Yang Cong, Tang Dengguo, Qu Jingtao, Zhang Ling, Zhang Lei, Chen Zhengjie, Liu Jian
Maize Research, Sichuan Agricultural University, Wenjiang, 611130, Sichuan, China.
Theor Appl Genet. 2016 Nov;129(11):2191-2209. doi: 10.1007/s00122-016-2767-2. Epub 2016 Aug 22.
A set of RIL population was used to detect QTL associated with the sizes of eight consecutive leaves, across different environments, and ten QTL clusters were identified as main QTLs. One of the important parameters of the maize leaf architecture that affects light penetration into the canopy, leaf size, has long attracted breeders' attention for optimizing the plant type of maize and for maximizing the grain yield (GY). In this study, we used 253 RIL lines derived from a cross between B73 and SICAU1212 to investigate the leaf widths (LWs), leaf lengths (LLs), and leaf areas (LAs) of eight consecutive leaves of maize below the tassel and GY across different environments and to identify quantitative traits loci (QTLs) controlling the above-mentioned traits, using inclusive interval mapping for single-environment analysis plus a mixed-model-based composite interval mapping for joint analysis. A total of 171 and 159 putative QTLs were detected through these two mapping methods, respectively. Single-environment mapping revealed that 39 stable QTLs explained more than 10 % of the phenotypic variance, and 35 of the 39 QTLs were also detected by joint analysis. In addition, joint analysis showed that nine of the 159 QTLs exhibited significant QTL × environment interaction and 15 significant epistatic interactions were identified. Approximately 47.17 % of the QTLs for leaf architectural traits in joint analysis were concentrated in ten main chromosomal regions, namely, bins 1.07, 2.02, 3.06, 4.09, 5.01, 5.02, 5.03-5.04, 5.07, 6.07, and 8.05. This study should provide a basis for further fine-mapping of these main genetic regions and improvement of maize leaf architecture.
利用一套重组自交系(RIL)群体,在不同环境下检测与连续八片叶子大小相关的数量性状基因座(QTL),并鉴定出10个QTL簇作为主要QTL。影响光线穿透冠层的玉米叶片结构的重要参数之一——叶片大小,长期以来一直吸引着育种者的关注,以优化玉米株型并最大化籽粒产量(GY)。在本研究中,我们使用由B73和SICAU1212杂交产生的253个RIL系,来研究雄穗以下玉米连续八片叶子的叶宽(LW)、叶长(LL)和叶面积(LA)以及不同环境下的GY,并使用单环境分析的包容性区间作图法和联合分析的基于混合模型的复合区间作图法来鉴定控制上述性状的QTL。通过这两种作图方法分别检测到总共171个和159个推定QTL。单环境作图显示,39个稳定QTL解释了超过10%的表型变异,联合分析也检测到了这39个QTL中的35个。此外,联合分析表明,159个QTL中有9个表现出显著的QTL×环境互作,并鉴定出15个显著的上位性互作。联合分析中约47.17%的叶片结构性状QTL集中在10个主要染色体区域,即第1.07、2.02、3.06、4.09、5.01、5.
