大豆泛基因组研究进展

doi:10.16288/j.yczz.23-321

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Hereditas(Beijing) ›› 2024, Vol. 46 ›› Issue (3): 183-198.doi: 10.16288/j.yczz.23-321

• Special Section: Excellent Doctoral Thesis • Previous Articles Next Articles

Frontiers of soybean pan-genome studies

Yucheng Liu¹(), Yanting Shen¹, Zhixi Tian¹^,²()

1. Key Laboratory of Seed Innovation, Institute of Genetics and Development of Biology, Chinese Academy of Sciences, Beijing 100101, China
2. University of Chinese Academy of Sciences, Beijing 101408, China

Received:2023-12-29 Revised:2024-02-09 Online:2024-03-20 Published:2024-02-22
Contact: Zhixi Tian E-mail:ychliu@genetics.ac.cn;zxtian@genetics.ac.cn
Supported by:
National Natural Science Foundation of China(32201775);National Natural Science Foundation of China(U22A20473);CAS Project for Young Scientists in Basic Research(YSBR-078)

Abstract

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.

Key words: soybean, pan-genome, structural variation, evolution, domestication

Yucheng Liu, Yanting Shen, Zhixi Tian. Frontiers of soybean pan-genome studies[J]. Hereditas(Beijing), 2024, 46(3): 183-198.

Figures/Tables 2

Table 1

Case studies of plant pan-genome"

类群	发表年份	样品数	测序方式	泛基因组构建策略	参考文献
拟南芥(Arabidopsis thaliana)	2011	18	二代测序	迭代组装+从头组装	[33]
野生大豆(Glycine soja)	2014	7	二代测序	从头组装	[17]
甘蓝(Brassica oleracea)	2016	9	二代测序	迭代组装	[22]
苜蓿(Medicago truncatula)	2017	15	二代测序	从头组装	[76]
二穗短柄草(Brachypodium distachyon)	2017	54	二代测序	从头组装	[16]
水稻(Oryza sativa)	2018	3010	二代测序+三代测序	比对组装	[21]
野生及栽培水稻(O. rufipogon, O. sativa)	2018	66	二代测序	比对组装	[42]
水稻属及亲缘物种(Oryza, Leersia)	2018	13	三代测序+二代测序	从头组装	[18]
辣椒属(Capsicum)	2018	168	二代测序	比对组装	[77]
芝麻(Sesamum indicum)	2018	5	二代测序	比对组装	[78]
番茄及野生亲缘种(Solanum section Lycopersicon)	2019	725	二代测序	比对组装	[19]
向日葵(Helianthus annuus)	2019	287	二代测序	比对组装	[20]
油菜(Brassica napus)	2020	8	三代测序	从头组装	[43]
野生及栽培大豆(Glycine subgenus Soja)	2020	29	三代测序	从头组装+图基因组	[39]
大麦(Hordeum vulgare)	2020	20	二代测序+三代测序	从头组装	[79]
番茄及野生亲缘种(Solanum section Lycopersicon)	2020	14	二代测序+三代测序	比对组装(泛结构变异)	[45]
鹰嘴豆(Cicer arietinum)	2021	3366	二代测序	比对组装	[80]
棉花及亲缘种(Gossypium)	2021	1961	二代测序	比对组装	[81]
野生及栽培高粱(Sorghum bicolor)	2021	13	三代测序	从头组装	[82]
玉米(Zea may)	2021	26	三代测序	从头组装	[83]
水稻(O. sativa)	2021	33	三代测序	从头组装+图基因组	[34]
野生及栽培萝卜(Raphanus)	2021	11	三代测序	从头组装+图基因组	[84]
黄瓜 (Cucumis sativus)	2022	12	三代测序	从头组装+图基因组	[38]
水稻属(Oryza)	2022	251	三代测序	从头组装+图基因组	[85]
棉花属(Gossypium)	2022	10	三代测序	从头组装+图基因组	[86]
多年生大豆(Glycine subgenus Glycine)	2022	6	三代测序	从头组装	[62]
野生及栽培马铃薯(Solanum section Petota)	2022	44	三代测序	从头组装	[87]
番茄(Solanum lycopersicum)	2022	32	三代测序	从头组装+图基因组	[35]
野生及栽培谷子(Setaria)	2023	110	三代测序	从头组装+图基因组	[40]
茶(Camellia sinensis)	2023	22	三代测序	从头组装+图基因组	[41]
柑橘属(Citrus)	2023	12	三代测序	从头组装+图基因组	[36]
番茄及野生亲缘种(Solanum section Lycopersicon)	2023	13	三代测序	从头组装+图基因组	[85]
玉米(Z. mays)	2023	12	三代测序	从头组装	[88]
野生及栽培黍(Panicum miliaceum)	2023	32	三代测序	从头组装+图基因组	[46]

Table 1

Fig. 1

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