Mapping QTLs for improving grain yield using the USDA rice mini-core collection

文献类型: 外文期刊

第一作者: Li, Xiaobai

作者: Li, Xiaobai;Jia, Limeng;Wu, Dianxing;Li, Xiaobai;Agrama, Hesham;Jia, Limeng;Moldenhauer, Karen;Li, Xiaobai;Yan, Wengui;Jia, Limeng;Jackson, Aaron;McClung, Anna;Shen, Xihong;Yeater, Kathleen

作者机构:

关键词: Association mapping;Germplasm;Grain yield;Linkage disequilibrium (LD);Rice

期刊名称:PLANTA ( 影响因子:4.116; 五年影响因子:4.316 )

ISSN:

年卷期:

页码:

收录情况: SCI

摘要: Yield is the most important and complex trait for genetic improvement in crops, and marker-assisted selection enhances the improvement efficiency. The USDA rice mini-core collection derived from over 18,000 accessions of global origins is an ideal panel for association mapping. We phenotyped 203 O. sativa accessions for 14 agronomic traits and identified 5 that were highly and significantly correlated with grain yield per plant: plant height, plant weight, tillers, panicle length, and kernels/branch. Genotyping with 155 genome-wide molecular markers demonstrated 5 main cluster groups. Linkage disequilibrium (LD) decayed at least 20 cM and marker pairs with significant LD ranged from 4.64 to 6.06% in four main groups. Model comparisons revealed that different dimensions of principal component analysis affected yield and its correlated traits for mapping accuracy, and kinship did not improve the mapping in this collection. Thirty marker-trait associations were highly significant, 4 for yield, 3 for plant height, 6 for plant weight, 9 for tillers, 5 for panicle length and 3 for kernels/branch. Twenty-one markers contributed to the 30 associations, because 8 markers were co-associated with 2 or more traits. Allelic analysis of OSR13, RM471 and RM7003 for their co-associations with yield traits demonstrated that allele 126 bp of RM471 and 108 bp of RM7003 should receive greater attention, because they had the greatest positive effect on yield traits. Tagging the QTLs responsible for multiple yield traits may simultaneously help dissect the complex yield traits and elevate the efficiency to improve grain yield using marker-assisted selection in rice.

分类号: Q94

  • 相关文献

[1]Association analysis of physicochemical traits on eating quality in rice (Oryza sativa L.). Zhao, Wei-Guo,Kwon, Soon-Wook,Park, Yong-Jin,Zhao, Wei-Guo,Chung, Jong-Wook,Ma, Kyung-Ho,Kwon, Soon-Wook,Park, Yong-Jin,Lee, Jeong-Heui. 2013

[2]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

[3]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

[4]Association Mapping of Quantitative Trait Loci for Mineral Element Contents in Whole Grain Rice (Oryza sativa L.). Huang, Yan,Chen, Yaling,Tong, Chuan,Bao, Jinsong,Sun, Chengxiao,Min, Jie.

[5]Association mapping and genetic dissection of nitrogen use efficiency-related traits in rice (Oryza sativa L.). Liu, Zhiyi,Jiang, Yue,Tian, Yunlu,Yu, Jun,An, Hongzhou,Tang, Weijie,Sun, Juan,Tang, Jianpeng,Chen, Gaoming,Wang, Chunming,Wan, Jianmin,Zhu, Chengsong,Zhai, Huqu,Wan, Jianmin,Wang, Chunming.

[6]The effect of low water content on seed longevity. Hu, CL,Zhang, YL,Tao, M,Hu, XR,Jiang, CY. 1998

[7]Two compounds from allelopathic rice accession and their inhibitory activity on weeds and fungal pathogens. Xu, XH,Zhou, B,Hu, F,Zhang, CX,Zhang, MX.

[8]Genetic analysis of genetic basis of a physiological disorder "straighthead" in rice (Oryza sativa L.). Li, Xiaobai,Jia, Limeng,Wu, Dianxing,Yan, Wengui,Jackson, Aaron,Jia, Melissa,Li, Xiaobai,Jia, Limeng,Agrama, Hesham,Moldenhauer, Karen,Correa, Fernando.

[9]Yield and yield component analysis of early-season rice in southern China. Mo, Hailing,Qin, Gang,Luo, Zhiyong,Zhang, Zongqiong,Chen, Caihong. 2013

[10]Improving nitrogen fertilization in rice by site-specific N management. A review. Peng, Shaobing,Buresh, Roland J.,Dobermann, Achim,Huang, Jianliang,Cui, Kehui,Zhong, Xuhua,Zou, Yingbin,Tang, Qiyuan,Yang, Jianchang,Wang, Guanghuo,Liu, Yuanying,Hu, Ruifa,Zhang, Fusuo. 2010

[11]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.

[12]Overexpression of a glyoxalase gene, OsGly I, improves abiotic stress tolerance and grain yield in rice (Oryza sativa L.). Xiong, Fangjie,Yu, Xiaohong,Gong, Xiaoping,Liu, Yongsheng,Luo, Juntao,Jiang, Yudong,Kuang, Haochi,Gao, Bijun,Niu, Xiangli,Liu, Yongsheng,Liu, Yongsheng.

[13]Influence of the system of rice intensification on rice yield and nitrogen and water use efficiency with different N application rates. Zhao, Limei,Wu, Lianghuan,Lu, Xinghua,Zhao, Limei,Li, Yongshan,Zhu, Defeng,Uphoff, Norman.

[14]Recombination between DEP1 and NRT1.1B under japonica and indica genetic backgrounds to improve grain yield in rice. Zhao, Mingzhu,Zheng, Wenjing,Zhao, Mingzhu,Geng, Xin,Bi, Wenjing,Xu, Quan,Sun, Jian,Huang, Yuwei,Wang, Qingying,Xu, Zhengjin.

[15]Identification and characterization of quantitative trait loci for grain yield and its components under different nitrogen fertilization levels in rice (Oryza sativa L.). Tong, Han-hua,Xing, Yong-zhong,Luo, Li-jun,Tong, Han-hua,Chen, Liang,Li, Wei-ping,Mei, Han-wei,Yu, Xing-qiao,Xu, Xiao-yan,Luo, Li-jun,Tong, Han-hua,Zhang, Shan-qing. 2011

[16]Review grain yield and nitrogen use efficiency in rice production regions in China. Che Sheng-guo,Zhao Bing-qiang,Li Yan-ting,Yuan Liang,Li Wei,Lin Zhi-an,Hu Shu-Wen,Shen Bing. 2015

[17]Nitrogen accumulation, remobilization and partitioning in rice (Oryza sativa L.) under an improved irrigation practice. Lin, XQ,Zhou, WJ,Zhu, DF,Chen, HZ,Zhang, YP. 2006

[18]Days to heading 7, a major quantitative locus determining photoperiod sensitivity and regional adaptation in rice. Gao, He,Jin, Mingna,Zheng, Xiao-Ming,Chen, Jun,Zhang, Zhe,Sheng, Peike,Ma, Jin,Ma, Weiwei,Wang, Haiyang,Wu, Chuanyin,Wan, Jianmin,Gao, He,Zhou, Kunneng,Jiang, Ling,Liu, Shijia,Wan, Jianmin,Yuan, Dingyang,Xin, Yeyun,Deng, Huafeng,Yuan, Longping,Wang, Maoqing,Huang, Dongyi.

[19]Control of Rice Embryo Development, Shoot Apical Meristem Maintenance, and Grain Yield by a Novel Cytochrome P450. Yang, Weibing,Gao, Mingjun,Yin, Xin,Zeng, Longjun,Li, Qun,He, Zuhua,Yang, Weibing,Gao, Mingjun,Yin, Xin,Zeng, Longjun,Li, Qun,He, Zuhua,Liu, Jiyun,Wang, Junmin,Zhang, Xiaoming,Xu, Yonghan,Zhang, Shubiao.

[20]Prediction of hybrid grain yield performances in Indica Rice (Oryza sativa L.) with effect-increasing loci. Ling Yinghua,Yang Zhenglin,Zhao Fangming,Zhong Bingqiang,Sang Xianchun,He Guanghua,Zha Renming,Xie Rong.

作者其他论文 更多>>

微信小程序