Changes in plant hormones and transcriptome behind the three pistils formation in wheat

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-10-21 DOI:10.1016/j.sajb.2024.10.034
Tao Li , Yichao Wu , Ruiyang Lan , Mingli Liao , Zhenyong Chen , Shuhong Wei , Zhengsong Peng , Zaijun Yang
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Abstract

Auxin and gibberellin significantly influence plant pistil development, but their specific roles in the formation of the three pistils trait in wheat are still unclear. To investigate the effects of auxin and gibberellin on the three pistils trait in wheat, we measured the contents of auxin and gibberellin in young spikes from three pistils wheat (TP and CM28TP) and single pistil wheat (CM28) at three stages. We also performed transcriptome sequencing. A total of 14 different auxins and 7 different gibberellins were detected from all samples, among which the contents of IAA-Glc and GA19 showed significant differences among different samples. The transcriptome sequencing yielded over 1.28 billion clean reads and 3.2 million transcripts. A total of 2,018 and 6,163 differentially expressed genes (DEGs) were identified from the comparisons of CM28 vs CM28TP and CM28 vs TP, respectively. Through the correlation analysis between auxin, gibberellin, and DEGs, 4 ARF genes, 3 AMI genes, and 3 DELLA genes were identified. These results suggest that IAA-Glc, GA19, and the 10 key genes were crucial factors in the formation of three pistils trait. Further analysis showed that ARF expression level and GA contents were negatively correlated with three pistils trait, while DELLA expression level and auxin contents were positively correlated. This study suggests that auxin and gibberellin signal transduction have an antagonistic relationship during wheat flower development, influencing the formation of the three pistils. This discovery helps further understanding of the mechanism behind the formation of the three pistils trait and provides theoretical support for the cultivation of high-yield wheat.

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小麦三雌蕊形成背后植物激素和转录组的变化
辅助素和赤霉素对植物雌蕊的发育有显著影响,但它们在小麦三雌蕊性状形成过程中的具体作用尚不清楚。为了研究辅助素和赤霉素对小麦三雌蕊性状的影响,我们测定了三雌蕊小麦(TP 和 CM28TP)和单雌蕊小麦(CM28)三个阶段幼穗中辅助素和赤霉素的含量。我们还进行了转录组测序。所有样品中共检测到 14 种不同的辅助素和 7 种不同的赤霉素,其中 IAA-Glc 和 GA19 的含量在不同样品间存在显著差异。转录组测序获得了超过 12.8 亿个纯净读数和 320 万个转录本。通过比较 CM28 与 CM28TP 和 CM28 与 TP,分别发现了 2,018 和 6,163 个差异表达基因(DEGs)。通过对辅助素、赤霉素和 DEGs 之间的相关性分析,发现了 4 个 ARF 基因、3 个 AMI 基因和 3 个 DELLA 基因。这些结果表明,IAA-Glc、GA19 和 10 个关键基因是形成三雌蕊性状的关键因素。进一步分析表明,ARF表达水平和GA含量与三雌蕊性状呈负相关,而DELLA表达水平和辅素含量呈正相关。该研究表明,在小麦花的发育过程中,辅助素和赤霉素信号转导存在拮抗关系,影响了三雌蕊的形成。这一发现有助于进一步了解三雌蕊性状形成的机理,为小麦高产栽培提供理论支持。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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