Chengdu Institute of Biology, Chinese Academy of Sciences, Chengdu, 610041, Sichuan, People's Republic of China.
University of Chinese Academy of Sciences, Beijing, People's Republic of China.
Theor Appl Genet. 2022 Jul;135(7):2543-2554. doi: 10.1007/s00122-022-04137-5. Epub 2022 Jun 13.
Morphological, genetic and transcriptomic characterizations of an EMS-induced wheat paired spikelets (PS) mutant were performed. A novel qualitative locus WPS1 on chromosome 1D was identified. Grain yield of wheat is significantly associated with inflorescence or spike architecture. However, few genes related to wheat spike development have been identified and their underlying mechanisms are largely unknown. In this study, we characterized an ethyl methanesulfonate (EMS)-induced wheat mutant, wheat paired spikelets 1 (wps1). Unlike a single spikelet that usually develops at each node of rachis, a secondary spikelet appeared below the primary spikelet at most of the rachis nodes of wps1. The microscope observation showed that the secondary spikelet initiated later than the primary spikelet. Genetic analysis suggested that the PS of wps1 is controlled by a single dominant nuclear gene, designated WHEAT PAIRED SPIKELETS 1 (WPS1). Further RNA-seq based bulked segregant analysis and molecular marker mapping localized WPS1 in an interval of 208.18-220.92 Mb on the chromosome arm 1DL, which is different to known genes related to spike development in wheat. By using wheat omics data, TraesCS1D02G155200 encoding a HD-ZIP III transcription factor was considered as a strong candidate gene for WPS1. Transcriptomic analysis indicated that PS formation in wps1 is associated with auxin-related pathways and may be regulated by networks involving TB1, Ppd1, FT1, VRN1, etc. This study laid the solid foundation for further validation of the causal gene of WPS1 and explored its regulatory mechanism in PS formation and inflorescence development, which may benefit to kernel yield improvement of wheat based on optimization or design of spike architecture in the future.
我们对 EMS 诱导的小麦双小穗突变体进行了形态学、遗传学和转录组学分析。鉴定了一个位于 1D 染色体上的新的定性基因座 WPS1。小麦的籽粒产量与花序或穗结构密切相关。然而,与小麦穗发育相关的基因很少被鉴定出来,其潜在机制在很大程度上尚不清楚。在本研究中,我们对乙基磺酸甲酯(EMS)诱导的小麦突变体小麦双小穗 1(wps1)进行了研究。不同于通常在小穗轴每个节上发育的单个小穗,wps1 的大多数小穗轴节上,次级小穗出现在初级小穗的下方。显微镜观察表明,次级小穗的起始时间晚于初级小穗。遗传分析表明,wps1 的双小穗由一个显性核基因控制,命名为 WHEAT PAIRED SPIKELETS 1(WPS1)。进一步的 RNA-seq 基于 bulked segregant 分析和分子标记作图将 WPS1 定位在染色体臂 1DL 上 208.18-220.92 Mb 的区间内,这与小麦中已知的与穗发育相关的基因不同。利用小麦组学数据,TraesCS1D02G155200 编码一个 HD-ZIP III 转录因子被认为是 WPS1 的一个强候选基因。转录组分析表明,wps1 中的双小穗形成与生长素相关途径有关,可能受到涉及 TB1、Ppd1、FT1、VRN1 等的网络调控。本研究为进一步验证 WPS1 的因果基因奠定了基础,并探索了其在双小穗形成和花序发育中的调控机制,这可能有助于未来基于穗结构的优化或设计来提高小麦的籽粒产量。
