水稻恢复系泸恢8258产量性状的QTL定位

doi:10.3969/j.issn.1674-7968.2020.04.003

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摘要恢复系是三系杂交稻(Oryza sativa)重要的亲本之一,挖掘其高产基因,对提高杂交稻的产量水平具有重要意义。本研究利用水稻三系恢复系'泸恢8258'与'扬恢34'构建重组自交系群体(recombinant inbred lines, RIL)作为材料,在四川德阳、遂宁、泸州3个环境下,考察了单株生物量、收获指数、单株产量、有效穗、每穗颖花数、每穗实粒数、结实率、千粒重8个产量相关的性状。在构建了一张包含184个DNA标记的遗传连锁图谱基础上,利用Windows QTL Cartographer 2.5检测产量相关性状的数量性状位点(quantitative trait locus, QTL),8个性状在3个环境下共检测到62个QTL,分布在12条染色体上。共有2个QTL在3个环境下同时检测到,分别是控制千粒重的qTGW3和控制每穗实粒数的qFGP6-1,增效等位基因来自'泸恢8258',对表型的贡献率分别为5.92% (德阳)、7.79% (遂宁)、19.04% (泸州)和8.80% (德阳)、10.90% (遂宁)、4.96% (泸州)。共有17个QTL在其中的两个环境下被检测到,分别是控制单株生物量的qBYP6-2、qBYP9,控制收获指数的qHI3-1、qHI3-2、qHI12,控制单株产量的qYP3-2、qYP12,控制单株有效穗的qEP2-1、qEP9-2,控制每穗颖花数的qSP6-1、qSP12,控制每穗实粒数qFGP2-1、qFGP2-2、qFGP6-2、qFGP12-2,控制结实率的qSSR2、qSSR6-1。在两个环境下检测到的17个QTL中,增效等位基因来自'泸恢8258'的有11个,分别是qHI3-1、qHI3-2、qBYP6-2、qBYP9、qYP3-2、qEP2-1、qEP9-2、qSSR2、qSSR6-1、qSP6-1、qFGP6-2,其他6个QTL增效等位基因来自'扬恢34'。8个性状检测到的QTL中,除每穗颖花数和每穗实粒数外,其他性状检测到的QTL增效等位基因大多来自'泸恢8258'。这些研究结果为水稻产量相关性状的精细定位、克隆、分子标记辅助选择提供理论和技术支撑。

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	曹应江
	游书梅
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	张涛
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	杨乾华
	万先齐
	李昭祥
	高磊
	郑家奎

关键词 ：水稻, 恢复系, 产量性状, QTL定位, '泸恢8258'

Abstract：Restorer lines is one of the important parents of three-line hybrid rice (Oryza sativa). Excavating its high-yielding genes is great important for improving the yield of hybrid rice. A recombinant inbred lines (RIL) population derived from a cross-combination of 'Luhui8258' and 'Yanghui34'. The RIL and 2 parents were grown under 3 different environments including Deyang, Suining and Luzhou of Sichuan province, and 8 yield traits including biological yield per plant (BYP), harvest index (HI), yield per plant (YP), effective panicles per plant (EP), spikelet per panicle (SP), full grain per panicle (FGP), seed setting rate (SSR, as a percentage), 1000-grain weight (TGW) were investigated. On the basis of constructing genetic linkage map consisted 184 DNA markers, a total of 62 QTLs for yield-related traits distributing on all of the 12 chromosomes were identified. Among them, 2 QTLs synergistic alleles were derived from 'Luhui8258' were detected repeatedly in 3 environments, namely, it were qTGW3 and qFGP6-1, with the contribution rate of 5.92% (Deyang), 7.79% (Suining), 19.04% (Luzhou) and 8.80% (Deyang), 10.90% (Suining), 4.96% (Luzhou), respectively. In addition, 17 yield-related QTL detected in two of these environments, included qBYP6-2, qBYP9 (QTL for BYP), qHI3-1, qHI3-2, qHI12 (for HI), qYP3-2, qYP12 (for YP), qEP2-1, qEP9-2 (for EP), qSP6-1、qSP12 (for SP), qFGP2-1, qFGP2-2, qFGP6-2, qFGP12-2 (for FGP) , qSSR2, qSSR6-1 (for SSR). Among them, 11 QTL synergistic alleles were derived from 'Luhui8258', including qHI3-1, qHI3-2, qBYP6-2, qBYP9, qYP3-2, qEP2-1, qEP9-2, qSSR2, qSSR6-1, qSP6-1, qFGP6-2, the other 6 QTL synergistic alleles were derived from 'Yanghui 34'. This research provides the basis and technical support for fine mapping, cloning and molecular marker-assisted selection of rice yield-related traits in near future breeding program.

Key words： Rice Restorer line Yield related trait QTL mapping Luhui 8258

收稿日期: 2019-08-21

ZTFLH:	S511.2+1
	S336

基金资助:国家重点研发计划(2017YFD0100205; 2016YFD0101101); 四川省科技支撑计划(2016NYZ0028)

通讯作者: ** zheng6102@126.com

作者简介: *同等贡献作者

引用本文:

曹应江, 游书梅, 蒋开锋, 张涛, 杨莉, 杨乾华, 万先齐, 李昭祥, 高磊, 郑家奎. 水稻恢复系泸恢8258产量性状的QTL定位[J]. 农业生物技术学报, 2020, 28(4): 594-604.
CAO Ying-Jiang, YOU Shu-Mei, JIANG Kai-Feng, ZHANG Tao, YANG Li, YANG Qian-Hua, WAN Xian-Qi, LI Zhao-Xiang, GAO-Lei, Zheng Jia-Kui. QTL Mapping for Yield-related Traits of Rice Restorer Line Luhui8258 (Oryza sativa). 农业生物技术学报, 2020, 28(4): 594-604.

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http://journal05.magtech.org.cn/Jwk_ny/CN/10.3969/j.issn.1674-7968.2020.04.003 或 http://journal05.magtech.org.cn/Jwk_ny/CN/Y2020/V28/I4/594

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