Mapping of a major QTL for salt tolerance of mature field-grown maize plants based on SNP markers

文献类型: 外文期刊

第一作者: Zhao, Yanxin

作者: Zhao, Yanxin;Zhang, Ruyang;Xing, Jinfeng;Duan, Minxiao;Li, Jingna;Wang, Naishun;Wang, Wenguang;Zhang, Shasha;Zhang, Huasheng;Shi, Zi;Song, Wei;Zhao, Jiuran;Chen, Zhihui

作者机构:

关键词: Salt tolerance;QTL mapping;SNP;Plant height;Maize

期刊名称:BMC PLANT BIOLOGY ( 影响因子:4.215; 五年影响因子:4.96 )

ISSN: 1471-2229

年卷期: 2017 年 17 卷

页码:

收录情况: SCI

摘要: Background: Salt stress significantly restricts plant growth and production. Maize is an important food and economic crop but is also a salt sensitive crop. Identification of the genetic architecture controlling salt tolerance facilitates breeders to select salt tolerant lines. However, the critical quantitative trait loci (QTLs) responsible for the salt tolerance of field-grown maize plants are still unknown. Results: To map the main genetic factors contributing to salt tolerance in mature maize, a double haploid population (240 individuals) and 1317 single nucleotide polymorphism (SNP) markers were employed to produce a genetic linkage map covering 1462.05 cM. Plant height of mature maize cultivated in the saline field (SPH) and plant height-based salt tolerance index (ratio of plant height between saline and control fields, PHI) were used to evaluate salt tolerance of mature maize plants. A major QTL for SPH was detected on Chromosome 1 with the LOD score of 22.4, which explained 31.2% of the phenotypic variation. In addition, the major QTL conditioning PHI was also mapped at the same position on Chromosome 1, and two candidate genes involving in ion homeostasis were identified within the confidence interval of this QTL. Conclusions: The detection of the major QTL in adult maize plant establishes the basis for the map-based cloning of genes associated with salt tolerance and provides a potential target for marker assisted selection in developing maize varieties with salt tolerance.

分类号:

  • 相关文献

[1]Molecular mapping of quantitative trait loci for three kernel-related traits in maize using a double haploid population. Shi, Zi,Song, Wei,Xing, Jinfeng,Duan, Minxiao,Wang, Fengge,Tian, Hongli,Xu, Liwen,Wang, Shuaishuai,Su, Aiguo,Li, Chunhui,Zhang, Ruyang,Zhao, Yanxin,Luo, Meijie,Wang, Jidong,Zhao, Jiuran.

[2]Molecular mapping of quantitative trait loci for grain moisture at harvest in maize. Song, Wei,Shi, Zi,Xing, Jinfeng,Duan, Minxiao,Su, Aiguo,Li, Chunhui,Zhang, Ruyang,Zhao, Yanxin,Luo, Meijie,Wang, Jidong,Zhao, Jiuran.

[3]Dynamic QTL mapping for plant height in Upland cotton (Gossypium hirsutum). Shang, Lianguang,Abduweli, Abdugheni,Cai, Shihu,Liu, Fang,Wang, Kunbo,Wang, Yumei.

[4]QTL Analysis of Spike Morphological Traits and Plant Height in Winter Wheat (Triticum aestivum L.) Using a High-Density SNP and SSR-Based Linkage Map. Zhai, Huijie,Feng, Zhiyu,Li, Jiang,Liu, Xinye,Ni, Zhongfu,Sun, Qixin,Zhai, Huijie,Feng, Zhiyu,Li, Jiang,Liu, Xinye,Ni, Zhongfu,Sun, Qixin,Xiao, Shihe. 2016

[5]GA-20 oxidase as a candidate for the semidwarf gene sdw1/denso in barley. Jia, Qiaojun,Jia, Qiaojun,Westcott, Sharon,Lance, Reg,Li, Chengdao,Zhang, Jingjuan,Westcott, Sharon,Zhang, Xiao-Qi,Li, Chengdao,Bellgard, Mathew. 2009

[6]A genome-wide association study of plant height and primary branch number in rapeseed (Brassica napus). Li, Feng,Chen, Biyun,Xu, Kun,Gao, Guizhen,Yan, Guixin,Qiao, Jiangwei,Li, Jun,Li, Hao,Li, Lixia,Xiao, Xin,Zhang, Tianyao,Wu, Xiaoming,Li, Feng,Nishio, Takeshi.

[7]QTL mapping of flag leaf traits in common wheat using an integrated high-density SSR and SNP genetic linkage map. Wu, Qiuhong,Chen, Yongxing,Fu, Lin,Zhou, Shenghui,Chen, Jiaojiao,Zhao, Xiaojie,Zhang, Dong,Ouyang, Shuhong,Wang, Zhenzhong,Li, Dan,Wang, Guoxin,Zhang, Deyun,Yuan, Chengguo,You, Mingshan,Liu, Zhiyong,Yuan, Chengguo,Wang, Lixin,Han, Jun.

[8]Mapping QTL for stay-green and agronomic traits in wheat under diverse water regimes. Shi, Shenkui,Azam, Farooq I.,Li, Huihui,Chang, Xiaoping,Jing, Ruilian,Shi, Shenkui,Li, Baoyun,Azam, Farooq I..

[9]The maize d2003, a novel allele of VP8, is required for maize internode elongation. Lv, Hongkun,Zheng, Jun,Wang, Tianyu,Fu, Junjie,Zhang, Xiang,Shi, Yunsu,Wang, Guoying,Huai, Junling,Min, Haowei,Tian, Baohua.

[10]Characterization of a set of chromosome single-segment substitution lines derived from two sequenced elite maize inbred lines. Lu, Ming-Yang,Shang, Ai-Lan,Wang, Yu-Min,Xi, Zhang-Ying,Li, Xin-Hai. 2011

[11]Comparative LD mapping using single SNPs and haplotypes identifies QTL for plant height and biomass as secondary traits of drought tolerance in maize. Lu, Yanli,Xu, Jie,Yuan, Zhimin,Lan, Hai,Rong, Tingzhao,Lu, Yanli,Xu, Yunbi,Xu, Yunbi,Shah, Trushar.

[12]Dissection of the genetic architecture for grain quality-related traits in three RIL populations of maize (Zea mays L.). Wang, Zhiyong,Liu, Na,Ku, Lixia,Tian, Zhiqiang,Shi, Yong,Guo, Shulei,Su, Huihui,Zhang, Liangkun,Ren, Zhenzhen,Li, Guohui,Wang, Xiaobo,Zhu, Yuguang,Chen, Yanhui,Wang, Zhiyong,Liu, Na,Ku, Lixia,Tian, Zhiqiang,Shi, Yong,Guo, Shulei,Su, Huihui,Zhang, Liangkun,Ren, Zhenzhen,Li, Guohui,Wang, Xiaobo,Zhu, Yuguang,Chen, Yanhui,Liu, Na,Qi, Jianshuang,Zhang, Xin.

[13]QTL Mapping in Three Connected Populations Reveals a Set of Consensus Genomic Regions for Low Temperature Germination Ability in Zea mays L.. Li, Xuhui,Wang, Guihua,Li, Li,Jia, Guangyao,Ren, Lisha,Wang, Jianhua,Gu, Riliang,Fu, Junjie,Wang, Guoying,Lubberstedt, Thomas. 2018

[14]Identification of QTL for maize resistance to common smut by using recombinant inbred lines developed from the Chinese hybrid Yuyu22. Ding, Jun-qiang,Chander, Subhash,Li, Jian-sheng,Wang, Xiao-ming. 2008

[15]Molecular genetic mapping of a high-lysine mutant gene (opaque-16) and the double recessive effect with opaque-2 in maize. Yang, WP,Zheng, YL,Zheng, WT,Feng, R. 2005

[16]Genetic analysis of leaf morphology underlying the plant density response by QTL mapping in maize (Zea mays L.). Ku, Lixia,Ren, Zhenzhen,Shi, Yong,Su, Huihui,Wang, Zhiyong,Li, Guohui,Wang, Xiaobo,Zhu, Yuguang,Zhou, Jinlong,Chen, Yanhui,Ku, Lixia,Ren, Zhenzhen,Shi, Yong,Su, Huihui,Wang, Zhiyong,Li, Guohui,Wang, Xiaobo,Zhu, Yuguang,Zhou, Jinlong,Chen, Yanhui,Chen, Xiao,Qi, Jianshuang,Zhang, Xin.

[17]QTL mapping of resistance to sheath blight in maize (Zea Mays L.). Yang, H,Yang, JP,Rong, TZ,Tan, J,Qiu, ZG.

[18]Comparative Proteomics of Contrasting Maize, Genotypes Provides Insights into Salt-Stress Tolerance Mechanisms. Luo, Meijie,Zhao, Yanxin,Wang, Yuandong,Shi, Zi,Zhang, Panpan,Zhang, Yunxia,Song, Wei,Zhao, Jiuran. 2018

[19]Overexpression of a putative maize calcineurin B-like protein in Arabidopsis confers salt tolerance. Wang, Maoyan,Gu, Dan,Liu, Tingsong,Wang, Zhaoqiang,Guo, Xiying,Hou, Wei,Bai, Yunfeng,Chen, Xiaoping,Wang, Guoying.

[20]Cloning and characterization of a novel CBL-interacting protein kinase from maize. Zheng, Jun,Wang, Guoying,Zheng, Jun,Wang, Guoying,Zhao, Jinfeng,Zhao, Jinfeng,Sun, Zhenfei,Guo, Xiying,Dong, Zhigang,Huai, Junling,Gou, Mingyue,He, Junguang,Jin, Yongsheng,Wang, Jianhua,Zhao, Jinfeng,Sun, Zhenfei,Guo, Xiying,Dong, Zhigang,Huai, Junling,Gou, Mingyue,He, Junguang,Jin, Yongsheng,Wang, Jianhua.

作者其他论文 更多>>

微信小程序