您好,欢迎访问吉林省农业科学院 机构知识库!
吉林省农业科学院机构知识库

全部

  • 全部
  • 标题
  • 学者
  • 机构
  • 关键词

Comparison of Genetic Diversity between Chinese and American Soybean (Glycine max (L.)) Accessions Revealed by High-Density SNPs

文献类型: 外文期刊

作者: Liu, Zhangxiong 1 ; Li, Huihui 1 ; Wen, Zixiang 2 ; Fan, Xuhong; Li, Yinghui 1 ; Guan, Rongxia 1 ; Guo, Yong 1 ; Wang, 1 ;

作者机构: 1.Chinese Acad Agr Sci, Inst Crop Sci, Key Lab Crop Germplasm Utilizat,Minist Agr, Natl Key Facil Gene Resources & Genet Improvement, Beijing, Peoples R China

2.Michigan State Univ, Dept Plant Soil & Microbial Sci, E Lansing, MI 48824 US

关键词: soybean;single nucleotide polymorphism (SNP);genetic diversity;population structure;US soybean accessions;Chinese soybean accessions

期刊名称:FRONTIERS IN PLANT SCIENCE ( 影响因子:5.753; 五年影响因子:6.612 )

ISSN: 1664-462X

年卷期: 2017 年 8 卷

页码:

收录情况: SCI

摘要: Soybean is one of the most important economic crops for both China and the United States (US). The exchange of germplasm between these two countries has long been active. In order to investigate genetic relationships between Chinese and US soybean germplasm, 277 Chinese soybean accessions and 300 US soybean accessions from geographically diverse regions were analyzed using 5,361 SNP markers. The genetic diversity and the polymorphism information content (PIC) of the Chinese accessions was higher than that of the US accessions. Population structure analysis, principal component analysis, and cluster analysis all showed that the genetic basis of Chinese soybeans is distinct from that of the USA. The groupings observed in clustering analysis reflected the geographical origins of the accessions; this conclusion was validated with both genetic distance analysis and relative kinship analysis. F-ST-based and EigenGWAS statistical analysis revealed high genetic variation between the two subpopulations. Analysis of the 10 loci with the strongest selection signals showed that many loci were located in chromosome regions that have previously been identified as quantitative trait loci (QTL) associated with environmental-adaptation-related and yield related traits. The pattern of diversity among the American and Chinese accessions should help breeders to select appropriate parental accessions to enhance the performance of future soybean cultivars.

  • 相关文献

[1]Genetic diversity and population structure of ginseng in China based on RAPD analysis. Zhao, Yan,Xu, Yong-hua,Zhang, Lian-xue,Wang, Shi-jie,Han, Feng-bo,Li, Ru-sheng,Chen, Xiao-lin,Wang, Shi-jie,Li, Gang. 2016

[2]Assessing the numbers of SNPs needed to establish molecular IDs and characterize the genetic diversity of soybean cultivars derived from Tokachi nagaha. Liu, Zhangxiong,Htwe, Nang Myint Phyu Sin,Xing, Lili,Li, Yinghui,Guan, Rongxia,Chang, Ruzhen,Qiu, Lijuan,Li, Jun,Fa, Xuhong,Wang, Shuming,Huang, Wen,Yang, Jiyu,Chen, Lijun,Wang, Dechun. 2017

[3]Stability of growth periods traits for soybean cultivars across multiple locations. Liu Zhang-xiong,Chang Ru-zhen,Qiu Li-juan,Wang Xiao-bo,Yang Chun-yan,Xu Ran,Zhang Li-feng,Lu Wei-guo,Wang Qian,Wei Su-hong,Yang Chun-ming,Wang Hui-cai,Wang Rui-zhen,Zhou Rong,Chen Huai-zhu. 2016

[4]Aspects of soybean insect resistance breeding in China. Wang, S. 2004

[5]RNAi-mediated SMV P3 cistron silencing confers significantly enhanced resistance to multiple Potyvirus strains and isolates in transgenic soybean. Yang, Xiangdong,Niu, Lu,Zhang, Wei,Yang, Jing,Xing, Guojie,He, Hongli,Guo, Dongquan,Du, Qian,Qian, Xueyan,Yao, Yao,Li, Qiyun,Dong, Yingshan. 2018

[6]Genome-wide identification and expression analysis of the CPP-like gene family in soybean. Zhang, L.,Wang, Y. M.,Yuan, C. P.,Zhang, Y. Y.,Li, H. Y.,Dong, Y. S.,Zhao, H. K.,Yan, X. F.,Li, Q. Y.. 2015

[7]Adaptation and Application of Soybean Phenology Model in the North China Spring Soybean Producing Area. Wang, Can,Zhang, Baogui,Yan, Xiaoyan. 2012

[8]Flavor characteristic analysis of soymilk prepared by different soybean cultivars and establishment of evaluation method of soybean cultivars suitable for soymilk processing. Shi Xiaodi,Li Jingyan,Guo Shuntang,Wang Shuming,Zhang Lei,Qiu Lijuan,Han Tianfu,Wang Qianyu,Chang Sam Kow-Ching.

[9]Characterization of root architecture in an applied core collection for phosphorus efficiency of soybean germplasm. Zhao, J,Fu, JB,Liao, H,He, Y,Nian, H,Hu, YM,Qiu, LJ,Dong, YS,Yan, XL.

[10]Selection of soybean elite cultivars based on phenotypic and genomic characters related to lodging tolerance. Liu, Zhangxiong,Li, Huihui,Li, Yinghui,Qiu, Lijuan,Fan, Xuhong,Zheng, Yuhong,Wang, Shuming,Huang, Wen,Yang, Jiyu,Wen, Zixiang,Wang, Dechun.

[11]Effects of wheat and soybean stubbles on soil sickness in continuous cropping of cucumber. Feng, T.,Wang, Y. Y.,Zhang, Y. H.,Shi, X. H.,Qin, C. H.,Zhang, S. A.,Jin, S. C.,Zhang, H.,Zhang, J.,Zhang, S. A.,Zhang, J.,Qin, C. H.. 2016

[12]A Comparative Proteomics Analysis of Soybean Cotyledon and Unifoliolate Leaves Under Heat (Chilling) Treatments. Jiang, Hong-wei,Xin, Da-wei,Shan, Cai-yun,Wang, Jin-hui,Chen, Qing-shan,Jiang, Hong-wei,Liu, Chun-yan,Hu, Guo-hua,Xin, Da-wei,Zhu, Rong-sheng,Hu, Zhen-bang,Chen, Qing-shan,Qiu, Hong-mei.

[13]Stability analysis of seven agronomic traits for soybean [(Glycine max (L.) Merr.] Tokachi nagaha and its derived cultivars using the AMMI model. Liu, Zhangxiong,Qiu, Lijuan,Fan, Xuhong,Zheng, Yuhong,Wang, Shuming,Huang, Wen,Yang, Jiyu. 2017

[14]Quantitative trait loci analysis of soluble sugar contents in soybean. Wang, Yueqiang,Chen, Pengyin,Zhang, Bo.

[15]Robust RNAi-mediated resistance to infection of seven potyvirids in soybean expressing an intron hairpin NIb RNA. Yang, Xiangdong,Niu, Lu,Zhang, Wei,He, Hongli,Yang, Jing,Xing, Guojie,Guo, Dongquan,Du, Qian,Qian, Xueyan,Yao, Yao,Li, Qiyun,Dong, Yingshan.

[16]Nitrogen manipulation affects leaf senescence during late seed filling in soybean. Islam, Md. Matiul,Islam, Md. Matiul,Ishibashi, Yushi,Iwaya-Inoue, Mari,Nakagawa, Andressa C. S.,Tomita, Yuki,Zhao, Xin,Arima, Susumu,Zheng, Shao-Hui.

[17]Sequencing of the chloroplast genomes of cytoplasmic male-sterile and male-fertile lines of soybean and identification of polymorphic markers. Lin, Chunjing,Dong, Yingshan,Lin, Chunjing,Zhang, Chunbao,Zhao, Hongkun,Xing, Shaochen,Wang, Yumin,Liu, Xiaodong,Yuan, Cuiping,Zhao, Limei,Dong, Yingshan,Zhang, Chunbao,Zhao, Limei,Dong, Yingshan.

[18]Phenotypic characterization and genetic dissection of nine agronomic traits in Tokachi nagaha and its derived cultivars in soybean (Glycine max (L.) Merr.). Liu, Zhangxiong,Li, Huihui,Li, Yinghui,Guan, Rongxia,Guo, Yong,Chang, Ruzhen,Qiu, Li-Juan,Fan, Xuhong,Wang, Shuming,Huang, Wen,Yang, Jiyu,Wen, Zixiang,Wang, Dechun,Chen, Pengyin.

[19]RNA-seq Analysis Reveals Ethylene-Mediated Reproductive Organ Development and Abscission in Soybean (Glycine max L. Merr.). Cheng, Yun-Qing,Liu, Jian-Feng,Liu, Chunming,Liu, Qiang,Yang, Xiangdong,Ma, Rui.

[20]Genetic Variation and Geographic Differentiation Among Populations of the Nonmigratory Agricultural Pest Oedaleus infernalis (Orthoptera: Acridoidea) in China. Sun, Wei,Dong, Hui,Su, Qian-Fu,Qian, Hai-Tao,Cong, Bin,Sun, Wei,Gao, Yue-Bo,Su, Qian-Fu,Bai, Hong-Yan,Zhang, Zhu-Ting. 2015

作者其他论文 更多>>
置顶
购物车
反馈

© 京ICP备09089781号-29 主办单位:吉林省农业科学院

学术资源: 中国农业科学院 农业专业知识服务系统 农科联盟资源共建共享平台 中国农业科技文献与信息服务平台 中国农业期刊集成服务平台