图1. 玉米自交系JING724 和JING724A1 茎秆断裂相关的茎秆结构与特征
内部茎结构显微术和X射线微型计算机断层扫描显示,JING724A1具有更多的维管束和更厚的厚壁组织(图2)。另外经测定,JING724A1中总可溶性糖含量,尤其是葡萄糖成分,显著高于JING724。
图2. JING724 与JING724A1 的维管解剖分析
利用源于JING724与JING724A1杂交后得到的F2:3群体,进行大量的茎秆断裂角性状分离分析,检测到一个QTL(数量性状位点)定位于Chr3: 14.00-19.28Mb。通过转录组数据分析以及Δ (SNP-index)方法,作者鉴定出两个与高茎秆断裂角显著相关的候选基因,分别编码一个RING/U-box超家族蛋白(Zm00001d039769)与一个MADS-box转录因子54(Zm00001d039913)。从这两个候选基因设计的两个KASP标记也显示与茎杆断裂角有显著相关性(图3)。
图3. 候选基因的相对表达水平及其KASP 标记
综上,该研究表明玉米节间形状和葡萄糖含量与茎秆柔韧性有关,且检测到两个可能与茎杆断裂角性状相关的基因。这些新的生理表型和相关性状遗传位点的鉴定将为理解作物倒伏的遗传机制提供理论基础,并为选择具有较好柔韧性和较强抗倒伏性状的玉米品种提供便利。
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