农科机构知识库联盟

Identification of QTLs associated with physiological nitrogen use efficiency in rice

文献类型：外文期刊

第一作者： Cho, Young-Il

作者： Cho, Young-Il;Jiang, Wenzhu;Chin, Joong-Hyoun;Piao, Zhongze;Cho, Yong-Gu;McCouch, Susan R.;Koh, Hee-Jong

作者机构：

关键词： epistasis;physiological nitrogen use efficiency;QTL;rice

期刊名称：MOLECULES AND CELLS （影响因子：5.034；五年影响因子：4.932 ）

ISSN： 1016-8478

年卷期： 2007 年 23 卷 1 期

页码：

收录情况： SCI

摘要： Demand for low-input sustainable crop cultivation is increasing to meet the need for environment-friendly agriculture. Consequently, developing genotypes with high nutrient use efficiency is one of the major objectives of crop breeding programs. This study was conducted to identify QTLs for traits associated with physiological nitrogen use efficiency (PNUE). A recombinant inbred population (DT-RILs) between Dasan-byeo (a tongil type rice, derived from an indica x japonica cross and similar to indica in its genetic make-up) and TR22183 (a Chinese japonica variety) consisting of 166 F-8 lines was developed and used for mapping. A frame map of 1,409 cM containing 113 SSR and 103 STS markers with an average interval of 6.5 cM between adjacent marker loci was constructed using the DT-RILs. The RILs were cultivated in ordinary-N (N-P2O5-K2O = 100-80-80 kg/ha) and low-N (N-P(2)o(5)K(2)O = 50-80-80 kg/ha) (100 kg/ha) conditions. PNUE was positively correlated with the harvest index and grain yield in both conditions. Twenty single QTLs (S-QTLs) and 58 pairs of epistatic loci (E-QTLs) were identified for the nitrogen concentration of grain, nitrogen concentration of straw, nitrogen content of shoot, harvest index, grain yield, straw yield and PNUE in both conditions. The phenotypic variance explained by these S-QTLs and E-QTLs ranged from 11.1 to 44.3% and from 16.0% to 63.6%, respectively. The total phenotypic variance explained by all the QTLs for each trait ranged from 35.8% to 71.3%, showing that the expression of PNUE and related characters depends signifycantly upon genetic factors. Both S-QTLs and E-QTLs may be useful for marker-assisted selection (MAS) to develop higher PNUE genotypes.

分类号：

相关文献

[1]Mapping QTL with Main Effect, Digenic Epistatic and QTL x Environment Interactions of Panicle Related Traits in Rice (Oryza sativa). Leng, Yujia,Huang, Lichao,Chen, Long,Ren, Deyong,Yang, Yaolong,Zhang, Guangheng,Hu, Jiang,Zhu, Li,Guo, Longbiao,Qian, Qian,Zeng, Dali,Leng, Yujia,Lin, Yongjun,Leng, Yujia,Lin, Yongjun,Xue, Dawei. 2017

[2]Genetic dissection of growth traits in a Chinese indigenous x commercial broiler chicken cross. Sheng, Zheya,Hu, Xiaoxiang,Li, Ning,Sheng, Zheya,Pettersson, Mats E.,Shen, Xia,Carlborg, Orjan,Luo, Chenglong,Qu, Hao,Shu, Dingming. 2013

[3]Bayesian Analysis for Genetic Architectures of Body Weights and Morphological Traits Using Distorted Markers in Japanese Flounder Paralichthys olivaceus. Cui, Yan,Wang, Hongwei,Liu, Haijin,Yang, Runqing,Cui, Yan,Qiu, Xuemei.

[4]QTL mapping and epistatic interaction analysis in asparagus bean for several characterized and novel horticulturally important traits. Xu, Pei,Wu, Xiaohua,Wang, Baogen,Hu, Tingting,Lu, Zhongfu,Liu, Yonghua,Qin, Dehui,Wang, Sha,Li, Guojing. 2013

[5]Quantitative trait loci mapping of yield and related traits using a high-density genetic map of maize. Chen, Lin,Li, Chunhui,Li, Yongxiang,Song, Yanchun,Zhang, Dengfeng,Wang, Tianyu,Li, Yu,Shi, Yunsu.

[6]Detection of epistatic interactions of three QTLs for heading date in rice using single segment substitution lines. Ding, Han-Feng,Liu, Xu,Li, Run-Fang,Wang, Wen-Ying,Zhang, Y.,Zhang, Xiao-Dong,Yao, Fang-Yin,Li, Guang-Xian,Jiang, Ming-Song,Ding, Han-Feng.

[7]Advanced Backcross QTL Analysis for the Whole Plant Growth Duration Salt Tolerance in Rice (Oryza sativa L.). Chai Lu,Zhang Jian,Zhang Fan,Zheng Tian-qing,Zhao Xiu-qing,Wang Wen-sheng,Xu Jian-long,Li Zhi-kang,Pan Xiao-biao,Jauhar, Ali. 2014

[8]A Rare Allele of GS2 Enhances Grain Size and Grain Yield in Rice. Hu, Jiang,Wang, Yuexing,Fang, Yunxia,Xu, Jie,Yu, Haiping,Shi, Zhenyuan,Pan, Jiangjie,Zhang, Dong,Zhu, Li,Dong, Guojun,Guo, Longbiao,Zeng, Dali,Zhang, Guangheng,Xie, Lihong,Qian, Qian,Zeng, Longjun,Kang, Shujing,Xiong, Guosheng,Qian, Qian,Li, Jiayang,Li, Jiayang. 2015

[9]Bayesian dissection for genetic architecture of traits associated with nitrogen utilization efficiency in rice. Yang, Runqing,Piao, Zhongze,Li, Maobai,Zhang, Jianming,Wang, Hui,Li, Peide,Zhu, Chunmei,Luo, Zhixiang,Lee, Jungro. 2009

[10]QTL Mapping by Whole Genome Re-sequencing and Analysis of Candidate Genes for Nitrogen Use Efficiency in Rice. Xia, Xiuzhong,Zhang, Zongqiong,Nong, Baoxuan,Zeng, Yu,Deng, Guofu,Li, Danting,Xiong, Faqian,Wu, Yanyan,Gao, Ju. 2017

[11]Analysis of QTLs for seed low temperature germinability and anoxia germinability in rice (Oryza sativa L.). Jiang, L,Liu, SJ,Hou, MY,Tang, JY,Chen, LM,Zhai, HQ,Wan, JM. 2006

[12]QTL mapping reveals a tight linkage between QTLs for grain weight and panicle spikelet number in rice. Luo, Xiao,Lee, Hyun-Sook,Kim, Dong-Min,Balkunde, Sangshetty,Kang, Ju-Won,Ahn, Sang-Nag,Ji, Shi-Dong,Yuan, Ping-Rong. 2013

[13]Dissection of combining ability for yield and related traits using introgression lines in the background of a key restorer line in rice (Oryza sativa L.). Xiang, Chao,Zhang, Hongjun,Wang, Jie,Wang, Wensheng,Gao, Yongming,Wang, Hui,Xia, Jiafa,Ye, Guoyou.

[14]Genetic analysis for rice seedling vigor and fine mapping of a major QTL qSSL1b for seedling shoot length. Zhang, Anpeng,Liu, Chaolei,Chen, Guang,Hong, Kai,Gao, Yang,Tian, Peng,Peng, Youlin,Zhang, Bin,Ruan, Banpu,Jiang, Hongzhen,Guo, Longbiao,Qian, Qian,Gao, Zhenyu.

[15]Genetic Overlap in the Quantitative Resistance of Rice at the Seedling and Adult Stages to Xanthomonas oryzae pv. oryzae. Zhou, Yong-Li,Xie, Xue-Wen,Xu, Mei-Rong,Zang, Jin-Ping,Zhu, Ling-Hua,Xu, Jian-Long,Li, Zhi-Kang,Li, Zhi-Kang.

[16]Identification of QTLs for rice flower opening time in two environments. Zhang, Meng,Zhang, Huali,Dai, Dongqing,Li, Ximing,Chen, Junyu,Ma, Liangyong,Bao, Jinsong.

[17]The way to a more precise sheath blight resistance QTL in rice. Zeng, Yuxiang,Ji, Zhijuan,Yang, Changdeng.

[18]Fine mapping of a major QTL for flag leaf width in rice, qFLW4, which might be caused by alternative splicing of NAL1. Chen, Mingliang,Luo, Ju,Shao, Gaoneng,Wei, Xiangjin,Tang, Shaoqing,Sheng, Zhonghua,Song, Jian,Hu, Peisong,Chen, Mingliang.

[19]Association Mapping and Marker Development of Genes for Starch Lysophospholipid Synthesis in Rice. Tong Chuan,Bao Jin-Song,Tong Chuan,Liu Lei,Waters, Daniel L. E.. 2016

[20]QTL detection of amino acid content in grains of rice using advanced backcross introgression lines. Cheng, Li-Rui,Luo, Cheng-Gang,Xu, Jian-Long. 2013

作者其他论文更多>>

Diversity of rhizosphere microbial communities in different rice varieties and their diverse adaptive responses to saline and alkaline stress

作者：Zhong, Yu;Wu, Tao;Fan, Wenbo;Su, Haoyu;Li, Ruoyu;Jiang, Wenzhu;Du, Xinglin;Ma, Ziming;Chi, Hai;Ma, Ziming

关键词：saline stress; alkaline stress; rice; rhizosphere microbiota; metagenomic analysis
Starch Properties of Roasting Rice from Naturally High-Resistant Starch Rice Varieties

作者：Yang, Ruifang;Tang, Jianhao;Zhao, Qi;Piao, Zhongze;Wan, Changzhao;Bai, Jianjiang;Lee, Gangseob

关键词：roasting; resistant starch; rice; digestion rate
Identification and characterization of the chalkiness endosperm gene CHALK-H in rice (Oryza sativa L.)

作者：Piao, Ri-hua;Chen, Mo-jun;Meng, Fan-mei;Qi, Chun-yan;Jin, Yong-mei;Yan, Yong-feng;Koh, Hee-jong;Jin, Yong-mei;Koh, Hee-jong;Song, An-qi;Gao, Meng-meng;Song, An-qi

关键词：CHALK -H; Seryl-tRNA synthetase; chalkiness; rice
Subchronic Toxicological Evaluation of Xiushui 134Bt Transgenic Insect-Resistant Rice in Rats

作者：Yang, Ruifang;Piao, Zhongze;Tang, Jianhao;Wan, Changzhao;Bai, Jianjiang;Lee, Gangseob

关键词：GM rice; safety assessment; insect resistance; Bacillus thuringiensis; toxicity
Evidence for evolution and selection of drought-resistant genes based on high-throughput resequencing in weedy rice

作者：Han, Bing;Cui, Di;Ma, Xiaoding;Cao, Guilan;Zhang, Hui;Han, Longzhi;Koh, Hee-Jong

关键词：Ca2+ and K+ flux; drought resistance; genome-wide association study; knockout; Oryza sativa f; spontanea; overexpression; selection analysis; weedy rice
OsDREB2B, an AP2/ERF transcription factor, negatively regulates plant height by conferring GA metabolism in rice

作者：Ma, Ziming;Wu, Tao;Hu, Lanjuan;Jiang, Wenzhu;Du, Xinglin;Jin, Yong-Mei;Zhang, Ying

关键词：AP2; ERF transcription factor; OsDREB2B; plant height; leaf sheath; gibberellin; rice
Identification of QTLs for cold tolerance at the booting and flowering stages in rice (Oryza sativa L.)

作者：Zhang, Lina;Tang, Jianghong;Cui, Di;Ma, Xiaoding;Han, Bing;Cao, Guilan;Han, Longzhi;Tang, Jianghong;Zhao, Zhengwu;Tang, Cuifeng;Ma, Xinxiang;Koh, Hee-Jong

关键词：Cold tolerance; Rice; QTL; Booting and flowering stages; qCtb5

Identification of QTLs associated with physiological nitrogen use efficiency in rice

作者其他论文 更多>>

Diversity of rhizosphere microbial communities in different rice varieties and their diverse adaptive responses to saline and alkaline stress

Starch Properties of Roasting Rice from Naturally High-Resistant Starch Rice Varieties

Identification and characterization of the chalkiness endosperm gene CHALK-H in rice (Oryza sativa L.)

Subchronic Toxicological Evaluation of Xiushui 134Bt Transgenic Insect-Resistant Rice in Rats

Evidence for evolution and selection of drought-resistant genes based on high-throughput resequencing in weedy rice

OsDREB2B, an AP2/ERF transcription factor, negatively regulates plant height by conferring GA metabolism in rice

Identification of QTLs for cold tolerance at the booting and flowering stages in rice (Oryza sativa L.)

作者其他论文更多>>