Validation of quantitative trait loci for aluminum tolerance in Chinese wheat landrace FSW

文献类型: 外文期刊

第一作者: Dai, Jian

作者: Dai, Jian;Dai, Jian;Bai, Guihua;Zhang, Dadong;Dai, Jian;Hong, Delin

作者机构:

关键词: Chinese landrace;Aluminum tolerance;Simple sequence repeats;QTL mapping

期刊名称:EUPHYTICA ( 影响因子:1.895; 五年影响因子:2.181 )

ISSN: 0014-2336

年卷期: 2013 年 192 卷 2 期

页码:

收录情况: SCI

摘要: Aluminum (Al) toxicity is one of the major constraints for wheat production in acidic soils worldwide and use of Al-tolerant cultivars is one of the most effective approaches to reduce Al damage in the acidic soils. A Chinese landrace, FSW, shows a high level of tolerance to Al toxicity and a mapping population of recombinant inbred lines (RILs) was developed from a cross between FSW and Al-sensitive US spring wheat cultivar Wheaton to validate the quantitative trait loci (QTL) previously identified in FSW. The mapping population was evaluated for net root growth (NRG) during Al stress in a nutrient solution culture and hematoxylin staining score (HSS) of root tips after Al stress. After 132 simple sequence repeat (SSR) markers from three chromosomes that were previously reported to have the QTLs were analyzed in the population, two QTLs for Al tolerance from FSW were confirmed. The major QTL on chromosome 4DL co-segregated with the Al-activated malate transporter gene (ALMT1), however, sequence analysis of the promoter region (Ups4) of ALMT1 gene indicated that FSW contained a marker allele that is different from the one that was reported to condition Al tolerance in the Brazilian source. Another QTL on chromosome 3BL showed a minor effect on Al tolerance in the population. The two QTLs accounted for about 74.9 % of the phenotypic variation for HSS and 72.1 % for NRG and demonstrated an epistatic effect for both HSS and NRG. SSR markers closely linked to the QTLs have potential to be used for marker-assisted selection (MAS) to improve Al tolerance in wheat breeding programs.

分类号:

  • 相关文献

[1]The genetic basic and fine-mapping of a stable quantitative-trait loci for aluminium tolerance in rice. Xue, Y.,Jiang, L.,Su, N.,Wang, J. K.,Deng, P.,Ma, J. F.,Zhai, H. Q.,Wan, J. M..

[2]TaALMT1 promoter sequence compositions, acid tolerance, and Al tolerance in wheat cultivars and landraces from Sichuan in China. Dai, S. F.,Liu, D. C.,Wei, Y. M.,Zheng, Y. L.,Wen, D. J.,Zhao, L.,Yan, Z. H.,Pu, Z. J.. 2013

[3]Wheat genotypes differing in aluminum tolerance differ in their growth response to CO2 enrichment in acid soils. Tian, Qiuying,Zhang, Xinxin,Gao, Yan,Bai, Wenming,Zhang, Wen-Hao,Ge, Feng,Ge, Feng,Zhang, Wen-Hao,Ma, Yibing. 2013

[4]Aluminum tolerance in Centipedegrass (Eremochloa ophiuroides [Munro] Hack.): Excluding Al from root. Yan, Jun,Chen, Jingbo,Liu, Jianxiu,Yan, Jun,Yu, Li. 2012

[5]Identifying aluminum tolerance in rice with a molecular marker. Zhang, Peng,Zhong, Zhengzheng,Tong, Hanhua,Zhong, Kaizhen. 2017

[6]Identification of quantitative trait loci associated with aluminum tolerance in rice (Oryza sativa L.). Xue, Yong,Wan, Jianmin,Jiang, Ling,Wang, Chunming,Liu, Linglong,Zhang, Yuan-ming,Zhai, Huqu. 2006

[7]Different Aluminum Tolerance among Indica, Japonica and Hybrid Rice Varieties. Shu Chang,Wu Jing-hao,Shi Gao-ling,Lou Lai-qing,Deng Jun-xia,Cai Qing-sheng,Wan Jian-lin. 2015

[8]Nitric oxide improves aluminum tolerance by regulating hormonal equilibrium in the root apices of rye and wheat. He, Long-Fei,Gu, Ming-Hua,Li, Xiao-Feng,He, Hu-Yi. 2012

[9]Genome-wide transcriptomic and phylogenetic analyses reveal distinct aluminum-tolerance mechanisms in the aluminum-accumulating species buckwheat (Fagopyrum tataricum). Zhu, Haifeng,Zhu, Yifang,Zou, Jianwen,Zhao, Fang-Jie,Huang, Chao-Feng,Wang, Hua. 2015

[10]QTL mapping for fiber quality traits across multiple generations and environments in upland cotton. Fu-Ding Sun,Jian-Hong Zhang,Shu-Fang Wang,Wan-Kui Gong,Yu-Zhen Shi,Ai-Ying Liu,Jun-Wen Li,Ju-Wu Gong,Hai-Hong Shang,You-Lu Yuan.

[11]Genetic variation of main parents of hybrid rice in China was revealed with simple sequence repeat markers. Li, YH,Xiao, H,Zhang, CQ,Hu, GC,Yu, YH,Jia, JZ,Sun, ZX. 1999

[12]Development of simple sequence repeats (SSR) markers of ramie and comparison of SSR and inter-SSR marker systems. Zhou, JL,Jie, YC,Jiang, YB,Zhong, YL,Liu, YH,Zhang, J. 2005

[13]Association Analysis of the Amino Acid Contents in Rice. Zhao, Weiguo,Chung, Jong-Wook,Park, Yong-Jin,Zhao, Weiguo,Park, Eun-Jin,Chung, Ill-Min,Ahn, Joung-Kuk,Kim, Gwang-Ho,Zhao, Weiguo. 2009

[14]Combining ability and heterotic grouping of ten temperate, subtropical and tropical quality protein maize inbreds. Fan, XM,Tan, J,Yang, JY,Chen, HM. 2004

[15]Identification and mapping of a rice blast resistance gene Pi-g(t) in the cultivar Guangchangzhan. Zhou, JH,Wang, JL,Xu, JC,Lei, CL,Ling, ZZ. 2004

[16]Heterotic grouping for tropical and temperate maize inbreds by analyzing combining ability and SSR markers. Fan, XM,Tan, J,Chen, HM,Yang, JY. 2003

[17]Development and characterization of novel transcriptome-derived microsatellites for genetic analysis of persimmon. Luo, C.,Zhang, Q. L.,Luo, Z. R.,Luo, C.. 2014

[18]Molecular Mapping of the Major Resistance Quantitative Trait Locus qHS2.09 with Simple Sequence Repeat and Single Nucleotide Polymorphism Markers in Maize. Weng, Jianfeng,Hao, Zhuanfang,Xie, Chuanxiao,Li, Mingshun,Zhang, Degui,Bai, Li,Liu, Changlin,Zhang, Shihuang,Li, Xinhai,Liu, Xianjun,Wang, Zhenhua,Zhang, Lin,Wang, Jianjun.

[19]Genetic diversity among a founder parent and widely grown wheat cultivars derived from the same origin based on morphological traits and microsatellite markers. Li, X. J.,Xu, X.,Yang, X. M.,Li, X. Q.,Liu, W. H.,Gao, A. N.,Li, L. H.,Li, X. J.,Xu, X..

[20]Phenotypic and Genotypic Characterization of Phytophthora infestans Isolates from China. Li, Benjin,Chen, Qinghe,Lv, Xin,Lan, Chengzhong,Zhao, Jian,Qiu, Rongzhou,Weng, Qiyong.

作者其他论文 更多>>

微信小程序