农科机构知识库联盟

Genetic diversity and construction of core collection in Chinese wheat genetic resources

文献类型：外文期刊

第一作者： Hao ChenYang

作者： Hao ChenYang;Dong YuChen;Wang LanFen;You GuangXia;Zhang HongNa;Ge HongMei;Jia JiZeng;Zhang XueYong

作者机构：

关键词： genotype;phenotype;genetic diversity;ecological environment;genetic resource;core collection;genetic richness

期刊名称：CHINESE SCIENCE BULLETIN （影响因子：1.649；五年影响因子：1.738 ）

ISSN：

年卷期：

页码：

收录情况： SCI

摘要： Genetic diversity among 5029 accessions representing a proposed Chinese wheat core collection was analyzed using 78 pairs of fluorescent microsatellite (SSR) primers mapped to 21 chromosomes. A stepwise hierarchical sampling strategy with priority based on 4x10(5) SSR data-points was used to construct a core collection from the 23090 initial collections. The core collection consisted of 1160 accessions, including 762 landraces, 348 modern varieties and 50 introduced varieties. The core accounts for 23.1 % of the 5029 candidate core accessions and 5% of the 23090 initial collections, but retains 94.9% of alleles from the candidate collections and captures 91.5% of the genetic variation in the initial collections. These data indicate that it is possible to maintain genetic diversity in a core collection while retaining fewer accessions than the accepted standard, i.e., 10% of the initial collections captured more than 70% of their genetic diversity. Estimated genetic representation of the core constructed by preferred sampling (91.5%) is much higher than that by random sampling (79.8%). Both mean genetic richness and genetic diversity indices of the landraces were higher than those of the modern varieties in the core. Structure and principal coordinate analysis revealed that the landraces and the modern varieties were two relatively independent subpopulations. Strong genetic differentiation associated with ecological environments has occurred in the landraces, but was relatively weak in the modern cultivars. In addition, a mini-core collection was constructed, which consisted of 231 accessions with an estimated 70% representation of the genetic variation from the initial collections. The mini-core has been distributed to various research and breeding institutes for detailed phenotyping and breeding of genetic introgression lines.

分类号： N1

相关文献

[1]Meta-analysis of constitutive and adaptive QTL for drought tolerance in maize. Hao, Zhuanfang,Li, Xinhai,Liu, Xiulin,Xie, Chuanxiao,Li, Mingshun,Zhang, Degui,Zhang, Shihuang,Hao, Zhuanfang.

[2]Discovery and transmission of functional QTL in the pedigree of an elite soybean cultivar Suinong14. Yang, R. Q.,Qin, J.,Li, Y. H.,Guan, R. X.,Chang, R. Z.,Qiu, L. J.,Qin, J.,Jiang, C. X.,Li, W. B..

[3]Solvent retention capacities as indirect selection criteria for sugar snap cookie quality in Chinese soft wheats. Zhang, Yong,Zhang, Qijun,He, Zhonghu,Zhang, Yan,He, Zhonghu,Ye, Guoyou.

[4]Genetic characterization of antimicrobial resistance in Staphylococcus aureus isolated from bovine mastitis cases in Northwest China. Yang Feng,Wang Xu-rong,Wang Ling,Li Xin-pu,Luo Jin-yin,Zhang Shi-dong,Li Hong-sheng,Wang Qi. 2016

[5]Diversity of plant growth-promoting Paenibacillus mucilaginosus isolated from vegetable fields in Zhejiang, China. Lu, Jing-Jiang,Xue, Ai-Qin,Yang, Sui-juan,Hu, Xiu-Fang,Cao, Zhao-Yun.

[6]Phytophthora infestans Field Isolates from Gansu Province, China are Genetically Highly Diverse and Show a High Frequency of Self Fertility. Han, Miao,Liu, Gang,Zhu, Xiao-Qiong,Shen, Chong-Yao,Guo, Li-Yun,Li, Ji-Ping,Govers, Francine,Govers, Francine.

[7]Tracing genetic differentiation of Chinese Mongolian sheep using microsatellites. Zhong, T.,Han, J. L.,Zhao, Q. J.,Fu, B. L.,Pu, Y. B.,He, X. H.,Guan, W. J.,Ma, Y. -H.,Zhong, T.,Jeon, J. T.,Han, J. L.,Guo, J..

[8]Comparison of the genetic diversity between Triticum aestivum ssp tibetanum Shao and Tibetan wheat landraces (Triticum aestivum L.) by using intron-splice junction primers. Zeng, Xingquan,Wang, Yajuan,Li, Weiyan,Wang, Changyou,Liu, Xinlun,Ji, Wanquan,Zeng, Xingquan.

[9]A core collection and mini core collection of Oryza sativa L. in China. Zhang, Hongliang,Zhang, Dongling,Wang, Meixing,Sun, Junli,Qi, Yongwen,Li, Jinjie,Li, Zichao,Wei, Xinghua,Tang, Shengxiang,Han, Longzhi,Qiu, Zongen.

[10]Analysis of genetic diversity and construction of core collection of local mulberry varieties from Shanxi Province based on ISSR marker. Lin, Zhang,Sheng, Qiang,Lin, Zhang,guo, Zhao Wei,jia, Shen Xing,Li, Liu,Lin, Zhang,bai, Chen Jun,Yong, Huang,Yong, Huang,jia, Shen Xing. 2011

[11]Studies on sampling schemes for the establishment of corecollection of rice landraces in Yunnan, China. Li, ZC,Zhang, HL,Zeng, YW,Yang, ZY,Shen, SQ,Sun, CQ,Wang, XK. 2002

[12]Genetic diversity and structure of the core collection for maize inbred lines in China. Yu, Y.,Wang, R.,Shi, Y.,Song, Y.,Wang, T.,Li, Y.. 2007

[13]Establishment of a Core Collection for the Chinese annual wild soybean (Glycine Soja). Zhao, LM,Dong, YS,Li, B,Hao, S,Wang, KJ,Li, XH.

[14]Development of a Core Set from a Large Rice Collection using a Modified Heuristic Algorithm to Retain Maximum Diversity. Chung, Jong-Wook,Zhao, Weiguo,Park, Yong-Jin,Chung, Hun-Ki,Kim, Kyu-Won,Lee, Jung-Ro,Lee, Sok-Young,Gwag, Jae-Gyun,Dixit, Anupam,Kang, Hee-Kyoung,Zhao, Weiguo,McNally, Kenneth L.,Hamilton, Ruraidh S.. 2009

[15]Evaluation of Genetic Diversity of Rice Landraces (Oryza sativa L.) in Yunnan, China. Zeng, Yawen,Zhang, Hongliang,Li, Zichao,Shen, Shiquan,Sun, Jiani,Wang, Meixing,Liao, Dengqun,Liu, Xia,Wang, Xiangkun,Xiao, Fenghui,Wen, Guosong.

[16]Genetic diversity assessment of sesame core collection in China by phenotype and molecular markers and extraction of a mini-core collection. Zhang, Yanxin,Zhang, Xiurong,Che, Zhuo,Wang, Linhai,Wei, Wenliang,Li, Donghua,Che, Zhuo. 2012

[17]Analysis of genetic diversity among indigenous landraces from sesame (Sesamum indicum L.) core collection in China as revealed by SRAP and SSR markers. Zhang, Yan-xin,Zhang, Xiu-rong,Hua, Wei,Wang, Lin-han,Che, Zhuo. 2010

[18]Genetic diversity and core collection evaluations in common wheat germplasm from the Northwestern Spring Wheat Region in China. Hao, CY,Zhang, XY,Wang, LF,Dong, YS,Shang, XW,Jia, JZ. 2006

[19]Molecular characterization of Newcastle disease viruses in Ostriches (Struthio camelus L.): Further evidences of recombination within avian paramyxovirus type 1. Cui, Shangjin,Yin, Yanbo,Wang, Jianlin,Cortey, Marti,Dolz, Roser,Zhang, Yi,Gong, Zhenhua.

[20]DEVELOPMENT AND CHARACTERIZATION OF 21 EST-DERIVED MICROSATELLITE MARKERS IN VICIA FABA (FAVA BEAN). Ma, Yu,Yang, Tao,Guan, Jianping,Wang, Shumin,Wang, Haifei,Sun, Xuelian,Zong, Xuxiao.

作者其他论文更多>>

Identification and Microsatellite Markers of a Resistance Gene to Powdery Mildew in Common Wheat Introgressed from Triticum durum

作者：Zhu Zhendong;Kong Xiuying;Zhou Ronghua;Jia Jizeng

关键词：resistance gene;microsatellite;molecular tagging;powdery mildew;durum wheat
Chromosomal Distribution of the 18S-5.8S-26S rDNA Loci and Heterogeneity of Nuclear ITS Regions in Thinopyrum intermedium (Poaceae: Triticeae)

作者：Li Dayong;Ru Yanyan;Zhang Xueyong

关键词：Thinopyrum intermedium;18S-5.8S-26S rDNA;internal transcribed spacer (ITS);concerted evolution;fluorescent in situ hybridization (FISH);genomic in situ hybridization (GISH)
Genetic diversity in Chinese modern wheat varieties revealed by microsatellite markers

作者：Hao Chenyang;Wang Lanfen;Zhang Xueyong;You Guangxia;Dong Yushen;Jia Jizeng;Liu Xu;Shang Xunwu;Liu Sancai;Cao Yongsheng

关键词：wheat;microsatellite markers;genetic diversity

Genetic diversity and construction of core collection in Chinese wheat genetic resources

作者其他论文 更多>>

Identification and Microsatellite Markers of a Resistance Gene to Powdery Mildew in Common Wheat Introgressed from Triticum durum

Chromosomal Distribution of the 18S-5.8S-26S rDNA Loci and Heterogeneity of Nuclear ITS Regions in Thinopyrum intermedium (Poaceae: Triticeae)

Genetic diversity in Chinese modern wheat varieties revealed by microsatellite markers

作者其他论文更多>>