Fine mapping of qHUS6.1, a quantitative trait locus for silicon content in rice (Oryza sativa L.)

文献类型: 外文期刊

第一作者: Gong JunYi

作者: Gong JunYi;Wu JiRong;Wang Kai;Fan YeYang;Zhuang JieYun

作者机构:

关键词: rice (Oryza sativa L.);silicon content;quantitative trait locus (QTL);fine mapping;residual heterozygous line (RHL);near isogenic line (NIL)

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

ISSN: 1001-6538

年卷期: 2010 年 55 卷 29 期

页码:

收录情况: SCI

摘要: Silicon is essential for optimal growth of rice (Oryza sativa L.). This study was conducted to fine map qHUS6.1, a quantitative trait locus (QTL) for rice hull silicon content previously located in the interval RM510-RM19417 on the short arm of chromosome 6, and to analyze the effect of this QTL on the silicon content in different organs of rice. Selfed progenies of a residual heterozygous line of rice were detected using 13 microsatellite markers in the vicinity of qHUS6.1. Three plants with overlapping heterozygous segments were selected. Three sets of near isogenic lines (NILs) were developed from the selfed progenies of the 3 plants. They were grown in a paddy field and the silicon contents of the hull, flag leaf, and stem were measured at maturity. Based on analyses of the phenotypic distribution and variance among different genotypic groups in the same NIL set, a significant genotypic effect was shown in the NIL set that was heterogenous in the interval RM19410-RM5815, whereas a significant effect was not found in the remaining 2 NIL sets that were heterogenous in either of the intervals RM4923-RM19410 or RM19417-RM204. On comparison among the physical positions of the 3 heterogenous segments, qHUS6.1 was delimited to a 64.2-kb region flanked by RM19410 and RM19417 that contains nine annotated genes according to the genome sequence of Nipponbare. This QTL showed strong effects on all of the three traits tested, and the enhancing alleles were always derived from the paternal line Milyang 46. The present study will facilitate the cloning of qHUS6.1 and the exploration of new genetic resources for QTL fine mapping.

分类号:

  • 相关文献

[1]Identification and validation of a novel major QTL for harvest index in rice (Oryza sativa L.). Zhang, Shaohong,He, Xiuying,Zhao, Junliang,Cheng, Yongsheng,Chen, Yuehan,Yang, Tifeng,Dong, Jingfang,Wang, Xiaofei,Liu, Qing,Liu, Wei,Mao, Xingxue,Fu, Hua,Chen, Zhaoming,Liao, Yaoping,Liu, Bin,Zhang, Shaohong,He, Xiuying,Zhao, Junliang,Cheng, Yongsheng,Chen, Yuehan,Yang, Tifeng,Dong, Jingfang,Wang, Xiaofei,Liu, Qing,Liu, Wei,Mao, Xingxue,Fu, Hua,Chen, Zhaoming,Liao, Yaoping,Liu, Bin,Xie, Zhimei,Xie, Zhimei. 2017

[2]Genetic dissection of seed storability using two different populations with a same parent rice cultivar N22. Lin, Qiuyun,Wang, Wenyan,Ren, Yakun,Jiang, Yimei,Sun, Ailing,Qian, Ying,Zhang, Yifei,He, Niqing,Ngo Thi Hang,Liu, Zhou,Li, Linfang,Liu, Linglong,Jiang, Ling,Wan, Jianmin,Wan, Jianmin.

[3]Genetic dissection of silicon uptake ability in rice (Oryza sativa L.). Wu, Q. -S.,Wan, X. -Y.,Su, N.,Cheng, Z. -J.,Wang, J. -K.,Lei, C. -L.,Zhang, X.,Jiang, L.,Ma, J. -F.,Wan, J. -M..

[4]Fine mapping of LOW TILLER 1, a gene controlling tillering and panicle branching in rice. Yu, Haiping,Qiu, Zhennan,Xu, Qiankun,Wang, Zhongwei,Zeng, Dali,Hu, Jiang,Zhang, Guangheng,Zhu, Li,Gao, Zhenyu,Chen, Guang,Guo, Longbiao,Qian, Qian,Ren, Deyong,Yu, Haiping.

[5]Genetic analysis and fine mapping of LH1 and LH2, a set of complementary genes controlling late heading in rice (Oryza sativa L.). Yang, Jin Shui,Luo, Xiao Jin,Wang, Feng,Li, Jin Hua,Gao, Li Jun,Li, Rong Bai,Gao, Han Liang,Deng, Guo Fu. 2012

[6]Fine mapping of a major quantitative trait locus, qFLL6.2, controlling flag leaf length and yield traits in rice (Oryza sativa L.). Shen, Bo,Yu, Wei-Dong,Zhu, Yu-Jun,Fan, Ye-Yang,Zhuang, Jie-Yun,Shen, Bo,Yu, Wei-Dong,Zhu, Yu-Jun,Fan, Ye-Yang,Zhuang, Jie-Yun,Shen, Bo,Yu, Wei-Dong. 2012

[7]Identification of a novel tillering dwarf mutant and fine mapping of the TDDL(T) gene in rice (Oryza sativa L.). Gao ZhenYu,Guo LongBiao,Liu Jian,Dong GuoJun,Hu Jiang,Qian Qian,Gao ZhenYu,Liu XiaoHui,Han Bin. 2009

[8]Genetic analysis and fine mapping of the pubescence gene GL6 in rice (Oryza sativa L.). Zeng YueHui,Zhu YongSheng,Lian Ling,Xie HongGuang,Zhang JianFu,Xie HuaAn,Zeng YueHui,Zhu YongSheng,Lian Ling,Xie HongGuang,Zhang JianFu,Xie HuaAn. 2013

[9]Fine mapping and candidate gene analysis of a novel PANICLE AND SPIKELET DEGENERATION gene in rice. Zhang, Yunhui,Lin, Jing,Fang, Xianwen,Xu, Furong,Song, Chunfeng.

[10]Genome-Wide Discovery of Microsatellite Markers from Diploid Progenitor Species, Arachis duranensis and A. ipaensis, and Their Application in Cultivated Peanut (A. hypogaea). Zhao, Chuanzhi,Qiu, Jingjing,Wang, Jiangshan,Ren, Xuezhen,Xia, Han,Wan, Shubo,Wang, Xingjun,Zhao, Chuanzhi,Qiu, Jingjing,Wang, Jiangshan,Ren, Xuezhen,Xia, Han,Wan, Shubo,Wang, Xingjun,Qiu, Jingjing,Ma, Changle,Wang, Xingjun,Agarwal, Gaurav,Guo, Baozhu,Agarwal, Gaurav,Varshney, Rajeev K.,Pandey, Manish K.,Bertioli, David J.. 2017

[11]Genetic Dissection of Novel QTLs for Resistance to Leaf Spots and Tomato Spotted Wilt Virus in Peanut (Arachis hypogaea L.). Pandey, Manish K.,Wang, Hui,Khera, Pawan,Guo, Baozhu,Pandey, Manish K.,Khera, Pawan,Vishwakarma, Manish K.,Kale, Sandip M.,Varshney, Rajeev K.,Pandey, Manish K.,Wang, Hui,Khera, Pawan,Culbreath, Albert K.,Guo, Baozhu,Holbrook, C. Corley,Wang, Xingjun. 2017

[12]Identification of salt-tolerant QTLs with strong genetic background effect using two sets of reciprocal introgression lines in rice. Cheng, Lirui,Wang, Yun,Meng, Lijun,Hu, Xia,Cui, Yanru,Sun, Yong,Zhu, Linghua,Xu, Jianlong,Li, Zhikang,Wang, Yun,Ali, Jauhar,Li, Zhikang.

[13]Length of internode and spike: how do they contribute to plant height of wheat at an individual QTL level?. Wang, L.,Cui, F.,Ding, A. M.,Li, J.,Zhao, C. H.,Li, X. F.,Feng, D. S.,Wang, H. G.,Wang, L.,Wang, J. P.,Cui, F.,Ding, A. M.,Li, J..

[14]A transposon insertion in FLOWERING LOCUS T is associated with delayed flowering in Brassica rapa. Zhang, Xueming,Meng, Lin,Liu, Bo,Hu, Yunyan,Cheng, Feng,Liang, Jianli,Wang, Xiaowu,Wu, Jian,Aarts, Mark G. M..

[15]Both major and minor QTL associated with plant height can be identified using near-isogenic lines in maize. Ding, Xiaoyu,Liu, Zhizhai,Ding, Xiaoyu,Wu, Xun,Chen, Lin,Li, Chunhui,Shi, Yunsu,Song, Yanchun,Zhang, Dengfeng,Wang, Tianyu,Li, Yu,Li, Yong-Xiang,Wu, Xun.

[16]QTL identification on two genetic systems for rapeseed glucosinolate and erucic acid contents over two seasons. Xu, J. F.,Xu, H. M.,Wen, J.,Shi, C. H.,Long, Y.,Meng, J. L.,Wu, J. G.,Zhao, Z. G..

[17]Potassium (K) effects and QTL mapping for K efficiency traits at seedling and adult stages in wheat. Kong, Fan-Mei,Guo, Ying,Liang, Xue,Wu, Chun-Hong,Wang, Ying-Ying,Zhao, Yan,Li, Si-Shen,Guo, Ying,Wang, Ying-Ying.

[18]Identification of quantitative trait loci for the dead leaf rate and the seedling dead rate under alkaline stress in rice. Qi, Dongling,Cao, Guilan,Han, Longzhi,Qi, Dongling,Guo, Guizhen,Zhang, Junguo,Zhang, Sanyuan,Han, Longzhi,Lee, Myung-Chul,Suh, Seok-Cheol,Zhou, Qingyang. 2008

[19]QTL mapping for the paste viscosity characteristics in rice (Oryza sativa L.). Bao, JS,Zheng, XW,Xia, YW,He, P,Shu, QY,Lu, X,Chen, Y,Zhu, LH. 2000

[20]Haplotype, molecular marker and phenotype effects associated with mineral nutrient and grain size traits of TaGS1 a in wheat. Guo, Ying,Sun, Jinjie,Zhang, Guizhi,Wang, Yingying,Kong, Fanmei,Zhao, Yan,Li, Sishen,Guo, Ying,Wang, Yingying. 2013

作者其他论文 更多>>

微信小程序