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利用来自多个栽培稻供体的单片段代换系在七个种植季节对控制种子休眠的QTL进行代换作图。

Substitution mapping of QTLs controlling seed dormancy using single segment substitution lines derived from multiple cultivated rice donors in seven cropping seasons.

作者信息

Zhou Yuliang, Xie Yuehua, Cai Jinling, Liu Chunbao, Zhu Haitao, Jiang Ru, Zhong Yueying, Zhang Guoliang, Tan Bin, Liu Guifu, Fu Xuelin, Liu Ziqiang, Wang Shaokui, Zhang Guiquan, Zeng Ruizhen

机构信息

State Key Laboratory for Conservation and Utilization of Subtropical Agro-Bioresources and Guangdong Key Laboratory of Plant Molecular Breeding, South China Agricultural University, Guangzhou, 510642, China.

出版信息

Theor Appl Genet. 2017 Jun;130(6):1191-1205. doi: 10.1007/s00122-017-2881-9. Epub 2017 Mar 10.

DOI:10.1007/s00122-017-2881-9
PMID:28283703
Abstract

A permanent advanced population containing 388 SSSLs was used for genetic analysis of seed dormancy; 25 QTLs including eight stable, six major and five new were identified. Seed dormancy (SD) is not only a complex biological phenomenon, but also a key practical problem in agricultural production closely related with pre-harvest sprouting (PHS). However, the genetic mechanisms of SD remain elusive. Here, we report the genetic dissection of SD in rice using 388 single segment substitution lines (SSSLs) derived from 16 donor parents. Continuous variation and positive correlations in seed germination percentages were observed in seven seasons. Genetic analysis revealed the narrow sense heritability in different seasons varied from 31.4 to 82.2% with an average value of 56.8%. In addition, 49 SSSLs exhibited significant difference to recipient parent HJX74 on SD in at least two seasons, and 12 of them were stably identified with putative QTLs in all of their corresponding cropping seasons. Based on substitution mapping, a total of 25 dormancy QTLs were detected on 11 chromosomes except the chromosome 5 with an interval length of 1.1 to 31.3 cM. The additive effects of these QTLs changed from -0.31 to -0.13, and the additive effect contributions ranged from 16.7 to 41.4%. Six QTLs, qSD3-2, qSD4-1, qSD7-1, qSD7-2, qSD7-3 and qSD11-2, showed large additive effect contributions (≥30%). Five QTLs, qSD3-3, qSD7-1, qSD7-4, qSD9-1 and qSD10-1, may represent novel ones. Furthermore, linkage and recombinant analysis delimited qSD7-1 to a locus 1.5 cM away from marker Oi2 and a 355-kb fragment flanked by RM1134 and Ui159, respectively. Taken together, this work conducts a comprehensive genetic dissection of SD and will provide more selections for breeding elite PHS-resistant rice varieties.

摘要

一个包含388个单片段代换系(SSSL)的永久高代群体被用于种子休眠的遗传分析;共鉴定出25个数量性状基因座(QTL),其中包括8个稳定的、6个主效的和5个新的QTL。种子休眠(SD)不仅是一种复杂的生物学现象,也是农业生产中与收获前发芽(PHS)密切相关的一个关键实际问题。然而,SD的遗传机制仍不清楚。在此,我们报道了利用来自16个供体亲本的388个单片段代换系(SSSL)对水稻SD进行的遗传剖析。在七个季节中观察到种子发芽率的连续变异和正相关。遗传分析表明,不同季节的狭义遗传力在31.4%至82.2%之间变化,平均值为56.8%。此外,49个SSSL在至少两个季节中与受体亲本HJX74在SD上表现出显著差异,其中12个在其所有相应种植季节中均被稳定鉴定出具有假定的QTL。基于代换作图,在除第5染色体外的11条染色体上共检测到25个休眠QTL,区间长度为1.1至31.3 cM。这些QTL的加性效应在-0.31至-0.13之间变化,加性效应贡献率在16.7%至41.4%之间。6个QTL,qSD3-2、qSD4-1、qSD7-1、qSD7-2、qSD7-3和qSD11-2,表现出较大的加性效应贡献率(≥30%)。5个QTL,qSD3-3、qSD7-1、qSD7-4、qSD9-1和qSD10-1,可能代表新的QTL。此外,连锁和重组分析将qSD7-1定位到一个距标记Oi2 1.5 cM的位点以及一个分别由RM1134和Ui159侧翼的355-kb片段。综上所述,这项工作对SD进行了全面的遗传剖析,并将为培育抗PHS的优良水稻品种提供更多选择。

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