施氮与不施氮条件下玉米开花期相关性状的 QTL 定位

郭向阳; 陈建军; 卫晓轶; 祝云芳; 王安贵; 刘鹏飞; 汤继华; 陈泽辉

doi:10.11674/zwyf.16282

施氮与不施氮条件下玉米开花期相关性状的 QTL 定位

QTL mapping of flowering related traits of maize with and without nitrogen application

摘要

摘要:
目的探究施氮与不施氮对玉米开花期相关性状变异的影响，并定位相关 QTLs。

方法以玉米的骨干自交系综 3 为供体亲本，许 178 为受体亲本，通过杂交、回交和分子标记辅助选择的方法，构建了一套以许 178 为遗传背景的综 3 染色体单片段代换系 (SSSLs) 群体，其中包含 160 个单片段代换系。以这套 SSSLs 以及许 178 为材料，采用裂区试验设计，在施氮 (N+) 和不施氮 (N–) 条件下，通过一年三点 (贵州贵阳、德江和云南罗平) 的表型评价，利用复合区间作图法对玉米散粉期、吐丝期和散粉–吐丝间隔期 (ASI) 3 个开花期相关性状进行 QTL 定位。

结果在基因组范围内，2 种氮处理条件下共定位到 54 个开花期相关性状 QTLs，主要定位在第 1、3、6、9 和 10 染色体上。其中 5 个 QTLs 在 3 个环境中均被检测到。施氮条件下，吐丝期 (DTS) 相关位点qDTS9a，位于第 9 染色体，可解释表型变异的 3.05%；吐丝散粉间隔期 (ASI) 相关位点qASI10a，位于第 10 染色体，可解释表型变异的 30.74%。不施氮条件下，散粉期 (DTP) 相关位点qDTP9，可解释表型变异的 3.43%；吐丝期相关位点qDTS9a，位于第 9 染色体，可解释表型变异的 4.08%；ASI 相关位点qASI10，位于第 10 染色体，可解释表型变异的 50.28%。对不同处理条件下的定位结果比较发现，不施氮条件下检测到的 QTLs 数目显著高于施氮条件下的检测数量。

结论不同氮素处理下存在一些共有的控制玉米开花期相关的遗传区段，分别位于 Bin9.02 (umc1170-umc1636-bnlg1401-umc1271) 和 Bin10.04 (umc1077-umc1053-umc2350)，这些区段可能在玉米氮素吸收、转运和利用过程中起重要作用，可作为下一步精细定位和图位克隆玉米开花期相关基因的重要候选区域。

Abstract:
Objectives The purpose of this study was to dissect variation of maize flowering-related traits under two conditions of nitrogen applied normally or none, and to map the related QTLs.

Methods One panel included 160 Single Segment Substitution Lines (SSSLs) was constructed by using foundation parental lines of Zong3 and Xu178 as donor and receptor parents, respectively. The panel was treated with two conditions of nitrogen applied normally or none by using the split-plot experiment design, and the nitrogen treatment was set as the main plot and genotypes were set as the sub-plots under three environments, including Guiyang, Dejiang in Guizhou Province and Luoping in Yunnan Province. Three flowering-related traits, including day to pollen (DTP), day to silk (DTS) and anthesis-silking interval (ASI), were investigated in one treatment.

Results The results showed that across the whole genome, about 54 flowering-related traits QTLs were identified under the two N treatments, which were mainly located on the chromosome 1, 3, 6, 9 and 10, among them, 3 QTLs were common under three environments. Under N⁺ treatment, QTLqDTS9a controlling day to silling (DTS) was found which was located on chromosome 9, and could explain 3.05% genetic variation; another QTLqASI10a controlling the ASI was also found, which located on chromosome 10, and could explain 30.74% genetic variation. Under N– conditions, QTLqDTP9 was identified, which could explain 3.43% genetic variation of DTP;qDTS9a related withDTS was found, which located on chromosome 9, and could explain 4.08% genetic variation; QTLqASI10 was also identified, which located on chromosome 10, and could explain 50.28% genetic variation. Comparing between N+ and N– conditions showed that, the QTLs identified under N– was much more than those under N+ treatment.

Conclusions Two commonly QTLs are existed in the two nitrogen treatments, one isqDTS9a, which is located on Bin9.02, with flank markers of umc1170-umc1636-bnlg1401-umc1271, and the other isqASI10a, which is located on Bin 10.04, with flank markers of umc1077-umc1053-umc2350. These loci may play important role in nitrogen absorbing, transporting, and utilization during maize development, and served as candidate loci in further map-based cloning of maize flowering-related traits.

HTML全文

参考文献(30)

施引文献

资源附件(0)