João Paulo Gomes Viana, Arián Avalos, Zhihai Zhang, Randall Nelson, Matthew E Hudson
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引用次数: 0
摘要
了解与产量相关的选择的基本遗传基础,并将这些变化与遗传漂变区分开来,对于提高植物育种的认识和未来的成功至关重要。大豆[Glycine max (L.) Merr.]是世界粮食安全的关键物种,但目前对大豆选择性育种机制的了解,如美国大豆种质中长达一个世纪的人工选择计划,仅限于某些基因和位点。在这里,我们确定了美国多个育种计划为提高产量而进行人工选择的不同大豆群体的全基因组选择特征。我们将 USDA-ARS 创建的替代大豆育种群体(AGP)与在三个不同育种阶段(祖先、中间和精英)开发的常规公共大豆品系(CGP)进行了比较,以识别共同的选择特征并将其与漂移区分开来。结果表明,通过单位点频率和单倍型同源性方法确定的特定单倍型具有很强的选择性。在 AGP 和 CGP 中都发现了一组共同的选择特征,这支持了在相似环境中不同育种计划在相同关键单倍型的固定上形成合力的假设。每个育种计划都有其独特的特征。这些结果提出了一种可能性,即通过选择分析可以鉴定出有利的等位基因,从而加强定向培育方法。
Common signatures of selection reveal target loci for breeding across soybean populations.
Understanding the underlying genetic bases of yield-related selection and distinguishing these changes from genetic drift are critical for both improved understanding and future success of plant breeding. Soybean [Glycine max (L.) Merr.] is a key species for world food security, yet knowledge of the mechanism of selective breeding in soybean, such as the century-long program of artificial selection in U.S. soybean germplasm, is currently limited to certain genes and loci. Here, we identify genome-wide signatures of selection in separate populations of soybean subjected to artificial selection for increased yield by multiple breeding programs in the United States. We compared the alternative soybean breeding population (AGP) created by USDA-ARS to the conventional public soybean lines (CGP) developed at three different stages of breeding (ancestral, intermediate, and elite) to identify shared signatures of selection and differentiate these from drift. The results showed a strong selection for specific haplotypes identified by single site frequency and haplotype homozygosity methods. A set of common selection signatures was identified in both AGP and CGP that supports the hypothesis that separate breeding programs within similar environments coalesce on the fixation of the same key haplotypes. Signatures unique to each breeding program were observed. These results raise the possibility that selection analysis can allow the identification of favorable alleles to enhance directed breeding approaches.
期刊介绍:
The Plant Genome publishes original research investigating all aspects of plant genomics. Technical breakthroughs reporting improvements in the efficiency and speed of acquiring and interpreting plant genomics data are welcome. The editorial board gives preference to novel reports that use innovative genomic applications that advance our understanding of plant biology that may have applications to crop improvement. The journal also publishes invited review articles and perspectives that offer insight and commentary on recent advances in genomics and their potential for agronomic improvement.