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Acta Agron Sin ›› 2009, Vol. 35 ›› Issue (1): 41-47.doi: 10.3724/SP.J.1006.2009.00041

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

Epistatic Effects and QE Interaction Effects of QTLs for Protein Content in Soybean

SHAN Da-Peng1,2,4,ZHU Rong-Seng5,*,CHEN Li-Jun6,QI Zhao-Ming2,HU Guo-Hua1,3,*,CHEN Qing-Shan2,*   

  1. 1Crop Research and Breeding Center of Land-Reclamation,Harbin 150090,China;2 Soybean Research Institute, Northeast Agricultural Universtity,Harbin 150030,China;3The National Research Center of Soybean Engine ering and Technology,Harbin 150050,China; 4Heilongjiang Academy of Agricultural Sciences,Suihua Institute,Suihua 152052,China;5College of Science,Northeast Agricultural University,Harbin 150030,China;6 Heilongjiang Academy of Agricultural Sciences Crop Breeding Institute, Harbin 150086,China
  • Received:2008-04-20 Revised:2008-07-14 Online:2009-01-12 Published:2008-11-17
  • Contact: CHEN Qing-Shan

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Abstract:

Soybean [Glycine max (L). Merr.], widely grown in United States, Brazil, Argentina, and China, is one of the plant protein source. Protein content in soybean is a quantitative trait controlled by multiple genes, and Currently, SoyBase (2007) documented at least 76 QTL associated with protein content that have been mapped in many different populations and environments. The objective of the paper was to investigate epistatic effects and QE interaction effects of QTLs for protein content by mixed linear model. QTLs for soybean protein content were detected in a five-year experiment with the recombination inbred lines (RIL) population derived from a cross between Charleston and Dongnong 594. Ten QTLs with additive effects for protein content were mapped in the linkage groups B2, C2, D1a, E and N, one of which was the positive effect contributed by Charleston, the others of which were the negative effects donated by Dongnong 94. Fifteen QTLs pairs with epistatic effects for protein content in the RIL were detected, accounting for 13.57% of the general phenotypic variation. There existed interaction between 9 QTLs and environment, and the general contribution to protein content was 4.47%.

Key words: Soybean, Protein content, Mixed linear model, QTL×environment interaction, Epistatic effects

[1]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
[2]Wu X-L(吴晓雷), Wang Y-J(王永军), He C-Y(贺超英), Chen S-Y(陈受宜), Gai J-Y(盖钧镒), Wang X-C(王学臣). QTLs mapping of some agronomic traits of soybean. Acta Genet Sin (遗传学报), 2001, 28(10): 947–955(in Chinese with English abstract)
[3]Brummer E C, Graef G L, Orf J, Wilcox J R, Shoemaker R C. Mapping QTL for seed protein and oil content in English soybean population. Crop Sci, 1997, 37: 370–378
[4]Chapman A, Pantalone V R, Ustun A, Allen F L, Landau-Ellis D, Trigiano R N, Gressoff P M. Quantitative trait loci for agronomic and seed quality traits in an F2 and F4:6 soybean population. Euphytica, 2003, 129: 387–393
[5]Hyten D L, Pantalone V R, Sams C E, Saxton A M, Landau-Ellis D, Stefaniak T R, Schmidt M E. Seed quality QTL in a prominent soybean population. Theor Appl Genet, 2004, 109: 552–561
[6]Panthee D R, Pantalone V R, West D R, Saxton A M, Sams C E. Quantitative trait loci for protein and oil concentration, and seed size in soybean. Crop Sci, 2005, 45: 2015–2022
[7]Zhu J(朱军). General genetic models and new analysis methods for quantitative traits. J Zhejiang Agric Univ (浙江农业大学学报), 1994, 20(6): 551–559(in Chinese with English abstract)
[8]Wang D L, Zhu J, Li Z K, Paterson A H. Mapping QTLs with epistatic effects and QTL-environment interactions by mixed linear model approaches. Theor Appl Genet, 1999, 99: 1255–1264
[9]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 with English abstract)
[10]Li Z-F(李泽福), Zhou T(周彤), Zheng T-Q(郑天清), Luo L-G(罗林广), Xia J-F(夏加发), Zhai H-Q(翟虎渠), Wan J-M(万建民). Analysis of QTL×environment interactions for heading date of rice (Oryza sativa L.). Acta Agron Sin (作物学报), 2002, 28(6): 771–776(in Chinese with English abstract)
[11]Gao Y-M(高用明), Zhu J(朱军), Song Y-S(宋佑胜), He C-X(何慈信), Shi C-H(石春海), Xing Y-Z(邢永忠). Use of permanent F2 population to analyze epistasis and their interaction effects with environments for QTLs controlling heading date in Rice. Acta Agron Sin (作物学报), 2004, 30(9): 849–854(in Chinese with English abstract)
[12]Zhan J-P(张焦平), Jiang L-R(江良荣), Huang J-X(黄建勋), Zhang K(张凯), Wang H-C(王侯聪), Huang Y-M(黄育民). Analysis of epistatic and QE interaction effects of QTL controlling heading date in rice (Oryza sativa L.). Mol Plant Breed (分子植物育种), 2006, 4(3): 351–357(in Chinese with English abstract)
[13]Cao L-Y(曹立勇), Zhan X-D(占小登), Zhuang J-Y(庄杰云), Zheng K-L(郑康乐), Cheng S-H(程式华). QTL mapping and epistasis analysis for yield components in a RIL population of rice (Oryza sativa L. subsp. indica). Sci Agric Sin (中国农业科学), 2003, 36(11): 1241–1247(in Chinese with English abstract)
[14]Wang D-L(王道龙), Zhu J(朱军), Li Z-K(黎志康), Paterson A H. QTLMaper1.6. (2004-12)
[2005-2]. http://ibi.zju.edu.cn/software/qtlmapper/index.htm
[15]Zhang Z-C(张忠臣), Zhan X-L(战秀玲), Chen Q-S(陈庆山), Teng W-L(腾卫丽), Yang Q-K(杨庆凯), Li W-B(李文滨). QTL mapping of seed oil and protein content of soybean. Soybean Sci (大豆科学), 2004, 23(2): 81–85(in Chinese with English abstract)
[16]Jansen R C, Van Ooijien J M, Stam P. Genotype-by-environment interaction in genetic mapping of multiple quantitative trait loci. Theor Appl Genet, 1995, 91: 33–37
[17]Orf J H, Chase K, Jarvik T, Mansur L M, Cregan P B, Adler F R, Lark K G. Genetics of soybean agronomic traits: I. Comparison of three related recombinant inbred populations. Crop Sci, 1999, 39: 1642–1651
[18]Specht J E, Chase K, Macrander M, Graef B L, Chung J, Markwell J P, Germann M, Orf J H, Lark K G. Soybean response to water: A QTL analysis of drought tolerance. Crop Sci, 2001, 41: 493–509
[19]Guo L-B(郭龙彪), Luo L-J(罗利军), Xing Y-Z(邢永忠), Xu C-G(徐才国), Mei H-W(梅捍卫), Wang Y-P(王一平), Zhong D-B(钟代彬), Qian Q(钱前), Ying C-S(应存山), Shi C-H(石春海). Dissection of QTLs in two years for important agronomic traits in rice (Oryza sativa L.). Chin J Rice Sci (中国水稻科学), 2003, 17(3): 211–218(in Chinese with English abstract)
[20]Bao J-S(包劲松), Bao Z-Y(包志毅), He P(何平), Zhu L-H(朱立煌). Detection of QTLs controlling heading date in the process of rice development at two environments. J Zhejiang Univ (浙江大学学报), 2002, 28(1): 27–32(in Chinese with English abstract)
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