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精细定位影响小麦理想株型的分蘖抑制基因 TIN4。

Fine mapping of the tiller inhibition gene TIN4 contributing to ideal plant architecture in common wheat.

机构信息

Triticeae Research Institute, Sichuan Agricultural University, Wenjiang, Chengdu, 611130, China.

State Key Laboratory of Crop Gene Exploration and Utilization in Southwest China, Wenjiang, Chengdu, 611130, China.

出版信息

Theor Appl Genet. 2022 Feb;135(2):527-535. doi: 10.1007/s00122-021-03981-1. Epub 2021 Oct 30.

DOI:10.1007/s00122-021-03981-1
PMID:34716761
Abstract

A tiller inhibition gene, TIN4, was mapped to an approximately 311 kb genomic interval on chromosome arm 2DL of wheat. The tiller is one of the key components of plant morphological architecture and a central agronomic trait affecting spike number in wheat. Low tiller number has been proposed as a major component of crop ideotypes for high yield potential. In this study, we characterized the development of tillering in near-isogenic lines (NIL7A and NIL7B), indicating that the TIN4 gene inhibited the growth of tillering buds and negatively regulated tiller number. Low-tillering was controlled by a single gene (TIN4) located on chromosome 2DL by genetic analysis and bulked segregant RNA-seq analysis. A total of 17 new polymorphic markers were developed in this study, and 61 recombinants were identified in the secondary F2 population containing 4,266 individuals. TIN4 was finally mapped on a 0.35 cM interval, co-segregated with molecular marker M380, within a 311 kb genomic interval of the wheat cultivar Chinese Spring reference genome sequence that contained twelve predicted genes. Yield experiments showed that the yield of low-tillering lines was higher than that of high-tillering lines at a higher density. Overall, this study provides a foundation for the construction of a low-tillering ideotype for improving wheat yield and further cloning TIN4 by map-based cloning approach.

摘要

分蘖抑制基因 TIN4 被定位到小麦 2DL 染色体臂上约 311kb 的基因组区间内。分蘖是植物形态结构的关键组成部分之一,也是影响小麦穗数的重要农艺性状。低分蘖数被认为是高产量潜力作物理想型的主要组成部分。本研究通过近等基因系(NIL7A 和 NIL7B)对分蘖发育进行了特征描述,表明 TIN4 基因抑制分蘖芽的生长并负调控分蘖数。通过遗传分析和混池分离群体 RNA-seq 分析表明,低分蘖受位于 2DL 染色体上的单个基因(TIN4)控制。本研究共开发了 17 个新的多态性标记,在包含 4266 个个体的二次 F2 群体中鉴定出 61 个重组体。TIN4 最终被定位在一个 0.35cM 的区间内,与分子标记 M380 共分离,该区间位于包含十二个预测基因的小麦品种中国春参考基因组序列的 311kb 基因组区间内。产量试验表明,在较高密度下,低分蘖系的产量高于高分蘖系。总体而言,本研究为构建低分蘖理想型以提高小麦产量提供了基础,并通过图谱克隆方法进一步克隆了 TIN4。

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