Welcome to Acta Agronomica Sinica,

Acta Agron Sin ›› 2010, Vol. 36 ›› Issue (4): 574-579.doi: 10.3724/SP.J.1006.2010.00574

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

Mining and Identification of SNP from EST Sequences and Convertion of CAPS Markers in Soybean

SHU Yong-Jun,LI Yong,WU Na-La-Hu,BAI Xi,CAI Hua,JI Wei,ZHU Yan-Ming*   

  1. College of Life Science, Northeast Agricultural University, Harbin 150030, China
  • Received:2009-11-19 Revised:2010-01-08 Online:2010-04-12 Published:2010-02-09
  • Contact: ZHU Yan-Ming,E-mail: ymzhu2001@yahoo.com.cn; Tel: 0451-55190734

PDF

1679

Cited

13

Abstract:

SNPs widely distribute throughout genomes from non-coding regions to coding regions, constituting the most abundant molecular markers used in animal and plant genetic breeding. With the rapidly growing genome sequencing projects, a large amount of genomic and EST sequences has become available to the public. Many SNPs are identified by comparing genome sequences or ESTs obtained from genetically diverse lines or individuals in plants. However the SNP assay always relies on expensive equipments or reagent, which has limited the application of SNPs in genetics and breeding especially in plants. The CAPS marker, also known as PCR-RFLP marker, is the technique combining PCR and restriction enzymes digestion to detect the restriction fragment length polymorphisms. With the development of high-throughput sequencing technology, more and more SNPs are identified, among them many mutations have altered the restriction enzymes recognition sites. This provides an opportunity for high-through development of CAPS markers. With soybean genome sequences becoming available, high-throughput SNP marker development will significantly improve genetic mapping, map based cloning in soybean. To discover new SNPs in soybean, we aligned the ESTs with whole genome sequences in different soybean varieties and identified 537 EST-SNPs. The function of genes targeted by these EST-SNPs was analysed, the results showed that these genes participated in subcellular localization, protein binding or catalyzing, metabolic process and cell rescue, defense and disease resistance, etc. Most of these functions are involving in various physiological and biochemical processes influencing important agronomic traits. To develop easy assay method for these EST-SNPs, we identified the EST-SNPs which alter the restrict enzyme recognition sites by software EMBOSS, and 48 pair primers were designed to detect these EST-SNPs. forty-four pair primers amplified single bands (400–800 bp) from genomic DNA of Suinong 14 widely planted in the Northeast China. To verify the SNP polymorphisms, we used these primer pairs for PCR amplification from genomic DNA of Suinong 14, Hefeng 25, Acher, Evans, Peking, PI209332, Guxin wild soybean, Kefeng 1, Nannong 1138-2 and pool DNA of the nine soybean varieties. The PCR amplicons were sequenced, the traces of the 36 discordant ones were detected as candidate SNPs, which were then validated by re-sequencing the individuals. SNPs were identified using restriction enzymess of 26 pair primers with unequivocal restriction pattern were identified as CAPS markers. The SNPs discovery and CAPS markers conversion system developed in this study is fast, low cost and effecient, and holds great promise for molecular assisted breeding of soybean. , and the product

Key words: Soybean, EST, Genome sequences, SNP, CAPS

[1] Ganal M W, Altmann T, Roder M S. SNP identification in crop plants. Curr Opin Plant Biol, 2009, 12: 211–217

[2] Wiltshire T, Pletcher M T, Batalov S, Barnes S W, Tarantino L M, Cooke M P, Wu H, Smylie K, Santrosyan A, Copeland N G, Jenkins N A, Kalush F, Mural R J, Glynne R J, Kay S A, Adams M D, Fletcher C F. Genome-wide single-nucleotide polymorphism analysis defines haplotype patterns in mouse. Proc Natl Acad Sci USA, 2003, 100: 3380–3385

[3] Feltus F A, Wan J, Schulze S R, Estill J C, Jiang N, Paterson A H. An SNP resource for rice genetics and breeding based on subspecies indica and japonica genome alignments. Genome Res, 2004, 14: 1812–1819

[4] Jander G, Norris S R, Rounsley S D, Bush D F, Levin I M, Last R L. Arabidopsis map-based cloning in the post-genome era. Plant Physiol, 2002, 129: 440–450

[5] Picoult-Newberg L, Ideker T E, Pohl M G, Taylor S L, Donaldson M A, Nickerson D A, Boyce-Jacino M. Mining SNPs from EST databases. Genome Res, 1999, 9: 167–174

[6] Snelling W M, Casas E, Stone R T, Keele J W, Harhay G P, Bennett G L, Smith T P. Linkage mapping bovine EST-based SNP. BMC Genomics, 2005, 6: 74

[7] Batley J, Barker G, O’Sullivan H, Edwards K J, Edwards D. Mining for single nucleotide polymorphisms and insertions/deletions in maize expressed sequence tag data. Plant Physiol, 2003, 132: 84–91

[8] Somers D J, Kirkpatrick R, Moniwa M, Walsh A. Mining single-nucleotide polymorphisms from hexaploid wheat ESTs. Genome, 2003, 46: 431–437

[9] Mao X-G(毛新国), Tang J-F(汤继凤), Zhou R-H(周荣华), Jing R-L(景蕊莲), Jia J-Z(贾继增). Wheat cSNP mining based on full-length cDNA sequences. Acta Agron Sin(作物学报), 2006, 32(12): 1836–1840 (in Chinese with English abstract)

[10] Kota R, Rudd S, Facius A, Kolesov G, Thiel T, Zhang H, Stein N, Mayer K, Graner A. Snipping polymorphisms from large EST collections in barley (Hordeum vulgare L.). Mol Genet Genomics, 2003, 270: 24–33

[11] Kota R, Varshney R, Prasad M, Zhang H, Stein N, Graner A. EST-derived single nucleotide polymorphism markers for assembling genetic and physical maps of the barley genome. FunctIntegr Genomics, 2008, 8: 223–233

[12] Komori T, Nitta N. Utilization of the CAPS/dCAPS method to convert rice SNPs into PCR-based markers. Breed Sci, 2005, 55: 93–98

[13] Cregan P B, Jarvik T, Bush A L, Shoemaker R C, Lark K G, Kahler A L, Kaya N, VanToai T T, Lohnes D G, Chung J, Specht J E. An integrated genetic linkage map of the soybean genome. Crop Sci, 1999, 39: 1464–1490

[14] Song Q J, Marek L F, Shoemaker R C, Lark K G, Concibido V C, Delannay X, Specht J E, Cregan P B. A new integrated genetic linkage map of the soybean. Theor Appl Genet, 2004, 109: 122–128

[15] Tian A G, Wang J, Cui P, Han Y J, Xu H, Cong L J, Huang X G, Wang X L, Jiao Y Z, Wang B J, Wang Y J, Zhang J S, Chen S Y. Characterization of soybean genomic features by analysis of its expressed sequence tags. Theor Appl Genet, 2004, 108: 903–913

[16] Yang Z-Y(杨振宇), Ma X-P(马晓萍), Yamanaka N(山中直树). Polymorphism of phosphoenolpyruvate carboxylase gene in soybean cultivars from northeastern China and Japan. Acta Agron Sin(作物学报), 2005, 31(9): 1233–1235 (in Chinese with English abstract)

[17] Rice P, Longden I, Bleasby A. EMBOSS: The european molecular biology open software suite. Trends Genet, 2000, 16: 276–277

[18] Rozen S, Skaletsky H. Primer3 on the WWW for general users and for biologist programmers. Methods Mol Biol, 2000, 132: 365–386

[19] Garg K, Green P, Nickerson D A. Identification of candidate coding region single nucleotide polymorphisms in 165 human genes using assembled expressed sequence tags. Genome Res, 1999, 9: 1087–1092

[20] Guryev V, Berezikov E, Malik R, Plasterk R H, Cuppen E. Single nucleotide polymorphisms associated with rat expressed sequences. Genome Res, 2004, 14: 1438–1443

[21] Kerstens H H, Kollers S, Kommadath A, Del Rosario M, Dibbits B, Kinders S M, Crooijmans R P, Groenen M A. Mining for single nucleotide polymorphisms in pig genome sequence data. BMC Genomics, 2009, 10: 4

[22] Torjek O, Berger D, Meyer R C, Mussig C, Schmid K J, Rosleff Sorensen T, Weisshaar B, Mitchell-Olds T, Altmann T. Establishment of a high-efficiency SNP-based framework marker set for Arabidopsis. Plant J, 2003, 36: 122–140

[23] Yamamoto N, Tsugane T, Watanabe M, Yano K, Maeda F, Kuwata C, Torki M, Ban Y, Nishimura S, Shibata D. Expressed sequence tags from the laboratory-grown miniature tomato (Lycopersicon esculentum) cultivar Micro-Tom and mining for single nucleotide polymorphisms and insertions/deletions in tomato cultivars. Gene, 2005, 356: 127–134

[24] Dantec L L, Chagné D, Pot D, Cantin O, Garnier-Géré P, Bedon F, Frigerio J M, Chaumeil P, Léger P, Garcia V, Laigret F, de Daruvar A, Plomion C. Automated SNP detection in expressed sequence tags: Statistical considerations and application to maritime pine sequences. Plant Mol Biol, 2004, 54: 461–470

[25] Cordeiro G M, Eliott F, McIntyre C L, Casu R E, Henry R J. Characterisation of single nucleotide polymorphisms in sugarcane ESTs. Theor Appl Genet, 2006, 113: 331–343

[26] Choi I Y, Hyten D L, Matukumalli L K, Song Q, Chaky J M, Quigley C V, Chase K, Lark K G, Reiter R S, Yoon M S. A soybean transcript map: Gene distribution, haplotype and single-nucleotide polymorphism analysis. Genetics, 2007, 176: 685–696

[27] Zhu Y L, Song Q J, Hyten D L, Van Tassell C P, Matukumalli L K, Grimm D R, Hyatt S M, Fickus E W, Young N D, Cregan P B. Single-nucleotide polymorphisms in soybean. Genetics, 2003, 163: 1123–1134
[1] CHEN Ling-Ling, LI Zhan, LIU Ting-Xuan, GU Yong-Zhe, SONG Jian, WANG Jun, QIU Li-Juan. Genome wide association analysis of petiole angle based on 783 soybean resources (Glycine max L.) [J]. Acta Agronomica Sinica, 2022, 48(6): 1333-1345.
[2] HU Wen-Jing, LI Dong-Sheng, YI Xin, ZHANG Chun-Mei, ZHANG Yong. Molecular mapping and validation of quantitative trait loci for spike-related traits and plant height in wheat [J]. Acta Agronomica Sinica, 2022, 48(6): 1346-1356.
[3] YANG Huan, ZHOU Ying, CHEN Ping, DU Qing, ZHENG Ben-Chuan, PU Tian, WEN Jing, YANG Wen-Yu, YONG Tai-Wen. Effects of nutrient uptake and utilization on yield of maize-legume strip intercropping system [J]. Acta Agronomica Sinica, 2022, 48(6): 1476-1487.
[4] XU Tian-Jun, ZHANG Yong, ZHAO Jiu-Ran, WANG Rong-Huan, LYU Tian-Fang, LIU Yue-E, CAI Wan-Tao, LIU Hong-Wei, CHEN Chuan-Yong, WANG Yuan-Dong. Canopy structure, photosynthesis, grain filling, and dehydration characteristics of maize varieties suitable for grain mechanical harvesting [J]. Acta Agronomica Sinica, 2022, 48(6): 1526-1536.
[5] YU Chun-Miao, ZHANG Yong, WANG Hao-Rang, YANG Xing-Yong, DONG Quan-Zhong, XUE Hong, ZHANG Ming-Ming, LI Wei-Wei, WANG Lei, HU Kai-Feng, GU Yong-Zhe, QIU Li-Juan. Construction of a high density genetic map between cultivated and semi-wild soybeans and identification of QTLs for plant height [J]. Acta Agronomica Sinica, 2022, 48(5): 1091-1102.
[6] LI A-Li, FENG Ya-Nan, LI Ping, ZHANG Dong-Sheng, ZONG Yu-Zheng, LIN Wen, HAO Xing-Yu. Transcriptome analysis of leaves responses to elevated CO2 concentration, drought and interaction conditions in soybean [Glycine max (Linn.) Merr.] [J]. Acta Agronomica Sinica, 2022, 48(5): 1103-1118.
[7] PENG Xi-Hong, CHEN Ping, DU Qing, YANG Xue-Li, REN Jun-Bo, ZHENG Ben-Chuan, LUO Kai, XIE Chen, LEI Lu, YONG Tai-Wen, YANG Wen-Yu. Effects of reduced nitrogen application on soil aeration and root nodule growth of relay strip intercropping soybean [J]. Acta Agronomica Sinica, 2022, 48(5): 1199-1209.
[8] WANG Hao-Rang, ZHANG Yong, YU Chun-Miao, DONG Quan-Zhong, LI Wei-Wei, HU Kai-Feng, ZHANG Ming-Ming, XUE Hong, YANG Meng-Ping, SONG Ji-Ling, WANG Lei, YANG Xing-Yong, QIU Li-Juan. Fine mapping of yellow-green leaf gene (ygl2) in soybean (Glycine max L.) [J]. Acta Agronomica Sinica, 2022, 48(4): 791-800.
[9] YAN Sheng-Ji, DENG Ai-Xing, SHANG Zi-Yin, TANG Zhi-Wei, CHEN Chang-Qing, ZHANG Jun, ZHANG Wei-Jian. Characteristics of carbon emission and approaches of carbon mitigation and sequestration for carbon neutrality in China’s crop production [J]. Acta Agronomica Sinica, 2022, 48(4): 930-941.
[10] LI Rui-Dong, YIN Yang-Yang, SONG Wen-Wen, WU Ting-Ting, SUN Shi, HAN Tian-Fu, XU Cai-Long, WU Cun-Xiang, HU Shui-Xiu. Effects of close planting densities on assimilate accumulation and yield of soybean with different plant branching types [J]. Acta Agronomica Sinica, 2022, 48(4): 942-951.
[11] ZHENG Shu-Feng, LIU Xiao-Ling, WANG Wei, XU Dao-Qing, KAN Hua-Chun, CHEN Min, LI Shu-Ying. On the green and light-simplified and mechanized cultivation of cotton in a cotton-based double cropping system [J]. Acta Agronomica Sinica, 2022, 48(3): 541-552.
[12] LIU Dan, ZHOU Cai-E, WANG Xiao-Ting, WU Qi-Meng, ZHANG Xu, WANG Qi-Lin, ZENG Qing-Dong, KANG Zhen-Sheng, HAN De-Jun, WU Jian-Hui. Rapid identification of adult plant wheat stripe rust resistance gene YrC271 using high-throughput SNP array-based bulked segregant analysis [J]. Acta Agronomica Sinica, 2022, 48(3): 553-564.
[13] DU Hao, CHENG Yu-Han, LI Tai, HOU Zhi-Hong, LI Yong-Li, NAN Hai-Yang, DONG Li-Dong, LIU Bao-Hui, CHENG Qun. Improving seed number per pod of soybean by molecular breeding based on Ln locus [J]. Acta Agronomica Sinica, 2022, 48(3): 565-571.
[14] ZHOU Yue, ZHAO Zhi-Hua, ZHANG Hong-Ning, KONG You-Bin. Cloning and functional analysis of the promoter of purple acid phosphatase gene GmPAP14 in soybean [J]. Acta Agronomica Sinica, 2022, 48(3): 590-596.
[15] WANG Juan, ZHANG Yan-Wei, JIAO Zhu-Jin, LIU Pan-Pan, CHANG Wei. Identification of QTLs and candidate genes for 100-seed weight trait using PyBSASeq algorithm in soybean [J]. Acta Agronomica Sinica, 2022, 48(3): 635-643.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
Add: No.12 Zhongguancun South Street, Beijing 100081,China Email:xbzw@chinajournal.net.cn
Supported by Beijing Magtech Co.Ltd