转BtCry1Ac欧洲黑杨的外源基因插入位点分析及特异性检测

doi:10.11707/j.1001-7488.20201005

摘要/Abstract

摘要：

目的: 分析转BtCry1Ac欧洲黑杨外源基因插入位点，从而进一步完善抗虫转基因杨树的背景信息，推进抗虫转基因杨树的安全评价及应用。方法: 以转BtCry1Ac欧洲黑杨株系n12、n222为试验材料，使用高效热不对称交错PCR法（hiTAIL-PCR）分离外源基因插入位点侧翼序列，比对毛果杨基因组序列确定插入位点。根据插入位点处的侧翼序列设计2对特异性PCR检测引物，建立转BtCry1Ac欧洲黑杨外源基因特异性PCR检测方法，并利用实时荧光定量PCR技术分析插入位点周边基因表达情况。结果: PCR及半定量PCR结果表明，转基因欧洲黑杨株系的BtCry1Ac基因稳定表达。通过比对毛果杨基因组序列确定转基因杨n12 T-DNA插入基因组Chr15的10162773位点即Potri.015G076600第2个内含子，其碱基组成AT含量为65%；n222整合位点为基因组Chr01基因间隔区41596184位点，其碱基组成AT含量为69%。特异性PCR检测显示，n12能扩增出709 bp（转基因）和1 159 bp（非转基因）特异性条带，n222及其与丹红杨杂交子代能扩增出1 265 bp（转基因）和1 827 bp（非转基因）特异性条带，而对照仅能扩增非转基因特异性片段。n12 T-DNA插入造成插入位点的丝氨酸蛋白激酶（SPK）Potri.015G076600基因表达量上调4.3倍，而附近的共济失调毛细血管扩张症突变蛋白（ATM）Potri.015G076700表达量下调20倍，从而可能调节杨树生长速度。n222插入位点上下游基因异黄酮-7-O-β-葡萄糖苷6″-O-丙二酰转移酶（IBG）Potri.001G395700和光敏色素互作因子解旋酶（PIF）Potri.001G395800表达量均上调。结论: 转BtCry1Ac欧洲黑杨T-DNA偏好插入富含AT区域，同时T-DNA载体边界序列缺失，并引起插入位点附近基因表达量变化。建立转BtCry1Ac欧洲黑杨特异性检测方法，为转BtCry1Ac欧洲黑杨的管理与监测提供参考。

关键词: 欧洲黑杨, 抗虫基因, BtCry1Ac, 转基因, hiTAIL-PCR, 侧翼序列, 事件特异性检测

Abstract:

Objective: In order to further improve the background information and promote the safety evaluation and application of transgenic insect-resistant Populus nigra, flanking sequence of T-DNA insertion sites were isolated in two lines (n12 and n222 with BtCry1Ac). Method: The flanking sequences of exogenous gene insertion sites were separated by hiTAIL-PCR(high-efficiency thermal asymmetric interlaced PCR), and the insertion sites were determined by comparing the genomic sequences of P. trichocarpa. Two pairs of specific PCR primers were designed according to the flanking sequence of insertion sites, and a specific PCR method was established to detect the expression of genes around insertion sites in transgenic poplar with BtCry1Ac. Quantitative real-time reverse-transcription PCR (qRT-PCR) was used to analyze the expression of genes around insertion sites. Result: PCR and semi-quantitative PCR showed that the BtCry1Ac was stable in the transgenic materials. By comparing the genome sequence of P. trichocarpa, the T-DNA of transgenic poplar n12 was inserted into the second intron of Potri.015G076600 at 10162773 locus on Chr15 and the nucleotide composition was 65% for AT content. The integration locus of n222 was 41596184 in the gene spacer of Chr01 and the nucleotide composition was 69% for AT content. Specific PCR detection showed that n12 could amplify 709 bp (transgenic) and 1 159 bp (non-transgenic) specific bands, n222 and its hybrid offspring 1 265 bp (transgenic) and 1 827 bp (non-transgenic) specific bands, while the control could only amplify non-transgenic specific bands. The expression of Potri.015G076600 (serine-protein kinase, SPK) at n12 insertion site was up-regulated 4.3 times and that of nearby Potri.015G076700 (ataxia telangiectasia mutated family protein, ATM) was down-regulated 20 times, those may be involved in the regulation of poplar growth rate. Potri.001G395700 (isoflavone-7-O-β-glucoside 6″-O-malonyltransferase, IBG) and Potri.001G395800 (PIF1-like helicase, PIF) were up-regulated in n222 and its hybrids with P. deltoides 'Danhong'. Conclusion: The T-DNA of n12 and n222 preferentially inserted into AT rich regions, while the deletion of T-DNA vector boundary sequence caused the change of genes expression near the insertion site. And the specific detection method provides a basis for the management and monitoring of transgenic P. nigra with BtCry1Ac.

Key words: Populus nigra, insect-resistant gene, BtCry1Ac, transgenic, hiTAIL-PCR, flanking sequencing, event-specific detection

中图分类号:

S718.46

张磊,胡建军. 转BtCry1Ac欧洲黑杨的外源基因插入位点分析及特异性检测[J]. 林业科学, 2020, 56(10): 45-52.

Lei Zhang,Jianjun Hu. An Analysis of T-DNA Insertion Loci and Detection of the Locus-Specific of Transgenic Populus nigra Lines with BtCry1Ac[J]. Scientia Silvae Sinicae, 2020, 56(10): 45-52.

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引物名称 Primer name	引物序列 Primer sequence (5′—3′)
Bt-F	GAATTCGCTAGGAACCAAGCCATT
Bt-R	AAGTATATCCATCAAATGTGGACT
LAD1	ACGATGGACTCCAGAGCGGCCGCVNVNNNGGAA
LAD2	ACGATGGACTCCAGAGCGGCCGCBNBNNNGGTT
LAD3	ACGATGGACTCCAGAGCGGCCGCVVNVNNNCCAA
LAD4	ACGATGGACTCCAGAGCGGCCGCBDNBNNNCGGT
AC1	ACGATGGACTCCAGAG
LB-0A	CCCAACTTAATCGCCTTGCAGCACATC
LB-1A	ACGATGGACTCCAGTCCGGCCGATTTGGGTGATGG TTCACGTAGTGGG
LB-2A	TGGACCGCTTGCTGCAACTCTCTC
RB-0A	GGATACCGAGGGGAATTTATGGAACG
RB-1A	ACGATGGACTCCAGTCCGGCCGATAGTGACCTTAG GCGACTTTTGAACG
RB-2A	GTCATCGGCGGGGGTCATAACG
RB-F	TGTGGAGCATTGGTGTGAAG
RB-R	TTGAGTATGCCCTGCTGACA
LB-F	CCAACAATCCCCCAGATGAA
LB-R	AGGACACGGAAACCTTCGGA

引物名称 Primer name	引物序列(正向) Primer sequence (Forward)(5′—3′)	引物序列(反向) Primer sequence (Reverse)(5′—3′)
Actin	AAACTGTAATGGTCCTCCCTCCG	GCATCATCACAATCACTCTCCGA
qBt	TGTATGGGGACCGGATTCTA	CGAGCCTCGAAAACTACCAT
qSPK	TTTGGAACGATCACAGCTGC	GCTCTCCAGTTCCAGCACTA
qATM	AGGGGAAGGAATGCGAAAGA	GTCCCCAATGCCAACCTTG
qIBG	ACTCTACCAAGTCAGCCACC	AGGAGTGCATGGGAAAGTGA
qPIF1	TGCCGGCTCTTAGAATTTGC	GACCCAAAGACTTGCAAGCA

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