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作物学报 ›› 2009, Vol. 35 ›› Issue (8): 1386-1394.doi: 10.3724/SP.J.1006.2009.01386

• 作物遗传育种·种质资源·分子遗传学 • 上一篇    下一篇

利用双向导入系解析水稻抽穗期和株高QTL及其与环境互作表达的遗传背景效应

王韵1,2,程立锐2,孙勇2,周政2,朱苓华2,徐正进1,徐建龙2,*,黎志康2,3   

  1. 1沈阳农业大学/农业部作物生理生态遗传育种重点开放实验室,辽宁沈阳110161;2中国农业科学院作物科学研究所/农作物基因资源与遗传改良国家重点科学工程,北京100081;3International Rice Research Institute,DAPO Box 7777,Metro Manila,Philippines
  • 收稿日期:2009-01-21 修回日期:2009-03-13 出版日期:2009-08-12 网络出版日期:2009-06-10
  • 通讯作者: 徐建龙, E-mail: xujl@caas.net.cn
  • 基金资助:

    本研究由引进国际先进农业科学技术计划(948计划)项目(2006-G51和2006-G1)资助。

Genetic Background Effect on QTL Expression of Heading Date and Plant Height and Their Interaction with Environment in Reciprocal Introgression Lines of Rice 

WANG Yun1,2, CHENG Li-Rui2, SUN Yong2, ZHOU Zheng2, ZHU Ling-Hua2, XU Zheng-Jin1, XU Jian-Long2,*,LI Zhi-Kang2,3   

  1. 1 Shenyang Agricultural University / Key Laboratory of Crop Physiology, Ecology, Genetics and Breeding, Ministry of Agriculture, Shenyang 110161, China;
    2 Institute of Crop Sciences / National Key Facility for Crop Gene Resources and Genetic Improvement, Chinese Academy of Agricultural Sciences, Beijing 100081, China; 3 International Rice Research Institute, DAPO Box 7777, Metro Manila, Philippines
  • Received:2009-01-21 Revised:2009-03-13 Published:2009-08-12 Published online:2009-06-10
  • Contact: XU Jian-Long, E-mail: xujl@caas.net.cn

摘要:

利用粳稻Lemont和籼稻特青相互导入构建的遗传背景基本一致的双向回交导入系群体,分别在北京和海南环境定位影响抽穗期和株高的主效QTL及其环境互作,分析QTL及其与环境互作表达的遗传背景效应。在北京和海南分别检测到影响抽穗期和株高的主效QTL 16个和17个,其中有5个主效QTL (QHd2QHd8aQPh3QPh5QPh12)在两种背景下同时被检测到,表明多数主效QTL的表达具有遗传背景特异性。两种背景下检测到影响抽穗期的3个主效QTL (QHd8aQHd9QHd10b)存在环境互作,其中QHd8a与海南环境的互作在两种背景下提早抽穗2~3 d,与北京环境的互作则延迟抽穗2~3 d,是影响抽穗期的一个重要主效QTL。通过与以往相同亲本来源的7个不同定位群体在不同环境下定位结果的比较,鉴定出一些在不同遗传背景和环境下稳定表达的主效QTL,如QHd3QHd8aQPh3QPh4,适宜用于水稻抽穗期和株高的分子标记改良。基于QTL定位结果,本文对如何通过分子标记辅助改良品种在不同环境下的抽穗期进行了深入探讨。

关键词: 数量性状基因座, 遗传背景, 基因与环境互作, 双向导入系, 抽穗期, 株高

Abstract:

Expression of quantitative trait is affected by genetic background and environment. Genetic background effect on QTL mapping and QTL by environment interaction for heading date (HD) and plant height (PH) in Beijing and Hainan environments were dissected using a large set of reciprocal introgression lines (ILs) derived from a japonica variety “Lemont” and indica variety “Teqing”. The two sets of ILs showed transgressive segregation for the two traits. Total 16 and 17 main-effect QTLs were identified for HD and PH in the two environments, respectively. Among them, only five main-effect QTLs (QHd2, QHd8a, QPh3, QPh5,and QPh12) were detected under the two backgrounds, indicating expression of most main-effect QTLs are specific to genetic background. Three main-effect QTLs (QHd8a, QHd9, and QHd10b) by environment interactions for HD were significantly detected under the two backgrounds, of which that of QHd8a had earlier heading for 2–3 days in Hainan, but delayed heading for 2–3 days in Beijing. Therefore, QHd8a could be considered as an important main-effect QTL for HD. By comparison with the QTL mapping results previously identified in the seven different mapping populations derived from the same parents in different environments, some stably expressed main-effect QTLs including QHd3, QHd8a, QPh3,and QPh4 were identified under different backgrounds and environments, suggesting these QTLs could be used in marker-assisted breeding for HD and PH. On the basis of the mapping information, marker-assisted improvement of HD for a rice variety under different environments was deeply discussed.

Key words: Quantitative trait loci, Genetic background, Gene X environment interaction, Reciprocal introgression lines, Heading date, Plant height

[1] Burr B, Burr F A. Recombinant inbreds for molecular mapping in maize: theoretical and practical considerations. Trends Genet, 1991, 7: 55-60

[2] Li Z K , Arif M, Zhong D B,Fu Y, Xu J L, Domingo-Rey J, Ali J, Vijayakumar C H M, Yu S B, Khush G S. Complex genetic networks underlying the defensive system of rice (Oryza sativa L.) to Xanthomonas oryzae pv. oryzae. Proc Natl Acad Sci USA, 2006, 103: 7994-7999

[3] Mu P(穆平), Li Z-C(李自超), Li C-P(李春平), Zhang H-L(张洪亮), Wu C-M(吴长明), Li C(李晨), Wang X-K(王象坤). QTL mapping of the root traits and their correlation analysis with drought resistance using DH lines from paddy and upland rice cross.Chin Sci Bull (科学通报), 2003, 48(24): 2718-2724 (in Chinese)

[4] Xu J-C(徐吉臣), Wang J-L(王久林), Ling Z-Z(凌忠专), Zhu L-H(朱立煌). Analysis of rice blast resistance genes by QTL mapping.Chin Sci Bull (科学通报), 2004, 49(4): 337-342 (in Chinese)

[5] Tang J-H(汤继华), Ma X-Q(马西青), Teng W-T(滕文涛), Yan J-B(严建兵), Wu W-R(吴为人), Dai J-R(戴景瑞), Li J-S(李建生). Detection of quantitative trait loci and heterotic loci for plant height using an immortalized F2 population in maize. Chin Sci Bull (中国科学通报), 2007, 52(4): 477-483 (in Chinese)

[6] Yang H(杨华), Yang J-P(杨俊品), Rong T-Z(荣廷昭), Tan J(谭君), Qiu Z-G(邱正高). QTL mapping of resistance to sheath blight in maize (Zea mays L.).Chin Sci Bull (中国科学通报), 2005, 50(8): 782-787 (in Chinese)

[7] Mei H W, Li Z K, Shu Q Y, Guo L B, Wang Y P,Yu X Q,Ying C S, Luo L J. Gene actions of QTLs affecting several agronomic traits resolved in a recombinant inbred rice population and two backcross populations. Theor Appl Genet, 2005, 110: 649-659

[8] Paterson A H, Damon S, Hewitt J D. Mendelian factors underlying quantitative traits in tomato: comparison across species, generations and environments. Genetics, 1991, 127: 181--197

[9] Yan J Q, Zhu J, He C X. Molecular marker-assisted dissection of genotype ´ environment interaction for plant type traits in rice. Crop Sci, 1999, 39: 538-544

[10]Li Z K, Yu S B, Lafitte H R, Huang N, Courtois B, Hittalmani S, Vijayakumar C H M, Liu G F, Wang G C, Shashidhar H E, Zhuang J Y, Zheng K L, Singh V P, Sidhu J S, Srivantaneeyakul S, Khush G S. QTL ´ environment interactions in rice. I. Heading date and plant height. Theor Appl Genet, 2003, 108: 141-153

[11]Zang J-P(藏金萍), Sun Y(孙勇), Wang Y(王韵), Yang J(杨静), Li F(李芳), Zhou Y-L(周永力), Zhu L-H(朱苓华), Xu J-L(徐建龙), Li Z-K(黎志康). Dissection of genetic overlap of salt tolerance QTLs at the seeding and tillering stages using backcross introgressive lines in rice. Sci China (Ser C-Life Sci)(中国科学·C辑), 2008, 51(7): 583-591(in Chinese)

[12]Chevin L M, Hospital F. Selective sweep at a quantitative trait locus in the presence of background genetic variation. Genetics, 2008, 180: 1645-1660

[13]Tanksley S D, Nelson J C. Advanced backcross QTL analysis: A method for the simultaneous discovery and transfer of valuable QTLs from unadapted germplasm into elite breeding lines. Theor Appl Genet, 1996, 92: 191-203

[14]Li D-J(李德军), Sun C-Q(孙传清), Fu Y-C(付永彩), Li C(李晨), Zhu Z-F(朱作峰), Chen L(陈亮), Cai H-W(才宏伟), Wang X-K(王象坤). Identification andmapping of genes for improving yield from Chinese common wild rice (O. rufipogon Griff.) using advanced backcross QTL analysis. Chin Sci Bull (中国科学通报), 2002, 47(18): 1533-1537 (in Chinese)

[15]Tian F, Li D J, Fu Q, Zhu Z F, Fu Y C, Wang X K, Sun C Q. Construction of introgression lines carrying wild rice (Oryza rufipogon Griff.) segments in cultivated rice (Oryza sativa L.) background and characterization of introgressed segments associated with yield-related traits. Theor Appl Genet, 2006, 112: 570-580

[16]Ren Z H, Gao J P, Li L G, Cai X L,Huang W, Chao D Y, Zhu M Z, Wang Z Y, Luan S, Lin H X. A rice quantitative trait locus for salt tolerance encodes a sodium transporter. Nat Genet, 2005, 37: 1141-1146

[17]Yang Q-H(杨权海), Lu W(陆巍), Hu M-L(胡茂龙), Wang C-M(王春明), Zhang R-X(张荣铣), Yano M, Wan J-M(万建民). QTL and epistatic interaction underlying leaf chlorophyll and H2O2 content variation in rice (Oryza sativa L.).Acta Genet Sin (遗传学报), 2003, 30(3): 245-250 (in Chinese with English abstract)

[18]Zhao X Q, Xu J L, Zhao M, Lafitte R, Zhu L H, Fu B Y, Gao M Y, Li Z K. QTLs affecting morph-physiological traits related to drought tolerance detected in overlapping introgression lines of rice (Oryza sativa L.). Plant Sci, 2008, 174: 618-625

[19]Xu J L, Lafitte H R, Gao Y M, Fu B Y, Torres R, Li Z K. QTLs for drought avoidance and tolerance identified in a set of random introgression lines of rice. Theor Appl Genet, 2005, 111: 1642-1650

[20]Zhang X, Zhou S, Fu Y, Su Z, Wang X, Sun C. Identification of a drought tolerant introgression line derived from Dongxiang common wild rice (O. rufipogon Griff.). Plant Mol Biol, 2006, 62: 247-259

[21]Steele K A, Price A H, Shashidhar H E, Witcombe J R. Marker-assisted selection to introgress rice QTLs controlling root traits into an Indian upland rice variety. Theor Appl Genet, 2006, 112: 208-221

[22]Tanksley S D, Grandillo S, Fulton T M, Zamir D, Eshed Y, Petiard V, Lopez J, Beck-Bunn T. Advanced backcross QTL analysis in a cross between an elite processing line of tomato and its wild relative L. pimpinellifolium. Theor Appl Genet, 1996, 92: 213-224

[23]Bernacchi D, Beck-Bunn T, Emmatty D, Eshed Y, Inai S, Lopez J, Petiard V, Sayama H, Uhlig J, Zamir D, Tanksley S. Advanced backcross QTL analysis in tomato. II. Evaluation of near-isogenic lines carrying single-donor introgressions for desirable wild QTL-alleles derived from Lycopersicon hirsutum and L. pimpinellifolium. Theor Appl Genet, 1998, 97: 170-180

[24]Emebiri L, Michael P, Moody D B, Ogbonnaya F C, Black C. Pyramiding QTLs to improve malting quality in barley: gains in phenotype and genetic diversity. Mol Breed, 2009, 23: 219-228

[25]Robbins M D, Casler M D, Staub J E. Pyramiding QTL for multiple lateral branching in cucumber using inbred backcross lines. Mol Breed, 2008, 22: 131-139

[26]Manly K F, Olson J M .Overview of QTL mapping software and introduction to Map Manager QT. Mammalian Genome, 1999, 10: 327-334

[27]SAS Institute. SAS/STAT User’s Guide. Cary NC, USA: SAS Institute, 1996. pp 25-36

[28]Xue X-W(谢学文), Xu M-R(许美容), Zang J-P(藏金萍), Sun Y(孙勇), Zhu L-H(朱苓华), Xu J-L(徐建龙), Zhou Y-L(周永力), Li Z-K(黎志康).Genetic background and environmental effects on expression of QTL for sheath blight resistance in reciprocal introgression lines of rice. Acta Agron Sin (作物学报), 2008, 34(11): 1885-1893 (in Chinese with English abstract)

[29]Li Z K , Pinson S R M, Stansel J W, Park W D. Identification of QTL for heading date and plant height in rice using RFLP markers. Theor Appl Genet, 1995, 91: 374-381

[30]Li Z K, Pinson S R M, Paterson A H, Park W D, Stansel J W. Genetics of hybrid sterility and hybrid breakdown in an inter-subspecific rice (Oryza sativa L.) population. Genetics, 1997, 145: 1139-1148

[31]Mei H W, Luo L J, Ying C S, Wang Y P, Yu X Q, Guo L B, Paterson A H, Li Z K. Gene actions of QTLs affecting several agronomic traits resolved in a recombinant inbred rice population and two testcross populations. Theor Appl Genet, 2003, 107: 89-101

[32]Fan C C, Yu X Q, Xing Y Z, Xu C G, Luo L J, Zhang Q F. The main effects, epistatic effects and environmental interactions of QTL on the cooking and eating quality of rice in a doubled-haploid line population .Theor Appl Genet, 2005, 110: 1445-1452

[33]Zhang K P, Tian J C, Zhao L, Wang S S. Mapping QTLs with epistatic effects and QTL ´ environment interactions for plant height using a doubled haploid population in cultivated wheat. J Genet Genomics, 2008, 35: 119-127

[34]Yuan A-P(袁爱平), Cao L-Y(曹立勇), Zhuang J-Y(庄杰云), Li R-Z(李润植), Zheng K-L(郑康乐), Zhu J(朱军), Cheng S-H(程式华). Analysis of additive and AE interaction effects of QTLs controlling plant height, heading date and panicle number in rice (Oryza sativa L.). Acta Genet Sin (遗传学报), 2003, 30(10): 899-906(in Chinese)

[35]Liu G, Yang J, Xu H, Zhu J. Influence of epistasis and QTL´environment interaction on heading date of rice (Oryza sativa L.). J Genet Genomics, 2007, 34: 608-615

[36]Li Z K, Pinson S R M, Paterson A H, Park W D, Stansel J W. Epistasis for three grain yield components in rice (Oryza sativa L.). Genetics, 1997, 145: 453-465

[37]Ware D P, Jaiswal J J, Pan N X, Chang K,Clerk K, Teytelman L, Schmidt S, Zhao W, Cartinhour S, McCouch S, Stein L. Gramene: A Resource for Comparative Grass Genomics. Nucl Acids Res, 2002,30: 103-105

[38]Temnykh S, Declerck G, Lukashova A, Lipovich L, Cartinhour S, McCouch S. Computational and experimental analysis of microsatellites in rice (Oryza sativa L.): frequency, length variation, transposon associations, and genetic marker potential. Genome Res, 2001, 11:1441-1452

[39]Doi K, Izawa T, Fuse T, Yamanouchi U, Kubo T, Shimatani Z, Yano M, Yoshimura A. Ehd1, a B-type response regulator in rice, confers short-day promotion of flowering and controls FT-like gene expression independently of Hd1. Genes & Dev, 2004, 18: 926-936

[40]Yano M, Katayose Y, Ashikari M, Yamanouchi U, Monna L, Fuse T, Baba T, Yamamoto K, Umehara Y, Nagamura Y, Sasaki T. Hd1, a major photoperiod sensitivity quantitative trait locus in rice, is closely related to the Arabidopsis flowering time gene CONSTANS. Plant Cell, 2000, 12: 2473-2484

[41]Kojima S, Takahashi Y, Kobayashi Y, Monna L, Sasaki T, Araki T, Yano M. Hd3a, a rice ortholog of the ArabidopsisFT gene, promotes transition to flowering downstream of Hd1 under short-day conditions. Plant Cell Physiol, 2002, 43: 1096-1105

[42]Takahashi Y, Shomura A, Sasaki T, Yano M. Hd6, a rice quantitative trait locus involved in photoperiod sensitivity, encodes the a subunit of protein kinase CK2. Proc Natl Acad Sci USA, 2001, 98: 7922-7927

[43]Xue W, Xing Y, Weng X, Zhao Y, Tang W, Wang L, Zhou H, Yu S, Xu C, Li X, Zhang Q. Natural variation in Ghd7 is an important regulator of heading date and yield potential in rice. Nat Genet, 2008, 40: 761-767
Liu P Y, Zhu J, Lu Y. Impacts of QTL ´ environment interactions on genetic response to marker-assisted selection. Acta Genet Sin, 2006, 33: 63-71
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