Frontiers of soybean pan-genome studies.

Q3 Medicine
遗传 Pub Date : 2024-03-20 DOI:10.16288/j.yczz.23-321
Yu-Cheng Liu, Yan-Ting Shen, Zhi-Xi Tian
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引用次数: 0

Abstract

Artificial domestication provided the original motivation to the blooming of agriculture, following with the dramatic change of the genetic background of crops and livestock. According to theory and technology upgradation that contributing to the omics, we appreciate using the pan-genome instead of single reference genome for crop study. By comparison and integration of multiple genomes under the guidance of pan-genome theory, we can estimate the genomic information range of a species, leading to a global understanding of its genetic diversity. Combining pan-genome with large size chromosomal structural variations, high throughput population resequencing, and multi-omics data, we can profoundly study the genetic basis behind species traits we focus on. Soybean is one of the most important commercial crops over the world. It is also essential to our food security. Dissecting the formation of genetic diversity and the causal loci of key agricultural traits of soybean will make the modern soybean breeding more efficiently. In this review, we summarize the core idea of pan-genome and clarified the characteristics of construction strategies of pan-genome such as de novo/mapping assembly, iterative assembly and graph-based genome. Then we used the soybean pan-genome work as a case study to introduce the general way to study pan-genome. We highlighted the contribution of structural variation (SV) to the evolution/domestication of soybean and its value in understanding the genetic bases of agronomy traits. By those, we approved the value of graph-based pan-genome for data integration and SV calculation. Future research directions are also discussed for crop genomics and data science.

大豆泛基因组研究的前沿。
人工驯化为农业的蓬勃发展提供了原始动力,随之而来的是作物和牲畜遗传背景的巨大变化。随着全基因组学理论和技术的发展,我们更倾向于使用泛基因组而非单一参考基因组来研究作物。在泛基因组理论指导下,通过对多个基因组的比较和整合,我们可以估算出一个物种的基因组信息范围,从而对其遗传多样性有一个全面的了解。将泛基因组与大尺寸染色体结构变异、高通量群体重测序和多组学数据相结合,我们可以深入研究我们关注的物种性状背后的遗传基础。大豆是世界上最重要的经济作物之一。它对我们的粮食安全也至关重要。剖析大豆遗传多样性的形成和关键农业性状的因果位点将使现代大豆育种更加高效。在这篇综述中,我们总结了泛基因组的核心思想,阐明了从头/图谱组装、迭代组装和基于图谱的基因组等泛基因组构建策略的特点。然后,我们以大豆泛基因组研究为例,介绍了泛基因组研究的一般方法。我们强调了结构变异(SV)对大豆进化/驯化的贡献及其在理解农艺性状遗传基础方面的价值。由此,我们认可了基于图的泛基因组在数据整合和 SV 计算方面的价值。我们还讨论了作物基因组学和数据科学的未来研究方向。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
遗传
遗传 Medicine-Medicine (all)
CiteScore
2.50
自引率
0.00%
发文量
6699
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