Welcome to Acta Agronomica Sinica,

Acta Agronomica Sinica ›› 2020, Vol. 46 ›› Issue (4): 473-483.doi: 10.3724/SP.J.1006.2020.93047

• CROP GENETICS & BREEDING·GERMPLASM RESOURCES·MOLECULAR GENETICS •     Next Articles

Development of genetically modified maize MIR604 matrix reference materials

LI Jun1,LI Liang2,LI Xia-Ying3,SONG Gui-Wen3,SHEN Ping3,ZHANG Li1,ZHAI Shan-Shan1,LIU Fang-Fang2,WU Gang1,ZHANG Xiu-Jie3,*(),WU Yu-Hua1,*()   

  1. 1 Key Laboratory of Biology and Genetic Improvement of Oil Crops, Ministry of Agriculture and Rural Affairs, Oil Crops Research Institute, Chinese Academy of Agricultural Sciences, Wuhan 430062, Hubei, China
    2 Biotechnology Research Institute, Chinese Academy of Agricultural Sciences, Beijing 100081, China
    3 Development Center of Science and Technology, Ministry of Agriculture and Rural Affairs, Beijing 100025, China
  • Received:2019-08-28 Accepted:2019-12-26 Online:2020-04-12 Published:2020-01-15
  • Contact: Xiu-Jie ZHANG,Yu-Hua WU E-mail:zhxj7410@sina.com;wuyuhua@oilcrops.cn
  • Supported by:
    This study was supported by the National Major Project for Developing New GM Crops(2016ZX08012003);the National Natural Science Foundation of China(31601581)

RichHTML367

30

PDF

511

Abstract:

The safety supervision of genetically modified organisms (GMO) is the guarantee for the healthy development of the biotechnology, and the reference materials (RM) are the material basis for GMOs detection. The lack of RMs makes it difficult to ensure the accuracy, reliability and comparability of the test data. GM maize MIR604 is approved for import as a raw material in China. The safety supervision of GM maize MIR604 urgently requires to prepare RMs. The pure GM maize MIR604 matrix RMs were prepared through the steps of raw material identification, grinding, sieving and water content determination. The results of homogeneity test and stability test showed that the RMs in this batch had good homogeneity within the bottle and between the bottles, the property value of the RMs was stable, allowing them to be transported at room temperature for one month, as even for six months verified by the long-term stability test. The copy number ratio of the transgenic DNA to the total DNA was collaboratively characterized by nine laboratories using the duplex digital PCR of MIR604/Adh1. The certified value was 0.50. The various uncertainty components of the RM characterization results were fully evaluated, and the expanded uncertainty was combined to be 0.06 (copy/copy). The specification of RMs of this batch is 1 g bottle -1 and the minimum sample size is 100 mg. This batch of RMs can be used in the fields of safety supervision and labelling of MIR604, and laboratory quality control.

Key words: GM maize MIR604, matrix reference material, digital PCR, Real-time PCR, collaborative characterization

Table 1

List of primer and probe information"

靶标
Target		 引物名称
Primer name		 序列
Sequence (5°-3°)		 产物大小
Amplicon size (bp)		 参考文献
Reference
MIR604 MIR604F GCGCACGCAATTCAACAG 76 Mazzara et al. 2007[10]
MIR604R GGTCATAACGTGACTCCCTTAATTCT
MIR604P AGGCGGGAAACGACAATCTGATCATG
Adh1 ADH-FF3 CGTCGTTTCCCATCTCTTCCTCCT 135 Mazzara et al. 2013[10]
ADH-RR4 CCACTCCGAGACCCTCAGTC
ADH1-MDO AATCAGGGCTCATTTTCTCGCTCCTCA
MON810 MON810F TCGAAGGACGAAGGACTCTAACGT 92 ISO 21570[11]
MON810R GCCACCTTCCTTTTCCACTATCTT
MON810P AACATCCTTTGCCATTGCCCAGC
MON863 MON863F TGTTACGGCCTAAATGCTGAACT 84 Mazzara et al. 2005[12]
MON863R GTAGGATCGGAAAGCTTGGTAC
MON863P TGAACACCCATCCGAACAAGTAGGGTCA
NK603 NK603-F ATGAATGACCTCGAGTAAGCTTGTTAA 108 Mazzara et al. 2005[13]
NK603-R AAGAGATAACAGGATCCACTCAAACACT
NK603-PR TGGTACCACGCGACACACTTCCACTC
T25 MLD143 ACAAGCGTGTCGTGCTCCAC 102 Mazzara et al. 2013[14]
MDB551 GACATGATACTCCTTCCACCG
TM016 TCATTGAGTCGTTCCGCCATTGTCG
TC1507 TC1507F TAGTCTTCGGCCAGAATGG 58 Mazzara et al. 2007[15]
TC1507R CTTTGCCAAGATCAAGCG
TC1507P TAACTCAAGGCCCTCACTCCG
MIR604插入位点
MIR604 insert site		 MIR604GF GACGCCAGATCACACATG 168 本研究
This study
MIR604GR CACACCTCGTTGCCAAAG
MIR604GP CGTGCCGATCTCGCACCAGCA

Fig. 1

Schematic diagram of identifying genotype of genetically modified seeds The grey rectangles indicate the recipient genomic DNA, the black rectangles with white spots indicate the insert DNA, the arrows indicate the position of the primers, and the bold black lines indicate the position of the probes."

Fig. 2

Amplification curves of heterozygous seed"

Fig. 3

Measured values of initial test samples for homogeneity"

Fig. 4

Measurement results for homogeneity test of reference materials"

Table 2

Variance analysis of homogeneity test data"

项目
Item		 分析结果
Test data
测量平均值Mean 0.5
组间差方和Q1 0.013
组间自由度V1 14
组间方差S12 0.000922
组内差方和Q2 0.019
组内自由度V2 30
组内方差S22 0.000649
统计量F 1.42
临界值F0.05(14, 30) 2.04
比较Comparison F<F0.05(14, 30)
结论Conclusion 均匀Homogenous

Table 3

Short-term stability of copy number ratio"

时间
Time		 贮存温度 Storage temperature
4℃ 25℃ 37℃ 60℃
0周 0 week 0.499 0.493 0.500 0.489
1周 1 week 0.507 0.514 0.509 0.518
2周 2 weeks 0.510 0.504 0.488 0.500
4周 4 weeks 0.493 0.498 0.513 0.501
平均值 Mean 0.502 0.502 0.503 0.502
斜率Slope (β1) -0.002 -0.0004 0.002 0.001
与斜率相关的不确定度Uncertainty associated with slope s(β1) 0.0029 0.0037 0.0043 0.0049
t0.95,n-2 4.303 4.303 4.303 4.303
t0.95,n-2×s(β1) 0.013 0.016 0.018 0.021
稳定性判断Conclusion 稳定Stable 稳定Stable 稳定Stable 稳定Stable

Table 4

Long-term stability of copy number ratio"

时间
Time		 4℃条件下测量值
Measured value at 4℃		 -20℃条件下测量值
Measured value at -20℃
0个月 0 month 0.496 0.506
1个月 1 month 0.486 0.494
2个月 2 months 0.508 0.495
4个月 4 months 0.492 0.484
6个月 6 months 0.506 0.506
平均值Mean 0.498 0.497
斜率Slope (β1) 0.003 -0.001
与斜率相关的不确定度Uncertainty associated with slope s(β1) 0.0031 0.0034
t0.95,n-2 3.182 3.182
t0.95,n-2×s(β1) 0.010 0.011
稳定性判断Conclusion 稳定Stable 稳定Stable

Table 5

Data of collaborative characterization for the copy number ratio of MIR604 powdered reference materials"

实验室编号
Lab. no.		 重复1
Rep.1		 重复2
Rep.2		 重复3
Rep.3		 重复4
Rep.4		 重复5
Rep.5		 重复6
Rep.6		 重复7
Rep.7		 重复8
Rep.8
1 0.5029 0.5095 0.5110 0.5070 0.5109 0.5042 0.4968 0.5087
2 0.5088 0.4990 0.5000 0.4896 0.5191 0.5064 0.5183 0.5021
3 0.5135 0.4941 0.5070 0.5030 0.5010 0.4943 0.5018 0.4861
4 0.5141 0.5119 0.4903 0.5070 0.4949 0.4829 0.4990 0.5128
5 0.5011 0.4844 0.5072 0.4898 0.5053 0.4927 0.5077 0.4947
6 0.5094 0.5170 0.5064 0.5090 0.4948 0.5126 0.4861 0.4965
7 0.5000 0.4859 0.5132 0.4909 0.5167 0.5000 0.5082 0.4917
8 0.4990 0.5114 0.4858 0.4951 0.4981 0.5134 0.5028 0.5038
9 0.5143 0.5115 0.4962 0.5028 0.5163 0.5059 0.5091 0.4962
平均值Mean 0.5027
标准差SD 0.001
相对标准差RSD 0.002

Table 6

Components and combination of uncertainty for the copy number ratio of MIR604 powdered reference materials"

标准物质
标准值
Certified value		 定值引入的相对不确定度uc 均匀性引入的相对不确定度ubb 稳定性引入的相对不确定度us 相对不确定度
uCRM		 扩展不确定度
UCRM (k = 2)
A类uA B类uB 短期稳定性uss 长期稳定性uls
0.50 0.002 0.014 0.019 0.030 0.038 0.054 0.06
[1] 沈平, 武玉花, 梁晋刚, 卢新, 章秋艳, 王颢潜, 刘鹏程 . 转基因作物发展及应用概述. 中国生物工程杂志, 2017,37(1):119-128.
Shen P, Wu Y H, Liang J G, Lu X, Zhang Q Y, Wang H Q, Liu P C . The overview in development and application of genetically modified crops. China Biotechnol, 2017,37(1):119-128 (in Chinese with English abstract).
[2] 于亚东, 卢晓华, 倪晓丽, 陈文祥, 胡晓燕, 吴忠祥, 王亚平 . 标准物质通用术语和定义. JJF 1005-2016. 北京: 中国标准出版社, 2016. pp 1-22.
Yu Y D, Lu X H, Ni X L, Chen W X, Hu X Y, Wu Z X, Wang Y P. General Terms and Definitions Used in Connection with Reference Materials. JJF 1005-2016. Beijing: Standards Press of China, 2016 (in Chinese).
[3] 周云龙, 吴刚, 宋贵文, 王灿华, 卢长明, 龙丽坤, 朱莉, 沈平, 张丽, 张秀杰, 李亮, 李昂, 李文龙, 李飞武, 李允静, 杨立桃, 金芜军, 武玉花, 姜羽, 章秋燕 . 转基因生物标准物质研制与应用. 北京: 中国质检出版社, 2014. pp 39-61.
Zhou Y L, Wu G, Song G W, Wang C H, Lu C M, Long L K, Zhu Li, Shen P, Zhang L, Zhang X J, Li L, L A, Li W L, Li F W, Li Y J, Yang L T, Jin W J, Wu Y H, Jiang Y, Zhang Q Y . Development and Application of Reference Materials for Genetically Modified Organisms. Beijing: China Quality Inspection Press, 2014. pp 39-61(in Chinese).
[4] Ciabatti I, Marchesi U, Froiio A, Paternò A, Ruggeri M, Amaddeo D . Role of the “National Reference Centre for Genetically Modified Organisms (GMO) Detection” in the official control of food and feed. Veterinary Res Commun, 2005,29(2):31-34.
[5] Lauwaars M, Anklam E . Method validation and reference materials. Accred Qual Assur, 2004,9:253-258.
[6] 张丽, 吴刚, 武玉花, 沈平, 宋贵文, 周云龙 . 转基因产品检测标准物质的定值和不确定度研究进展. 农业生物技术学报, 2014,22:362-371.
Zhang L, Wu G, Wu Y H, Shen P, Song G W, Zhou Y L . Research progress on value characterization and uncertainty evaluation of reference materials for genetically modified organisms. J Agric Biotechnol, 2014,22:362-371 (in Chinese with English abstract).
[7] Wu Y, Li J, Li X, Zhai S S, Gao H F, Li Y, Zhang X, Wu G . Development and strategy of reference materials for the DNA-based detection of genetically modified organisms. Anal Bioanal Chem, 2019,411:1729-1744.
[8] Steiner H Y, Chen E, Meghji M . Corn event MIR604. Patent No: US 8884102B2, 2014. pp 1-33.
[9] 余逵, 刘清贤, 陈保华 . 一级标准物质技术规范, JJF 1006-1994. 北京: 中国标准出版社, 1994. pp 1-21.
Yu K, Liu Q X, Chen B H. Technical Norm of Primary Reference Material, JJF 1006-1994. Beijing: Standards Press of China, 1994. pp 1-21(in Chinese).
[10] Mazzara M, Munaro B, Foti N, Savini C, Van Den Eede G . Event-specific method for the quantification of maize line MIR604 using real-time PCR—validation report and protocol—maize seeds sampling and DNA extraction. 2007 [2017-05-10] pp 1-76. .
[11] International Organization for Standardization. Foodstuffs- Methods of analysis for the detection of genetically modified organisms and derived products—Quantitative nucleic acid based methods.ISO 21570: 1-103, 2005.
[12] Mazzara M, Foti N, Price S, Paoletti C, Van Den Eede G . Event-specific method for the quantitation of maize line MON 863 using real-time PCR—Validation report and protocol. 2005[2017-05-10]. pp 1-84. .
[13] Mazzara M, Paoletti C, Puumalaainen J, Rasulo D, Van Den Eede G . Event-specific method for the quantitation of maize line NK603 using real-time PCR—Validation report and protocol. 2005 [2017-05-10], pp 1-108. .
[14] Mazzara M, Grazioli E, Savini C, Van Den Eede G . Event-specific method for the quantification of maize line T25 using real-time PCR—Validation report and validated method. 2013 [2017-05-10], pp 1-102. .
[15] Mazzara M, Foti N, Price S, Paoletti C, Van Den Eede G . Event-specific method for the quantitation of maize line TC1507 using real-time PCR—Validation report and protocol—Sampling and DNA extraction of maize TC15O7. 2005 [2017-05-10]. pp 1-58. .
[16] 周云龙, 卢长明, 刘信, 曹应龙, 宋贵文, 沈平, 吴刚, 杨立桃, 王晶, 王江, 李允静, 李飞武, 赵欣 . 转基因植物及其产品成分检测: 基体标准物质制备技术规范, 农业部1782号公告- 8-2012. 北京: 中国农业出版社, 2012. pp 1-14.
Zhou Y L, Lu C M, Liu X, Cao Y L, Song G W, Shen P, Wu G, Yang L T, Wang J, Wang J, Li Y J, Li F W, Zhao X. Detection of Genetically Modified Plants and Derived Products: Technical Specification for Manufacture of Matrix Reference Material. Announcement No.1782 of the Ministry of Agriculture-8-2012. Beijing: China Agriculture Press, 2012. pp 1-14(in Chinese).
[17] 阚莹, 李红梅, 孟凡敏, 卢晓华, 郭敬, 胡晓燕, 王亚平 . 标准物质定值的通用原则及统计学原理, JJF 1343-2012. 北京: 中国标准出版社, 2012. pp 1-66.
Kan Y, Li H M, Meng F M, Lu X H, Guo J, Hu X Y, Wang Y P. General and Statistical Principles for Characterization of Reference Materials, JJF 1343-2012. Beijing: Standards Press of China, 2012. pp 1-66(in Chinese).
[18] 金芜军, 沈平, 张秀杰, 彭于发, 宋贵文, 黄昆仑, 张大兵, 宛煜嵩 . 转基因植物及其产品成分检测DNA提取和纯化, 农业部1485号公告-4-2010. 北京: 中国农业出版社, 2010. pp 1-12.
Jin W J, Shen P, Zhang X J, Peng Y F, Song G W, Huang K L, Zhang D B, Wan Y S. Detection of genetically modified plants and derived products—DNA extraction and purification. Announcement No.1485 of the Ministry of Agriculture-4-2010. Beijing: China Agriculture Press, 2010. pp 1-12(in Chinese).
[19] Kline M C, Duewer D L . Evaluating droplet digital polymerase chain reaction for the quantification of human genomic DNA: lifting the traceability fog. Anal Chem, 2017,89:4648-4654.
[20] Duewer D L, Kline M C, Romsos E L, Toman B . Evaluating droplet digital PCR for the quantification of human genomic DNA: converting copies per nanoliter to nanograms nuclear DNA per microliter. Anal Bioanal Chem, 2018,410:2879-2887.
[21] Košir A B, Divieto C, Pavšič J, Pavarelli S, Dobnik D, Dreo T, Bellotti R, Sassi M P, Žel J . Droplet volume variability as a critical factor for accuracy of absolute quantification using droplet digital PCR. Anal Bioanal Chem, 2017,409:6689-6697.
[22] European Union. Certification report: The certification of different mass fractions of DP-ØØ4114-3 in maize seed powder. Certified reference materials ERM®-BF439a, ERM®-BF439b, ERM®-BF439c, ERM®-BF439d and ERM®-BF439e. Luxembourg: Publications Office of the European Union, 2015.
[23] AOCS. Certified reference materials (CRMs). [2018-07-13].
[24] AOCS. Certificate of Analysis AOCS 1208-A, MIR162 maize. [ 2018-07-13].
[25] European Union. Certification report: the certification of the copy number concentration of solutions of plasmid DNA containing a BCR-ABL b3a2 transcript fragment, Certified reference materials: ERM®-AD623a, ERM®-AD623b, ERM®-AD623c, ERM®- AD623d, ERM®-AD623e, ERM®-AD623f. Luxembourg: Publications Office of the European Union. © European Union, 2012. pp 1-53.
[26] Haynes R J, Kline M C, Toman B, Scott C, Wallace P, Butler J M, Holden M J . Standard reference material 2366 for measurement of human cytomegalovirus DNA. J Mol Diagn, 2013,15:177-185.
[1] SHAN Lu-Ying, LI Jun, LI Liang, ZHANG Li, WANG Hao-Qian, GAO Jia-Qi, WU Gang, WU Yu-Hua, ZHANG Xiu-Jie. Development of genetically modified maize (Zea mays L.) NK603 matrix reference materials [J]. Acta Agronomica Sinica, 2022, 48(5): 1059-1070.
[2] WANG Wei-Xia, LAI Feng-Xiang, HU Hai-Yan, HE Jia-Chun, WEI Qi, WAN Pin-Jun, FU Qiang. Effect of 11-year storage of GMO reference material at ultra-low temperature on nucleic acid detection of standard matrix sample of transgenic crop [J]. Acta Agronomica Sinica, 2022, 48(1): 238-248.
[3] Zuo-Min WANG,Jin LIU,Shi-Chao SUN,Xin-Yu ZHANG,Fei XUE,Yan-Jun LI,Jie SUN. Identification and Expression Analysis of Multidrug and Toxic Compound Extrusion Protein Family Genes in Colored Cotton [J]. Acta Agronomica Sinica, 2018, 44(9): 1380-1392.
[4] SU Ya-Chun**,HUANG Long**,LING Hui,WANG Zhu-Qing,LIU Feng,SU Wei-Hua,HUANG Ning,WU Qi-Bin, GAO Shi-Wu,QUE You-Xiong*. Cloning and Expression Analysis of CDK Gene in Sugarcane [J]. Acta Agron Sin, 2017, 43(01): 42-50.
[5] QIANG Zhi-Quan,LIANGYa-Jun,YU Zheng-Yang,DUYa,ZHANGShuai,ZHUWei-Ning,ZHANG Lin-Sheng. Cloning and Functional Analysis of wzy2-1Gene in Wheat [J]. Acta Agron Sin, 2016, 42(08): 1253-1258.
[6] CONG Ya-Hui,WANG Ting-Ting,LIU Ju-Ge,WANG Ning,GAO Meng-Meng,LI Yan,GAI Jun-Yi. Cloning and Expression Analysis of Tolerance to Aluminum-toxicity Candidate Gene GmSTOP1 in Soybean [J]. Acta Agron Sin, 2015, 41(12): 1802-1809.
[7] CHENG Wei,ZHENG Yan-Ru,GE Dan-Feng,CHENG Guang-Yuan,ZHAI Yu-Shan,DENG Yu-Qing,PENG Lei,TAN Xiang-Yao,XU Jing-Sheng. Molecular Cloning and Expression Analysis of Transcriptional Activators ScCBF1 Gene from Sugarcane [J]. Acta Agron Sin, 2015, 41(05): 717-724.
[8] HUANG Long,SU Wei-Hua,ZHANG Yu-Ye,HUANG Ning,LING Hui,XIAO Xin-Huan,QUE You-Xiong*,CHEN Ru-Kai*. Cloning and Expression Analysis of CIPK Gene in Sugarcane [J]. Acta Agron Sin, 2015, 41(03): 499-506.
[9] HEN Na,PAN Li-Juan,CHI Xiao-Yuan,CHEN Ming-Na,WANG Tong,WANG Mian,YANG Zhen,HU Dong-Qing,WANG Dao-Yuan,YU Shan-Lin. Cloning and Expression Analysis of Fructose-1,6-Bisphosphate Aldolase Gene AhFBA1 in Peanut (Arachis hypogaea L.) [J]. Acta Agron Sin, 2014, 40(05): 934-941.
[10] ZHANG Guo-Jia,HOU Lei,WANG Qing-Guo,LI Zhen,DAI Shao-Jun,LIU Wei. Cloning and Functional Characterization of Peanut Gene AhSOS2 [J]. Acta Agron Sin, 2014, 40(03): 405-415.
[11] ZHU Xiao-Ling,CHEN Hai-Feng,WANG Cheng,HAO Qing-Nan,CHEN Li-Miao,GUO Dan-Dan,WU Bao-Duo,CHEN Shui-Lian,SHA Ai-Hua,ZHOU Rong,ZHOU Xin-An. Molecular Cloning and Bioinformatics Analysis of K+ Transporter Gene (GmKT12) from Soybean (Glycine max [L.] Merri) [J]. Acta Agron Sin, 2013, 39(09): 1701-1709.
[12] XIE Deng-Lei,CUI Jiang-Hui,CHANG Jin-Hua. Cloning and Expression Analysis of SbDREB2 Gene from Sorghum bicolor [J]. Acta Agron Sin, 2013, 39(08): 1352-1359.
[13] ZHANG Guang-Yuan,SUN Hong-Wei,LI Fan,YANG Shu-Ke,LU Xing-Bo,ZHAO Lei. Event-Specific PCR Detection Method of Genetically Modified Maize MIR162 and Its Standardization [J]. Acta Agron Sin, 2013, 39(07): 1141-1147.
[14] ZHU Bin,LU Jun-Xing,PENG Qian,WENG Chang-Mei,WANG Shu-Wen,YU Hao,LI Jia-Na,LU Kun,LIANG Ying. Cloning and Analysis of MAPK7 Gene Family and Their Promoters from Brassica napus [J]. Acta Agron Sin, 2013, 39(05): 789-805.
[15] MIN Dong-Hong,ZHAO Yue,CHEN Yang,XU Zhao-Shi,HUO Dong-Ying,HU Di,CHEN Ming,LI Lian-Cheng,MA You-Zhi. Isolation and Molecular Characterization of Stress-Related TaLEAL3 Gene in Wheat [J]. Acta Agron Sin, 2012, 38(10): 1847-1855.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
Add: No. 80 Xueyuan South Rd, Beijing 100081, P. R. China E-mail: zwxb301@caas.cn
Supported by Beijing Magtech Co.Ltd