您好,欢迎访问江苏省农业科学院 机构知识库!
江苏省农业科学院机构知识库

全部

  • 全部
  • 标题
  • 学者
  • 机构
  • 关键词

QTL mapping for seedling traits associated with low-nitrogen tolerance using a set of advanced backcross introgression lines of rice

文献类型: 外文期刊

作者: Zhao, Chun-fang 1 ; Zhou, Li-hui 1 ; Zhang, Ya-dong 1 ; Zhu, Zhen 1 ; Chen, Tao 1 ; Zhao, Qing-yong 1 ; Yao, Shu 2 ; Yu, 1 ;

作者机构: 1.Jiangsu Acad Agr Sci, Inst Food Crops, Jiangsu High Qual Rice Res & Dev Ctr, Nanjing Branch,China Natl Ctr Rice Improvement, Nanjing 210014, Peoples R China

2.Jiangsu Acad Agr Sci, Inst Food Crops, Jiangsu High Qual Rice Res & Dev Ctr,

关键词: seedling stage;Oryza sativa L.;low-nitrogen tolerance;QTL

期刊名称:PLANT BREEDING ( 影响因子:1.832; 五年影响因子:1.956 )

ISSN: 0179-9541

年卷期: 2014 年 133 卷 2 期

页码:

收录情况: SCI

摘要: Nitrogen (N) deficiency is a major yield-limiting factor in rice production. The objective of this study was to identify putative QTLs for low-N stress tolerance of rice, using an advanced backcross population derived from crosses between an indica cultivar '93-11' and a japonica cultivar 'Nipponbare' and genotyped at 250 marker loci. Plant height, maximum root length, root dry weight, shoot dry weight and plant dry weight under two N conditions and their relative traits were used to evaluate low-N tolerance at the seedling stage. A total of 44 QTLs were identified on chromosomes 1, 2, 3, 4, 5, 6, 8 and 9. Eight intervals on five chromosomes were identified to harbour multiple QTLs, suggesting pleiotropism or multigenic effects according to the contributor of alleles. Some QTL clusters were found in the nearby regions of genes associated with N recycling in rice, indicating that the key N metabolism genes might have effects on the expression of QTLs. Several unique QTLs for relative traits were detected, which suggested the specific genetic basis of relative performance.

  • 相关文献

[1]Analysis of QTLs for panicle exsertion and its relationship with yield and yield-related traits in rice (Oryza sativa L.). Zhao, C. F.,Chen, T.,Zhao, Q. Y.,Zhou, L. H.,Zhao, L.,Zhang, Y. D.,Zhu, Z.,Yao, S.,Wang, C. L.. 2016

[2]Association Mapping of Ferrous, Zinc, and Aluminum Tolerance at the Seedling Stage in Indica Rice using MAGIC Populations. Qian, Qian,Ye, Guoyou,Meng, Lijun,Zhao, Xiangqian,Ponce, Kimberly,Ye, Guoyou,Wang, Baoxiang,Zhao, Xiangqian. 2017

[3]Association analysis for detecting significant single nucleotide polymorphisms for phosphorus-deficiency tolerance at the seedling stage in soybean [Glycine max (L) Merr.]. Ning, Lihua,Kan, Guizhen,Du, Wenkai,Wang, Qing,Zhang, Guozheng,Cheng, Hao,Yu, Deyue,Ning, Lihua,Guo, Shiwei.

[4]小麦赤霉病抗性分子标记研究. 张旭,任丽娟,周淼平,高力,沈晓蓉,向阳海,马鸿翔,陆维忠. 2005

[5]Fine mapping and candidate gene analysis of a green-revertible albino gene gra(t) in rice. Chen, Tao,Zhang, Yadong,Zhao, Ling,Zhu, Zhen,Lin, Jing,Zhang, Suobing,Wang, Cailin. 2009

[6]Rare allele of OsPPKL1 associated with grain length causes extra-large grain and a significant yield increase in rice. Wang, Jianfei,Huang, Ji,Lan, Hongxia,Yin, Congfei,Wu, Yunyu,Tang, Haijuan,Zhang, Hongsheng,Wang, Cailin,Qian, Qian,Li, Jiayang,Li, Jiayang.

[7]Different maternal origins of Japanese lowland and upland rice populations. Ishikawa, R,Sato, YI,Tang, T,Nakamura, I. 2002

[8]Gamete abortion locus detected by segregation distortion of isozyme locus Pgi1 in indica-japonica hybrids of rice (Oryza sativa L.). Lu, CG,Zou, JS,Ikehashi, H. 2000

[9]Effect of allelopathic rice varieties combined with cultural management options on paddy field weeds. Kong, Chui-Hua,Wang, Peng,Kong, Chui-Hua,Hu, Fei,Wu, Jing-Lun.

[10]Evaluation of WARM for different establishment techniques in Jiangsu (China). Pagani, Valentina,Francone, Caterina,Bregaglio, Simone,Acutis, Marco,Confalonieri, Roberto,Wang, ZhiMing,Qiu, Lin.

[11]DISTRIBUTION OF SEVEN GRAIN GENES AND EVALUATION OF THEIR GENETIC EFFECTS ON GRAIN TRAITS. Zhang, Yadong,Zhao, Qingyong,Zhao, Chunfang,Chen, Tao,Zhu, Zhen,Zhou, Lihui,Yao, Shu,Zhao, Ling,Wang, Cailin. 2016

[12]New insights into the genetic networks affecting seed fatty acid concentrations in Brassica napus. Wang, Xiaodong,Yin, Yongtai,Gan, Lu,Yu, Longjiang,Li, Maoteng,Long, Yan,Zhang, Chunyu,Meng, Jinling,Long, Yan,Wang, Xiaodong,Liu, Liezhao. 2015

[13]Quantitative trait loci analysis and genome-wide comparison for silique related traits in Brassica napus. Wang, Xiaodong,Chen, Li,Chao, Hongbo,Li, Maoteng,Wang, Xiaodong,Chen, Li,Xiang, Jun,Gan, Jianping,Wang, Aina,Wang, Hao,Tian, Jianhua,Zhao, Xiaoping,Zhao, Yajun,Zhao, Weiguo. 2016

[14]Quantitative trait loci for resistance to Sharp Eyespot (Rhizoctonia cerealis) in recombinant inbred wheat lines from the cross Niavt 14 x Xuzhou 25. Jiang, Yanjie,Zhu, Fangfang,Cai, Shibin,Wu, Jizhong,Zhang, Qiaofeng. 2016

[15]Construction of a linkage map for quantitative trait loci associated with economically important traits in creeping bentgrass (Agrostis stolonifera L.). Zhang, Tifu,Ge, Min,Ye, Xiaoqing,Zhao, Han,Bughrara, Suleiman S..

[16]小麦雌性育性双向极端群体QTL定位策略初探. 徐海风,窦秉德,侯北伟,朱晓滨,杨晋彬. 2009

[17]基于BinMap的大麦耐盐QTL整合. 沈会权,张英虎,乔海龙,臧慧,陶红,栾海业,陈健,陈和. 2014

[18]植物基因组学在育种实践上的研究进展. 严国红,孙明法,姚立生,单忠德. 2011

[19]玉米产量性状QTL定位分析. 贾波,管飞翔,谢庆春,张玲,邓德祥,钱东海. 2013

[20]水稻耐冷QTL定位以及分子机理研究进展. 李育红,王志平,戴正元,黄年生. 2016

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:江苏省农业科学院

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