A chromosome arm from Thinopyrum intermedium × Thinopyrum ponticum hybrid confers increased tillering and yield potential in wheat.

IF 3 3区农林科学 Q1 AGRONOMY Molecular Breeding Pub Date : 2024-01-22 eCollection Date: 2024-02-01 DOI:10.1007/s11032-024-01439-y

Edina Türkösi, Éva Szakács, László Ivanizs, András Farkas, Eszter Gaál, Mahmoud Said, Éva Darkó, Mónika Cséplő, Péter Mikó, Jaroslav Doležel, Márta Molnár-Láng, István Molnár, Klaudia Kruppa

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Abstract

Tiller number is a key component of wheat plant architecture having a direct impact on grain yield. Because of their viability, biotic resistance, and abiotic stress tolerance, wild relative species are a valuable gene source for increasing wheat genetic diversity, including yield potential. Agropyron glael, a perennial hybrid of Thinopyrum intermedium and Th. ponticum, was created in the 1930s. Recent genome analyses identified five evolutionarily distinct subgenomes (J, J^st, J^vs, J^r, and St), making A. glael an important gene source for transferring useful agronomical traits into wheat. During a bread wheat × A. glael crossing program, a genetically stable translocation line, WT153397, was developed. Sequential in situ hybridizations (McGISH) with J-, St-, and D-genomic DNA probes and pSc119.2, Afa family, pTa71, and (GAA)₇ DNA repeats, as well as molecular markers specific for the wheat 6D chromosome, revealed the presence of a 6DS.6J^vs Robertsonian translocation in the genetic line. Field trials in low-input and high-input breeding nurseries over four growing seasons demonstrated the Agropyron chromosome arm's high compensating ability for the missing 6DL, as spike morphology and fertility of WT153397 did not differ significantly from those of wheat parents, Mv9kr1 and 'Mv Karizma.' Moreover, the introgressed 6J^vs chromosome arm significantly increased the number of productive tillers, resulting in a significantly higher grain yield potential compared to the parental wheat cultivars. The translocated chromosome could be highly purified by flow cytometric sorting due to the intense fluorescent labeling of (GAA)₇ clusters on the Thinopyrum chromosome arm, providing an opportunity to use chromosome genomics to identify Agropyron gene variant(s) responsible for the tillering capacity. The translocation line WT153397 is an important genetic stock for functional genetic studies of tiller formation and useful breeding material for increasing wheat yield potential. The study also discusses the use of the translocation line in wheat breeding.

Supplementary information: The online version contains supplementary material available at 10.1007/s11032-024-01439-y.

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Thinopyrum intermedium × Thinopyrum ponticum 杂交种的染色体臂可提高小麦的分蘖能力和产量潜力。

分蘖数是小麦植株结构的关键组成部分，对谷物产量有直接影响。野生近缘物种具有生存能力、抗生物性和耐非生物胁迫性，是增加小麦遗传多样性（包括产量潜力）的宝贵基因来源。Agropyron glael 是 Thinopyrum intermedium 和 Th. ponticum 的多年生杂交种，诞生于 20 世纪 30 年代。最近的基因组分析发现了五个进化上截然不同的亚基因组（J、Jst、Jvs、Jr 和 St），这使得 A. glael 成为将有用的农艺性状转移到小麦中的重要基因来源。在面包小麦 × A. glael 杂交项目中，培育出了一个遗传稳定的易位系 WT153397。用 J-、St-和 D-基因组 DNA 探针和 pSc119.2、Afa 家族、pTa71 和 (GAA)7 DNA 重复序列以及小麦 6D 染色体特异性分子标记进行序列原位杂交（McGISH），发现该基因系存在 6DS.6Jvs 罗伯逊易位。在低投入和高投入育种苗圃中进行的四个生长季节的田间试验表明，WT153397 的穗形态和生育力与小麦亲本 Mv9kr1 和'Mv Karizma'没有显著差异，因此 Agropyron 染色体臂对缺失的 6DL 有很强的补偿能力。此外，与亲本小麦栽培品种相比，导入的 6Jvs 染色体臂显著增加了生产性分蘖的数量，从而大大提高了粮食产量潜力。由于 Thinopyrum 染色体臂上的（GAA）7 团簇具有强烈的荧光标记，因此可以通过流式细胞分选技术高度纯化移入的染色体，这为利用染色体基因组学鉴定造成分蘖能力的 Agropyron 基因变体提供了机会。易位系 WT153397 是分蘖形成功能基因研究的重要基因储备，也是提高小麦产量潜力的有用育种材料。该研究还讨论了易位系在小麦育种中的应用：在线版本包含补充材料，可查阅 10.1007/s11032-024-01439-y。

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来源期刊

Molecular Breeding 农林科学-农艺学

CiteScore

5.60

自引率

6.50%

发文量

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.