State Key Laboratory of Crop Stress Biology for Arid Areas, College of Agronomy, Northwest A&F University, Yangling 712100, China.
State Key Laboratory of Crop Stress Biology for Arid Areas, College of Agronomy, Northwest A&F University, Yangling 712100, China; Shaanxi Research Station of Crop Gene Resources and Germplasm Enhancement, Ministry of Agriculture, Yangling 712100, China.
Plant Sci. 2022 Oct;323:111392. doi: 10.1016/j.plantsci.2022.111392. Epub 2022 Jul 20.
Improving yield potential is a major goal of wheat breeding that depends on identifying key genetic loci. In this study, two residual heterozygous line RHL351- and RHL78-derived populations were employed for genetic linkage map construction and QTL detection. Two genetic populations indicated a robust grain-size QTL between Marker6 and Marker10. It covered a 95.54-99.38 Mb physical interval and was named Qpleio.nwafu.3D, containing the candidate gene Tasg (TraesCS3D02G137200). Intriguingly, RNA-seq analysis and sequencing revealed two different allelic variants in Tasg, named Tasg-D1 (G>A) and Tasg-D2 (C>G), respectively. Although the relationship between Tasg-D1 and grain size had been demonstrated previously, here we provided the first genetic evidence that C/G allelic variation in Tasg-D2 was associated with grain shape and size through a newly developed dCAPS marker. In addition, transcriptome comparison indicated that Tasg-D1/2 might primarily contribute to significant expression differences in brassinolide (BR) metabolism-related genes rather than those related to BR responses in developing grains and spikes. Our study provided new evidence and a breeder-friendly dCAPS marker for improving grain size through the selection of Tasg, as well as a basis to understand Tasg function in the future.
提高产量潜力是小麦育种的主要目标,这取决于鉴定关键的遗传基因座。在这项研究中,利用两个剩余杂合系 RHL351-和 RHL78 衍生群体进行遗传连锁图谱构建和 QTL 检测。两个遗传群体在标记 6 和标记 10 之间显示出一个稳健的粒型 QTL。它覆盖了 95.54-99.38 Mb 的物理区间,被命名为 Qpleio.nwafu.3D,包含候选基因 Tasg(TraesCS3D02G137200)。有趣的是,RNA-seq 分析和测序揭示了 Tasg 中的两个不同等位基因变体,分别命名为 Tasg-D1(G>A)和 Tasg-D2(C>G)。虽然 Tasg-D1 与粒大小之间的关系以前已经得到证明,但在这里,我们提供了第一个遗传证据,表明 Tasg-D2 中的 C/G 等位基因变异与粒形和大小有关,这是通过新开发的 dCAPS 标记实现的。此外,转录组比较表明,Tasg-D1/2 可能主要导致油菜素内酯(BR)代谢相关基因的显著表达差异,而不是与发育中的谷物和穗中 BR 反应相关的基因。我们的研究为通过 Tasg 的选择来提高粒大小提供了新的证据和一个适合育种者的 dCAPS 标记,以及未来理解 Tasg 功能的基础。
