分析遗传分化和基因组变异以揭示玉米改良过程中的潜在重要区域。

Analysis of genetic differentiation and genomic variation to reveal potential regions of importance during maize improvement.

作者信息

Wu Xun, Li Yongxiang, Li Xin, Li Chunhui, Shi Yunsu, Song Yanchun, Zheng Zuping, Li Yu, Wang Tianyu

机构信息

Institute of Crop Science, Chinese Academy of Agricultural Science, Beijing, China.

Nanchong Academy of Agricultural Sciences, Nanchong, Sichuan, China.

出版信息

BMC Plant Biol. 2015 Oct 24;15:256. doi: 10.1186/s12870-015-0646-7.

DOI:10.1186/s12870-015-0646-7

PMID:26496865

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4620006/

Abstract

BACKGROUND

Exploring genetic differentiation and genomic variation is important for both the utilization of heterosis and the dissection of the genetic bases of complex traits.

METHODS

We integrated 1857 diverse maize accessions from America, Africa, Europe and Asia to investigatetheir genetic differentiation, genomic variation using 43,252 high-quality single-nucleotide polymorphisms(SNPs),combing GWAS and linkage analysis strategy to exploring the function of relevant genetic segments.

RESULTS

We uncovered many more subpopulations that recently or historically formed during the breeding process. These patterns are represented by the following lines: Mo17, GB, E28, Ye8112, HZS, Shen137, PHG39, B73, 207, A634, Oh43, Reid Yellow Dent, and the Tropical/subtropical (TS) germplasm. A total of 85 highly differentiated regions with a DEST of more than 0.2 were identified between the TS and temperate subpopulations. These regions comprised 79% of the genetic variation, and most were significantly associated with adaptive traits. For example, the region containing the SNP tag PZE.108075114 was highly differentiated, and this region was significantly associated with flowering time (FT)-related traits, as supported by a genome-wide association study (GWAS) within the interval of FT-related quantitative trait loci (QTL). This region was also closely linked to zcn8 and vgt1, which were shown to be involved in maize adaptation. Most importantly, 197 highly differentiated regions between different subpopulation pairs were located within an FT- or plant architecture-related QTL.

CONCLUSIONS

Here we reported that 700-1000 SNPs were necessary needed to robustly estimate the genetic differentiation of a naturally diverse panel. In addition, 13 subpopulations were observed in maize germplasm, 85 genetic regions with higher differentiation between TS and temperate maize germplasm, 197 highly differentiated regions between different subpopulation pairs, which contained some FT- related QTNs/QTLs/genes supported by GWAS and linkage analysis, and these regions were expected to play important roles in maize adaptation.

摘要

背景

探索遗传分化和基因组变异对于杂种优势的利用以及复杂性状遗传基础的剖析都很重要。

方法

我们整合了来自美洲、非洲、欧洲和亚洲的1857份不同玉米种质，利用43252个高质量单核苷酸多态性（SNP）来研究它们的遗传分化和基因组变异，结合全基因组关联研究（GWAS）和连锁分析策略来探索相关遗传区段的功能。

结果

我们发现了许多在育种过程中近期或历史上形成的亚群。这些模式由以下品系代表：Mo17、GB、E28、掖8112、黄早四、沈137、PHG39、B73、207、A634、Oh43、瑞德黄马牙，以及热带/亚热带（TS）种质。在TS和温带亚群之间共鉴定出85个分化程度高的区域，其分化选择统计量（DEST）大于0.2。这些区域占遗传变异的79%，且大多数与适应性性状显著相关。例如，包含SNP标签PZE.108075114的区域高度分化，并且该区域与开花时间（FT）相关性状显著相关，这在FT相关数量性状位点（QTL）区间内的全基因组关联研究（GWAS）中得到了支持。该区域还与zcn8和vgt1紧密连锁，这两个基因已被证明参与玉米的适应性。最重要的是，不同亚群对之间的197个高度分化区域位于与FT或株型相关的QTL内。

结论

我们在此报告，要可靠地估计自然多样化群体的遗传分化，需要700 - 1000个SNP。此外，在玉米种质中观察到13个亚群，TS和温带玉米种质之间有85个分化程度较高的遗传区域，不同亚群对之间有197个高度分化区域，其中包含一些经GWAS和连锁分析支持的与FT相关的数量性状核苷酸（QTN）/QTL/基因，并且这些区域有望在玉米适应性中发挥重要作用。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d2bf/4620006/6027ff1ee26b/12870_2015_646_Fig1_HTML.jpg

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分析遗传分化和基因组变异以揭示玉米改良过程中的潜在重要区域。

Analysis of genetic differentiation and genomic variation to reveal potential regions of importance during maize improvement.

作者信息

机构信息

出版信息

BACKGROUND

METHODS

RESULTS

CONCLUSIONS

背景

方法

结果

结论

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