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定位控制油菜角果败育和每角粒数的主效位点并进行候选基因分析

Fine mapping and candidate gene analysis of a major locus controlling ovule abortion and seed number per silique in Brassica napus L.

机构信息

National Key Laboratory of Crop Genetic Improvement, Huazhong Agricultural University, Wuhan, 430070, People's Republic of China.

出版信息

Theor Appl Genet. 2021 Aug;134(8):2517-2530. doi: 10.1007/s00122-021-03839-6. Epub 2021 Apr 24.

DOI:10.1007/s00122-021-03839-6
PMID:33895853
Abstract

A major QTL controlling ovule abortion and SN was fine-mapped to a 80.1-kb region on A8 in rapeseed, and BnaA08g07940D and BnaA08g07950D are the most likely candidate genes. The seed number per silique (SN), an important yield determining trait of rapeseed, is the final consequence of a complex developmental process including ovule initiation and the subsequent ovule/seed development. To explore the genetic mechanism regulating the natural variation of SN and its related components, quantitative trait locus (QTL) mapping was conducted using a doubled haploid (DH) population derived from the cross between C4-146 and C4-58B, which showed significant differences in SN and aborted ovule number (AON), but no obvious differences in ovule number (ON). QTL analysis identified 19 consensus QTLs for six SN-related traits across three environments. A novel QTL on chromosome A8, un.A8, which associates with multiple traits, except for ON, was stably detected across the three environments. This QTL explained more than 50% of the SN, AON and percentage of aborted ovules (PAO) variations as well as a moderate contribution on silique length (SL) and thousand seed weight (TSW). The C4-146 allele at the locus increases SN and SL but decreases AON, PAO and TSW. Further fine mapping narrowed down this locus into an 80.1-kb interval flanked by markers BM1668 and BM1672, and six predicted genes were annotated in the delimited region. Expression analyses and DNA sequencing showed that two homologs of Arabidopsis photosystem I subunit F (BnaA08g07940D) and zinc transporter 10 precursor (BnaA08g07950D) were the most promising candidate genes underlying this locus. These results provide a solid basis for cloning un.A8 to reduce the ovule abortion and increase SN in the yield improvement of rapeseed.

摘要

一个控制胚珠败育和 SN 的主要 QTL 被精细定位到油菜 A8 上的 80.1-kb 区域,BnaA08g07940D 和 BnaA08g07950D 是最有可能的候选基因。每角粒数 (SN) 是油菜的一个重要产量决定性状,是包括胚珠起始和随后的胚珠/种子发育在内的复杂发育过程的最终结果。为了探讨调节 SN 及其相关组分自然变异的遗传机制,使用来自 C4-146 和 C4-58B 杂交的加倍单倍体 (DH) 群体进行了数量性状位点 (QTL) 作图,C4-146 和 C4-58B 在 SN 和败育胚珠数 (AON) 上表现出显著差异,但在胚珠数 (ON) 上没有明显差异。QTL 分析在三个环境中鉴定了 19 个与六个 SN 相关性状相关的一致性 QTL。在三个环境中稳定检测到一个位于染色体 A8 上的新 QTL un.A8,该 QTL 与多个性状相关,除了 ON。该 QTL 解释了超过 50%的 SN、AON 和败育胚珠百分比 (PAO) 的变异以及对长角果长度 (SL) 和千粒重 (TSW) 的适度贡献。该位点 C4-146 等位基因增加了 SN 和 SL,但减少了 AON、PAO 和 TSW。进一步的精细定位将该位点缩小到一个 80.1-kb 的区间,该区间由标记 BM1668 和 BM1672 侧翼,在所限定的区域中注释了六个预测基因。表达分析和 DNA 测序表明,拟南芥光系统 I 亚基 F 的两个同源物 (BnaA08g07940D) 和锌转运蛋白 10 前体 (BnaA08g07950D) 是该位点最有希望的候选基因。这些结果为克隆 un.A8 提供了坚实的基础,以减少油菜胚珠败育并提高产量。

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