Relationships of Aegilops tauschii revealed by DNA fingerprints: The evidence for agriculture exchange between China and the West

文献类型: 外文期刊

第一作者: Wei, Huiting

作者: Wei, Huiting;Li, Jun;Yang, Wuyun;Peng, Zhengsong;Zhao, Zhijun

作者机构:

关键词: The Silk Road;Aegilops tauschii;Common wheat;SSR fingerprints;Genetic diversity;Affinity;Crop dispersion

期刊名称:PROGRESS IN NATURAL SCIENCE ( 影响因子:3.607; 五年影响因子:4.795 )

ISSN: 1002-0071

年卷期: 2008 年 18 卷 12 期

页码:

收录情况: SCI

摘要: Genetic diversity and relationships of wild goat grass (Aegilops tauschii Cosson) from Iran and Xinjiang, west China, as well as its weedy type from the Yellow River region of Shaanxi and Henan provinces in China were analyzed by simple sequence repeat (SSR) fingerprints. A high level of genetic diversity in Aegilops tauschii accessions from Iran was observed, and the richness of genetic diversity was followed by accessions from Shaanxi, Henan, and Xinjiang. The weedy type of Aegilops tauschii showed a close genetic relationship with the wild type from different regions in Iran. The results indicated that the weedy Aegilops tauschii found in the Yellow River region was most likely introduced from Iran-the diversity center of Aegilops tauschii. The weedy Aegilops tauschii populations found in the Yellow River region may be brought into the central part of China as a weed species together with common wheat ( Triticum aestivum L.) from the West during various periods of time in history. This finding has provided strong evidence for the introduction of common wheat from the West into China via the Silk Road, and also demonstrated the important role of the Silk Road in the exchange of agriculture and other relevant technologies between China and the West. (c) 2008 National Natural Science Foundation of China and Chinese Academy of Sciences. Published by Elsevier Limited and Science in China Press. All rights reserved.

分类号:

  • 相关文献

[1]Synthetic hexaploid wheat and its utilization for wheat genetic improvement in China. Li, Jun,Wei, Huiting,Hu, Xiaorong,Zou, Yuchun,Liu, Dengcai,Zhang, Lianquan,Zheng, Youliang,He, Zhouhu,He, Zhouhu,Liu, Dengcai. 2009

[2]Analysis of Genetic Diversity in Synthetic Wheat Assemblage (T. turgidumxAegilops tauschii; 2n=6x=42; AABBDD) for Winter Wheat Breeding. Hanif, Uzma,Kazi, Alvina Gul,Afzal, Fakiha,Khalid, Maria,Rasheed, Awais,Munir, Muhammad,Mujeeb-Kazi, Abdul.

[3]The impact of modern plant breeding on dominant Chinese wheat cultivars (Triticum aestivum L.) revealed by SSR and functional markers. Meng, Lingzhi,Xiang, Chao,Liu, Hongwei,Yang, Li,Li, Hongjie,Zhang, Hongjun,Zhou, Yang,Mai, Chunyan,Wei, Yunliang,Yu, Liqiang. 2018

[4]Genetic diversity trend of common wheat (Triticum aestivum L.) in China revealed with AFLP markers. Tian, QZ,Zhou, RH,Jia, JZ. 2005

[5]The teleost humoral immune response. Ye, Jianmin,Kaattari, Ilsa M.,Kaattari, Stephen,Ma, Cuiyan. 2013

[6]Inheritance in hexaploid wheat of genes for hairy auricles and hairy leaf sheath derived from Aegilops tauschii Coss.. Wu, BH,Hu, XR,Ye, Y,Zhang, Y. 1999

[7]Synthetic hexaploid wheat enhances variation and adaptive evolution of bread wheat in breeding processes. Wan, Hong-Shen,Yang, Wu-Yun,Li, Jun,Wan, Hong-Shen,Yang, Wu-Yun. 2014

[8]Comparing two approaches for introgression of germplasm from Aegilops tauschii into common wheat. Cox, Thomas S.,Wu, Jizhong,Wang, Shuwen,Cai, Jin,Zhong, Qiaofeng,Fu, Bisheng,Cox, Thomas S.,Wang, Shuwen. 2017

[9]Identification of SNPs and development of allelic specific PCR markers for high molecular weight glutenin subunit D(t)x1.5 from Aegilops tauschii through sequence characterization. Yang, WY,Zhang, WJ,Lu, BR. 2005

[10]Random amplified polymorphism of DNA analysis in Aegilops tauschii. Kong, LR,Dong, YC,Jia, JZ. 1998

[11]Differentiation of the high molecular weight glutenin subunit D-t x2.1 of Aegilops tauschii indicated by partial sequences of its encoding gene and SSR markers. Yang, WY,Lu, BR. 2005

[12]Diversity in D-genome synthetic hexaploid wheat association panel for seedling emergence traits under salinity stress. Khan, Zeeshan,Qazi, Javaria,Rasheed, Awais,Rasheed, Awais,Mujeeb-Kazi, Abdul.

[13]Five Fatty Acyl-Coenzyme A Reductases Are Involved in the Biosynthesis of Primary Alcohols in Aegilops tauschii Leaves. Wang, Meiling,Wu, Hongqi,Li, Chunlian,Wang, Yong,Wang, Zhonghua,Xu, Jing. 2017

[14]Mapping of the heading date gene HdAey2280 in Aegilops tauschii. Liu Guo-xiang,Zhang Li-chao,Xia Chuan,Jia Ji-zeng,Zhang Jun-cheng,Zhang Qiang,Dong Chun-hao,Kong Xiu-ying,Liu Xu. 2016

[15]Identification and Mapping of Two New Genes Conferring Resistance to Powdery Mildew from Aegilops tauschii (Coss.) Schmal. Sun, Xiao-Li,Liu, Di,Zhang, Hai-Quan,Huo, Na-Xin,Zhou, Rong-Hua,Jia, Ji-Zeng.

[16]Discovery, evaluation and distribution of haplotypes of the wheat Ppd-D1 gene. Guo, Zhiai,Song, Yanxia,Zhou, Ronghua,Jia, Jizeng,Guo, Zhiai,Ren, Zhenglong.

[17]Quantitative trait loci mapping of adult-plant resistance to powdery mildew in Chinese wheat cultivar Lumai 21. Caixia Lan,Xiaowen Ni,Jun Yan,Yong Zhang,Xianchun Xia,Xinmin Chen,Zhonghu He.

[18]Diversity, distribution of Puroindoline genes and their effect on kernel hardness in a diverse panel of Chinese wheat germplasm. Ma, Xiaoling,Sajjad, Muhammad,Wang, Jing,Yang, Wenlong,Sun, Jiazhu,Li, Xin,Zhang, Aimin,Liu, Dongcheng,Ma, Xiaoling,Sajjad, Muhammad,Wang, Jing. 2017

[19]Cloning and Characterization of TaTGW-7A Gene Associated with Grain Weight in Wheat via SLAF-seq-BSA. Hu, Ming-Jian,Zhang, Hai-Ping,Liu, Kai,Cao, Jia-Jia,Wang, Sheng-Xing,Jiang, Hao,Wu, Zeng-Yun,Lu, Jie,Zhu, Xiao F.,Xia, Xian-Chun,Sun, Gen-Lou,Ma, Chuan-Xi,Chang, Cheng,Xia, Xian-Chun,Sun, Gen-Lou. 2016

[20]Genome-wide identification and evolutionary analyses of bZIP transcription factors in wheat and its relatives and expression profiles of anther development related TabZIP genes. Li, Xueyin,Gao, Shiqing,Tang, Yimiao,Zhang, Fengjie,Feng, Biane,Fang, Zhaofeng,Zhao, Changping,Li, Xueyin,Ma, Lingjian,Li, Lei,Zhang, Fengjie,Feng, Biane. 2015

作者其他论文 更多>>

微信小程序