基于SLAF-seq技术开发长穗偃麦草染色体特异分子标记

doi:10.3724/SP.J.1006.2013.00727

摘要/Abstract

摘要：

长穗偃麦草1E及7E染色体上带有重要的抗赤霉病基因, 开发大量相关染色体特异分子标记有助于准确定位抗性基因及获得可用于辅助育种紧密连锁的标记。基于SLAF-seq技术, 获得了368个长穗偃麦草1E染色体特异片段, 随机选取80个特异片段设计引物, 开发了20个长穗偃麦草1E染色体特异分子标记、2个长穗偃麦草基因组特异分子标记及26个其他特异分子标记, 效率达60%。用这些特异标记能稳定检测出不同小麦–长穗偃麦草衍生材料中的1E染色体或片段。通过标记与优良性状的共分离特性, 获得与相关基因紧密连锁的标记, 将为小麦抗性育种中的分子标记辅助选择提供依据。

关键词: 长穗偃麦草, SLAF-seq 技术, 染色体特异分子标记, 小麦赤霉病, 分子标记辅助选择

Abstract:

The 1E and 7E chromosomes of Thinopyrum elongatum carry important resistance genes to wheat Fusarium head blight. Mapping and utilization of these resistance genes require numerous molecular markers specific to the 1E or 7E chromosome. In this study, we developed 368 specific fragments of Thinopyrum elongatum 1E chromosome using SLAF-seq technique, and randomly selected 80 fragments to design specific primers. Finally, 20 1E-specific, 2 genome-specific, and 26 other specific molecular markers were obtained, with the efficiency up to 60%. All the newly developed markers could amplify the specific bands in different lines derived from wheat–Th. elongatum progenies. According to the cosegregation of the specific markers and elite traits, some markers detected could be closely linked to the genes corresponding to target traits.

Key words: Thinopyrum elongatum, SLAF-seq technique, Chromosome specific molecular marker, Wheat Fusarium head blight, Marker-assisted selection

陈士强,秦树文,黄泽峰,戴毅,张璐璐,高营营,高勇,陈建民. 基于SLAF-seq技术开发长穗偃麦草染色体特异分子标记[J]. 作物学报, 2013, 39(04): 727-734.

CHEN Shi-Qiang,QIN Shu-Wen,HUANG Ze-Feng,DAI Yi,ZHANG Lu-Lu,GAO Ying-Ying,GAO Yong,CHEN Jian-Min. Development of Specific Molecular Markers for Thinopyrum elongatum Chromosome Using SLAF-seq Technique[J]. Acta Agron Sin, 2013, 39(04): 727-734.

参考文献

[1]Mao P S, Huang Y, Wang X G, Meng L, Mao P C, Zhang G F. Cytological evaluation and karyotype analysis in plant germplasms of Elytrigia Desv. Agric Sci China, 2010, 9: 1553–1560

[2]Li N(李娜), Wang X-P(王献平), Cao S-H(曹双河), Zhang X-Q(张相岐). Genome constitution of Agropyron elongatum 4x by biochemical and SSR markers. Acta Genet Sin (遗传学报), 2005, 32(6): 571–578 (in Chinese with English abstract)

[3]Yan X-D(闫小丹), Li J-L(李集临), Zhang Y-M(张延明). Application study of genetic resources in Elytrigia. Biotechnol Bull (生物技术通报), 2010(6): 18–21 (in Chinese with English abstract)

[4]Chen S Y, Xia G M, Quan T Y, Xiang F N, Jin Y, Chen H M. Introgression of salt-tolerance from somatic hybrids between common wheat and Thinopyrum ponticum. Plant Sci, 2004, 167: 773–779

[5]Li Z, Li B, Tong Y. The contribution of distant hybridization with decaploid Agropyron elongatum to wheat improvement in China. J Genet Genomics, 2008, 35: 451–456

[6]Garg M, Tanaka H, Ishikawa N, Takata K, Yanaka M, Tsujimoto H. Agropyron elongatum HMW-glutenins have a potential to improve wheat end-product quality through targeted chromosome introgression. J Cereal Sci, 2009, 50: 358–363

[7]Lammer D, Cai X W, Arterburn M, Chatelain J, Murray T, Jones S. A single chromosome addition from Thinopyrum elongatum confers a polycarpic, perennial habit to annual wheat. J Exp Bot, 2004, 55: 1715–1720

[8]Zhang X L, Shen X R, Hao Y F, Cai J J, Ohm H W, Kong L R. A genetic map of Lophopyrum ponticum chromosome 7E harboring resistance genes to Fusarium head blight and leaf rust. Theor Appl Genet, 2011, 122: 263–270

[9]Fu S L, Lü Z L, Qi B, Guo X, Li J, Liu B, Han F P. Molecular cytogenetic characterization of Wheat-Thinopyrum elongatum addition, substitution and translocation lines with a novel source of resistance to Wheat Fusarium head blight. J Genet Genomics, 2012, 39: 103–110

[10]Hu L J, Liu C, Zeng Z X, Li G R, Song X J, Yang Z J. Genomic rearrangement between wheat and Thinopyrum elongatum revealed by mapped functional molecular markers. Genes Genomics, 2012, 34: 67–75

[11]Jauhar P P, Peterson T S, Xu S S. Cytogenetic and molecular characterization of a durum alien disomic addition line with enhanced tolerance to Fusarium head blight. Genome, 2009, 52: 467–483

[12]Dvorák J, Knott D R. Disomic and ditelosomic additions of diploid Agropyron elongatum chromosomes to Triticum aestivum. Can J Genet Cytol, 1974, 16: 399–417

[13]Dvorák J, Sosulski F W. Effects of additions and substitutions of Agropyron elongatum chromosomes on characters in wheat. Can J Genet Cytol, 1974, 16: 627–637

[14]Cuthbert P A, Somers D J, Thomas J, Cloutier S, Brule-Babel A. Fine mapping Fhb1, a major gene controlling Fusarium head blight resistance in bread wheat (Triticum aestivum L.). Theor Appl Genet, 2006, 112: 1465–1472

[15]Cuthbert P A, Somers D J, Brule-Babel A. Mapping of Fhb2 on chromosome 6BS:a gene controlling Fusarium head blight field resistance in bread wheat (Triticum aestivum L.). Theor Appl Genet, 2007, 114: 429–437

[16]Qi L L, Pumphrey M O, Friebe B, Chen P D, Gill B S. Molecular cytogenetic characterization of alien introgressions with gene Fhb3 for resistance to Fusarium head blight disease of wheat. Theor Appl Genet, 2008, 117: 1155–1166

[17]Liu D-C(刘登才), Zheng Y-L(郑有良), Wang Z-R(王志容), Hou Y-C(侯永翠), Lan X-J(兰秀锦), Wei Y-M(魏育明). Distribution of chromosomes in diploid Lophopyrum elongatum (Host) A. Love that influences resistance to head scab of common wheat. J Sichuan Agric Univ (四川农业大学学报), 2001, 19(3): 200–205 (in Chinese with English abstract)

[18]Chen S-Q(陈士强), Huang Z-F(黄泽峰), Zhang Y(张勇), Ge J-Y(葛江燕), Zhu X(朱雪), Gao Y(高勇), Chen J-M(陈建民). Chromosomal location of the genes associated with FHB resistance of Lophopyrum elongatum in Chinese Spring background. J Triticeae Crops (麦类作物学报), 2012, 32(5): 839–845 (in Chinese with English abstract)

[19]Shen X R, Kong L R, Ohm H. Fusarium head blight resistance in hexaploid wheat (Triticum aestivum)-Lophopyrum genetic lines and tagging of the alien chromatin by PCR markers. Theor Appl Genet, 2004, 108: 808–813

[20]Shen X R, Ohm H. Fusarium head blight resistance derived from Lophopyrum elongatum chromosome 7E and its augmentation with Fhb1 in wheat. Plant Breed, 2006, 125: 424–429

[21]Wang J R, Wang L, Gulden S, Rocheleau H, Balcerzak M, Hattori J, Cao W, Han F, Zheng Y L, Fedak G, Ouellet T. RNA profiling of Fusarium head blight-resistant wheat addition lines containing the Thinopyrum elongatum chromosome 7E. Can J Plant Pathol, 2010, 32: 188–214

[22]Du J-K(杜军凯), Yu G-H(余桂红), Wang X-E(王秀娥), Ma H-X(马鸿翔). Development and validation of a SSCP marker for Fusarium head blight resistance QTL region in wheat. J Triticeae Crops(麦类作物学报), 2010, 30(5): 829–834 (in Chinese with English abstract)

[23]Liu S-B(刘树兵), Jia J-Z(贾继增), Wang H-G(王洪刚), Kong L-R(孔令让), Zhou R-H(周荣华). Special chromosome markers for E genome and DNA polymorphism between Agropyron elongatum (2n = 14) and common wheat detected by RAPD markers. Acta Agron Sin (作物学报), 1998, 24(6): 687–690 (in Chinese with English abstract)

[24]You M-S(尤明山), Li B-Y(李保云), Tang Z-H(唐朝晖), Liu S-B(刘守斌), Song J-M(宋健民), Mao S-F(毛善峰). Establishment of E-genome specific RAPD and SCAR markers for Thinopyrum spp. J China Agric Univ (中国农业大学学报), 2002, 7(5): 1–6 (in Chinese with English abstract)

[25]You M-S(尤明山), Li B-Y(李保云), Tian Z-H(田志会), Tang Z-H(唐朝晖), Liu S-B(刘守斌), Liu G-T(刘广田). Development of specific SSR marker for Ee-genome of Thinopymm sp. by using wheat microsatellites. J Agric Biotechnol (农业生物技术学报), 2003, 11(6): 577–581 (in Chinese with English abstract)

[26]Wang R R, Larson S R, Jensen K B. Analyses of Thinopyrum bessarabicum, T. elongatum, and T. junceum chromosomes using EST-SSR markers. Genome, 2010, 53: 1083–1089

[27]Autrique E, Tanksley S D, Sorrells M E, Singh R P. Molecular markers for four leaf rust resistance genes introgressed into wheat from wild relatives. Genome, 1995, 38: 75–83

[28]Liu S-B(刘树兵), Jia J-Z(贾继增), Wang H-G(王洪刚), Kong L-R(孔令让), Zhou R-H(周荣华). Identification of homoeology between the Elytrigia elongatum (2n = 14, EE) and wheat chromosomes using biochemical and molecular markers. Acta Agron Sin (作物学报), 1999, 26(1): 37–42 (in Chinese with English abstract)

[29]Prins R, Groenewa J Z, Marais G F, Snape J W, Koebner R M D. AFLP and STS tagging of Lr19, a gene conferring resistance to leaf rust in wheat. Theor Appl Genet, 2001, 103: 618–624

[30]Zhang L(张丽), Yan Z-H(颜泽洪), Zheng Y-L(郑有良), Liu D-C(刘登才), Dai S-F(代寿芬), Zhang L-Q(张连全), Wei Y-M (魏育明). Development of Ee-chromosome specific AFLP and STS molecular marker for Lophopyrum elongatum in Chinese Spring wheat background. J Agric Biotechnol (农业生物技术学报), 2008, 16(3): 465–473 (in Chinese with English abstract)

[31]Prabhu K V, Gupta S K, Charpe A, Koul S. SCAR marker tagged to the alien leaf rust resistance gene Lr19 uniquely marking the Agropyron elongatum-derived gene Lr24 in wheat: a revision. Plant Breed, 2004, 123: 417-420

[32]Yan H-F(闫红飞), Yang W-X(杨文香), Chen Y-F(陈云芳), Meng Q-F(孟庆芳), Liu D-Q(刘大群). Specificity and stability of E-chromosome specific SCAR marker from Thinopyrum spp. for Lr19. Acta Phytopathol Sin (植物病理学报), 2009, 39(1): 76–81 (in Chinese with English abstract)

[33]Li X M, Lee B S, Mammadov A C, Koo B C, Mott I W, Wang R C. CAPS markers specific to Eb, Ee, and R genomes in the tribe Triticeae. Genome, 2007, 50: 400–411

[34]Chen G-Y(陈国跃), Dong P(董攀), Wei Y-M(魏育明), He K(何坤), Li W(李伟), Zheng Y-L(郑有良). Development of Ee-chromosome-specific RGAP markers for Lophopyrum elongatum (Host) in wheat background by using resistance gene analog polymorphism. Acta Agron Sin (作物学报), 2007, 33(11): 1782–1787 (in Chinese with English abstract)

[35]Ge J-Y(葛江燕), Chen S-Q(陈士强), Gao Y-Y(高营营), Gao Y(高勇), Zhu X(朱雪), Huang Z-F(黄泽峰), Chen J-M(陈建民). Development of genome-specific molecular markers for Lophopyrum elongatum based on suppression subtractive hybridization. Acta Agron Sin (作物学报), 2012, 38(10): 1818–1826 (in Chinese with English abstract)

[36]Wang J-X(王景雪), Sun Y(孙毅), Gao W-J(高武军). A simple of practical method for extracting plant total DNA. J Shanxi Univ (Nat Sci Edn) (山西大学学报•自然科学版), 2000, 23(3): 271–272 (in Chinese with English abstract)

[37]Kent W J. BLAT: the BLAST-Like alignment tool. Genome Res, 2002, 12: 656–664

[38]Ma J-X(马渐新), Zhou R-H(周荣华), Dong Y-C(董玉琛), Jia J-Z(贾继增). Chromosomal location of the genes resistant to wheat stripe rust from Lophopyrum elongatum. Chin Sci Bull (科学通报), 1999, 44(1): 65–69 (in Chinese)

[39]Sears E R. Use of radiation to transfer alien segments to wheat. Crop Sci, 1993, 33: 897–901

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