Selvaraj, Jonathan Nimal,Liu, Yang. 2014

[3]Real-time PCR method for detection of the transgenic rice event TT51-1. Wu, Gang,Wu, Yuhua,Nie, Shujing,Zhang, Li,Xiao, Ling,Cao, Yinglong,Lu, Changming.

[4]Endpoint Visual Detection of Three Genetically Modified Rice Events by Loop-Mediated Isothermal Amplification. Chen, Xiaoyun,Wang, Xiaofu,Zhou, Yu,Huang, Sainan,Miao, Qingmei,Zhu, Qing,Xu, Junfeng,Jin, Nuo,Huang, Sainan. 2012

[5]Increasing Carotenoid Bioaccessibility from Yellow Peppers Using Excipient Emulsions: Impact of Lipid Type and Thermal Processing. Liu, Xuan,Bi, Jinfeng,Liu, Xuan,Xiao, Hang,McClements, David Julian,Xiao, Hang,McClements, David Julian,McClements, David Julian.

[6]Effect of thermal processing on phenolic profiles and antioxidant activities in Castanea mollissima. Liu, Fengyuan,Hu, Xiaodan,Guo, Xinbo,Chang, Xiaoxiao,Brennan, Charles S.,Guo, Xinbo.

[7]Metabolite profiles of rice cultivars containing bacterial blight-resistant genes are distinctive from susceptible rice. Huang, Xin,Zhu, Shuifang,Wu, Jiao,Yu, Haichuan,Wu, Jiao,Dai, Haofu,Mei, Wenli,Peng, Ming. 2012

[8]A novel simple extracellular leucine-rich repeat (eLRR) domain protein from rice (OsLRR1) enters the endosomal pathway and interacts with the hypersensitive-induced reaction protein 1 (OsHIR1). Zhou, Liang,Cheung, Ming-Yan,Zhang, Shi-Hong,Sun, Samuel Sai-Ming,Lam, Hon-Ming,Zhou, Liang,Cheung, Ming-Yan,Zhang, Shi-Hong,Sun, Samuel Sai-Ming,Lam, Hon-Ming,Zhang, Qi,Lei, Cai-Lin,Zhang, Shi-Hong.

[9]Effects of insect-resistance transgenes on fecundity in rice (Oryza sativa, Poaceae): A test for underlying costs. Chen, LY,Snow, AA,Wang, F,Lu, BR. 2006

[10]Hybridizing transgenic Bt cotton with non-Bt cotton counters resistance in pink bollworm. Wang, Ling,Wu, Kongming,Wan, Peng,Xu, Dong,Cong, Shengbo,Wang, Jintao,Wu, Huaiheng,Wang, Ling,Jiang, Yuying,Huang, Yunxin,Carriere, Yves,Mathias, Andrea,Li, Xianchun,Tabashnik, Bruce E..

[11]Jasmonate inhibits COP1 activity to suppress hypocotyl elongation and promote cotyledon opening in etiolated Arabidopsis seedlings. Zheng, Yuyu,Zhu, Ziqiang,Cui, Xuefei,Gong, Qingqiu,Su, Liang,Yang, Jianping,Fang, Shuang,Chu, Jinfang. 2017

[12]Arabidopsis CRY2 and ZTL mediate blue-light regulation of the transcription factor CIB1 by distinct mechanisms. Liu, Hongtao,Liu, Yawen,Liu, Hongtao,Wang, Qin,Tobin, Elaine M.,Lin, Chentao,Wang, Qin,Zhao, Xiaoying,Zhao, Xiaoying,Imaizumi, Takato,Somers, David E..

[13]Construction and application of EST library from Setaria italica in response to dehydration stress. Zhang, Jinpeng,Liu, Tingsong,Fu, Junjie,Zhu, Yun,Jia, Jinping,Zheng, Jun,Zhao, Yinhe,Zhang, Ying,Wang, Guoying.

[14]HIV-1 Vpr increases Env expression by preventing Env from endoplasmic reticulum-associated protein degradation (ERAD). Zhang, Xianfeng,Zhou, Tao,Zheng, Yong-Hui,Zhang, Xianfeng,Zhou, Tao,Frabutt, Dylan A.,Zheng, Yong-Hui.

[15]Phosphoproteomic profiling of myofibrillar and sarcoplasmic proteins of muscle in response to salting. Zhang, Caixia,Wang, Zhenyu,Li, Zheng,Chen, Lijuan,Gao, Lingling,Zhang, Dequan,Shen, Qingwu. 2016

[16]Structure of an endogenous yeast 26S proteasome reveals two major conformational states. Luan, Bai,Huang, Xiuliang,Wu, Jianping,Wang, Yiwei,Xue, Xiaobin,Yan, Chuangye,Wang, Jiawei,Shi, Yigong,Wang, Feng,Mei, Ziqing,Finley, Daniel J..

[17]Arabidopsis cryptochrome 1 interacts with SPA1 to suppress COP1 activity in response to blue light. Liu, Bin,Zuo, Zecheng,Liu, Hongtao,Lin, Chentao,Liu, Bin,Zuo, Zecheng,Liu, Xuanming. 2011

[18]Towards systems biological understanding of leaf senescence. Guo, Yongfeng,Guo, Yongfeng.

[19]Targeting the middle region of CP4-EPSPS protein for its traceability in highly processed soy-related products. Wu, Honghong,Zhang, Yihua,He, Jian,Shen, Wenbiao,Wang, Xiaofu,Zhou, Xinghu,Huang, Ming,Wu, Honghong,Zhou, Xinghu.

[20]The F-box protein CPR1/CPR30 negatively regulates R protein SNC1 accumulation. Gou, Mingyue,Shi, Zhenying,Zhu, Ying,Bao, Zhilong,Hua, Jian,Shi, Zhenying,Zhu, Ying,Wang, Guoying. 2012

作者其他论文 更多>>

微信小程序