小麦寡耕突变体ot1的赤霉内酯和脱落酸合成及信号传导途径增强

IF 2.6 3区 农林科学 Q1 AGRONOMY
Jiaxing Bai, Huijun Guo, Hongchun Xiong, Yongdun Xie, Jiayu Gu, Linshu Zhao, Shirong Zhao, Yuping Ding, Luxiang Liu
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引用次数: 0

摘要

分蘖数对小麦的产量有很大影响。此前,我们利用甲基磺酸乙酯诱变发现了少分蘖突变体ot1。从分蘖初期到抽穗期,ot1 的分蘖数明显低于相应的野生型。与野生型相比,ot1的千粒重和粒长分别增加了15.41%和31.44%,而株高和穗长分别减少了26.13%和37.25%。在返青和拔节期进行了转录组分析,以确定差异表达基因(DEGs)。利用京都基因组百科全书(KEGG)和基因本体(GO)数据库进行的功能富集分析表明,在分蘖发育过程中,与ADP结合、跨膜运输和转录调控相关的基因表达存在差异。ot1的分蘖数量差异导致赤霉内酯(SL)和脱落酸(ABA)途径中的基因上调。具体而言,SL 生物合成基因 DWARF(D27)、D17、D10 和 MORE AXILLARY GROWTH 1(MAX1)上调了 3.37 至 8.23 倍;SL 信号转导基因 D14 和 D53 分别上调了 1.81 和 1.32倍;ABA生物合成基因9-CIS-EPOXICAROTENOID DIOXIGENASE 3(NCED3)和NCED5分别上调1.66倍和3.4倍;SNF1-REGULATED PROTEIN KINASE2(SnRK2)和PROTEIN PHOSPHATASE 2C(PP2C)基因上调1.30倍至4.79倍。这表明,ot1 的分蘖数量减少是由于植物激素途径发生了变化。已知促进分蘖生长的基因上调,而已知抑制分蘖生长的基因下调。例如,促进分蘖生长的 PIN-FORMED 9(PIN9)在 ot1 中上调了 8.23 倍;抑制分蘖生长的 Ideal Plant Architecture 1(IPA1)下调了 1.74 倍。TILLER NUMBER 1(TN1)和TEOSINTE BRANCHED 1(TB1)的表达水平没有明显差异,表明ot1的分蘖减少不受已知基因的控制。我们的发现为后续研究小麦分蘖的遗传基础和调控机制提供了宝贵的数据。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Strigolactone and abscisic acid synthesis and signaling pathways are enhanced in the wheat oligo-tillering mutant ot1

Strigolactone and abscisic acid synthesis and signaling pathways are enhanced in the wheat oligo-tillering mutant ot1

Tiller number greatly contributes to grain yield in wheat. Using ethylmethanesulfonate mutagenesis, we previously discovered the oligo-tillering mutant ot1. The tiller number was significantly lower in ot1 than in the corresponding wild type from the early tillering stage until the heading stage. Compared to the wild type, the thousand-grain weight and grain length were increased by 15.41% and 31.44%, respectively, whereas the plant height and spike length were decreased by 26.13% and 37.25%, respectively. Transcriptomic analysis was conducted at the regreening and jointing stages to identify differential expressed genes (DEGs). Functional enrichment analysis with the Kyoto Encyclopedia of Genes and Genomes (KEGG) and Gene Ontology (GO) databases showed differential expression of genes associated with ADP binding, transmembrane transport, and transcriptional regulation during tiller development. Differences in tiller number in ot1 led to the upregulation of genes in the strigolactone (SL) and abscisic acid (ABA) pathways. Specifically, the SL biosynthesis genes DWARF (D27), D17, D10, and MORE AXILLARY GROWTH 1 (MAX1) were upregulated by 3.37- to 8.23-fold; the SL signal transduction genes D14 and D53 were upregulated by 1.81- and 1.32-fold, respectively; the ABA biosynthesis genes 9-CIS-EPOXICAROTENOID DIOXIGENASE 3 (NCED3) and NCED5 were upregulated by 1.66- and 3.4-fold, respectively; and SNF1-REGULATED PROTEIN KINASE2 (SnRK2) and PROTEIN PHOSPHATASE 2C (PP2C) genes were upregulated by 1.30- to 4.79-fold. This suggested that the tiller number reduction in ot1 was due to alterations in plant hormone pathways. Genes known to promote tillering growth were upregulated, whereas those known to inhibit tillering growth were downregulated. For example, PIN-FORMED 9 (PIN9), which promotes tiller development, was upregulated by 8.23-fold in ot1; Ideal Plant Architecture 1 (IPA1), which inhibits tiller development, was downregulated by 1.74-fold. There were no significant differences in the expression levels of TILLER NUMBER 1 (TN1) or TEOSINTE BRANCHED 1 (TB1), indicating that the tiller reduction in ot1 was not controlled by known genes. Our findings provide valuable data for subsequent research into the genetic bases and regulatory mechanisms of wheat tillering.

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来源期刊
Molecular Breeding
Molecular Breeding 农林科学-农艺学
CiteScore
5.60
自引率
6.50%
发文量
67
审稿时长
1.5 months
期刊介绍: Molecular Breeding is an international journal publishing papers on applications of plant molecular biology, i.e., research most likely leading to practical applications. The practical applications might relate to the Developing as well as the industrialised World and have demonstrable benefits for the seed industry, farmers, processing industry, the environment and the consumer. All papers published should contribute to the understanding and progress of modern plant breeding, encompassing the scientific disciplines of molecular biology, biochemistry, genetics, physiology, pathology, plant breeding, and ecology among others. Molecular Breeding welcomes the following categories of papers: full papers, short communications, papers describing novel methods and review papers. All submission will be subject to peer review ensuring the highest possible scientific quality standards. Molecular Breeding core areas: Molecular Breeding will consider manuscripts describing contemporary methods of molecular genetics and genomic analysis, structural and functional genomics in crops, proteomics and metabolic profiling, abiotic stress and field evaluation of transgenic crops containing particular traits. Manuscripts on marker assisted breeding are also of major interest, in particular novel approaches and new results of marker assisted breeding, QTL cloning, integration of conventional and marker assisted breeding, and QTL studies in crop plants.
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