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Research Article

Flanking Sequence and Copy-Number Analysis of Transformation Events by Integrating Next-Generation Sequencing Technology with Southern Blot Hybridization

Plant Breeding and Biotechnology 2017;5(4):269-281.
Published online: December 1, 2017

National Institute of Agricultural Science, Rural Development Administration, Jeonju 54874, Korea

*Corresponding author: Seong-Kon Lee, goryeong@korea.kr, Tel: +82-63-238-4708, Fax: +82-63-238-4704
• Received: September 4, 2017   • Revised: October 19, 2017   • Accepted: October 23, 2017

Copyright © 2017 The Korean Society of Breeding Science

This is an Open-Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/by-nc/4.0) which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

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Flanking Sequence and Copy-Number Analysis of Transformation Events by Integrating Next-Generation Sequencing Technology with Southern Blot Hybridization
Plant Breed. Biotech.. 2017;5(4):269-281.   Published online December 1, 2017
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Flanking Sequence and Copy-Number Analysis of Transformation Events by Integrating Next-Generation Sequencing Technology with Southern Blot Hybridization
Plant Breed. Biotech.. 2017;5(4):269-281.   Published online December 1, 2017
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Flanking Sequence and Copy-Number Analysis of Transformation Events by Integrating Next-Generation Sequencing Technology with Southern Blot Hybridization
Image Image Image Image Image Image Image Image
Fig. 1 Three transformation vector constructs of four transgenic lines. (A) Vector construction used to produce Bt-resistant transgenic rice C1-8-8. (B) Vector construction used to produce resveratrol-producing transgenic rice Iksan515. (C) Vector construction used to produce beta-carotene-enhanced transgenic soybeans 10-19-1 and 9-1-2. The red star signifies the enzyme selected for Southern blot hybridization.
Fig. 2 Four transgenic lines and reference read-mapping coverages of their respective transformation vectors. (A) Bt-resistant transgenic rice C1-8-8. (B) Resveratrol-producing transgenic rice Iksan515. (C) Beta-carotene-enhanced transgenic soybean 10-19-1. (D) Beta-carotene-enhanced transgenic soybean 9-1-2. Single reads mapping in the forward and reverse directions are shown in green and red, respectively; Paired reads including both the forward and reverse directions are shown in blue; Non-specific matches are shown in yellow.
Fig. 3 Flanking sequence analysis of Bt-resistant transgenic rice C1-8-8 by NGS. (A) Left border flanking sequence. (B) Right border flanking sequence. (C) Transgene insertion site on rice chromosome 8.
Fig. 4 Flanking sequence analysis of resveratrol-producing rice Iksan515 by NGS. (A) Left border flanking sequence. (B) Right border flanking sequence. (C) Transgene insertion site on rice chromosome 4.
Fig. 5 Flanking sequence analysis of beta-carotene enhanced soybean 10-19-1 by NGS. (A) Left border flanking sequence. (B) Right border flanking sequence. (C) Transgene insertion site on soybean chromosome 13.
Fig. 6 Flanking sequence analysis of beta-carotene enhanced soybean 9-1-2 by NGS. (A) Left border flanking sequence. (B) Right border flanking sequence.
Fig. 7 Transgene insertion sites of beta-carotene-enhanced soybean 9-1-2 on soybean chromosomes 5, 11 and 15. (A) Transgene insertion site on chromosome 5. (B) Transgene insertion site on chromosome 11. (C) Transgene insertion site on chromosome 15.
Fig. 8 Transgene insertion numbers analysis by Southern blot hybridization for each transgenic line. (A) C1-8-8 rice line detected by the Cry1AC probe. (B, C) Iksan515 rice line detected by Bar and RS probes, respectively. (D, E) 9-1-2 and 10-19-1 soybean lines detected by Bar and CrtI probes, respectively.
Flanking Sequence and Copy-Number Analysis of Transformation Events by Integrating Next-Generation Sequencing Technology with Southern Blot Hybridization

Reference assembly of four transgenic lines and their two donor varieties onto the Nipponbare genome (Oryza sativa Japonica) and Williams 82 genome (Glycine max).

Donors/Transformants Total reference length (bp) Total read length (bp) Average coverage Total read count Reads in aligned pairs Mapping reads percentage (%)
Dongjin 374,424,240 14,012,547,900 37.18 93,416,986 86,008,524 92.07
C1-8-8 374,427,124 13,521,598,500 35.89 90,143,990 83,362,146 92.48
Iksan515 374,429,849 10,816,879,012 28.70 107,097,812 96,012,272 89.65
Kwangan 973,344,380 44,604,413,778 45.30 297,083,584 255,110,192 85.87
10-19-1 973,349,815 46,520,391,465 47.28 309,818,590 266,173,764 85.91
9-1-2 973,349,815 33,735,100,468 33.53 225,265,764 184,757,664 82.02

Read depth of inserted genes versus each reference gene.

Transformants Features Reference name Reference length (bp) Mapped reads Average coverage Read depthz) Copy number
C1-8-8 (Rice) Inserted gene Cry1AC 1,860 355 28.13 0.84 1
T-DNA vector PCMF-Cry-MF 2,884 566 29.00 0.87
H.S. geney) SPS (U33175) 7,150 1,610 33.41
Iksan515 (Rice) Inserted gene Bar 554 243 42.49 1.66 2
Inserted gene Resveratrol synthase 1,170 598 50.79 1.99
T-DNA vector PSB2220 5,609 2,574 45.89 1.80
H.S. gene SPS (U33175) 7,150 1,829 25.55
10-19-1 (Soybean) Inserted gene Bar 552 121 30.18 0.76 1
Inserted gene Phytoene synthase 1,257 434 50.96 1.29
Inserted gene Carotene desaturase 1,479 384 38.24 0.97
T-DNA vector PAC-vector 5,435 1,467 40.34 1.02
H.S. gene Le1 (K00821.1) 2,152 580 39.58
9-1-2 (Soybean) Inserted gene Bar 552 496 126.09 4.18 6
Inserted gene Phytoene synthase 1,257 1,221 142.03 4.70
Inserted gene Carotene desaturase 1,479 1,375 135.46 4.49
T-DNA vector PAC-vector 5,435 4,694 127.30 4.22
H.S. gene Le1 (K00821.1) 2,152 450 30.20

z)Read depth = average coverage of inserted gene (transformation vector) / average coverage of housekeeping gene;

y)H.S. gene: Housekeeping gene with one copy in plant genomes.

T-DNA insertion sites and insertion structures of four transformants.

Donor genome Transformants Insertion chr.z) Insertion site Insertion structure
Rice C1-8-8 Chr.8 24,020,082-24,020,142 Reverse (RB-LB)
Rice Iksan515 Chr.4 28,858,797-28,858,848 Inverted repeat (tail to tail)
Soybean 10-19-1 Chr.13 23,918,809-23,918,840 Reverse (RB-LB)
Soybean 9-1-2 Chr.5 755,381-755,401 Inverted repeat (head to head)
Chr.11 1,680,418-1,680,448 Inverted repeat (tail to tail)
Chr.15 12,709,967-12,709,991 Inverted repeat (head to head)

z)T-DNA insertion chromosome of donor genome.

Table 1 Reference assembly of four transgenic lines and their two donor varieties onto the Nipponbare genome (Oryza sativa Japonica) and Williams 82 genome (Glycine max).
Table 2 Read depth of inserted genes versus each reference gene.

Read depth = average coverage of inserted gene (transformation vector) / average coverage of housekeeping gene;

H.S. gene: Housekeeping gene with one copy in plant genomes.

Table 3 T-DNA insertion sites and insertion structures of four transformants.

T-DNA insertion chromosome of donor genome.