Large-scale screening for maize drought resistance using multiple selection criteria evaluated under water-stressed and well-watered environments

文献类型: 外文期刊

第一作者: Hao, Zhuanfang

作者: Hao, Zhuanfang;Xie, Chuanxiao;Li, Xinhai;Zhang, Shihuang;Lu, Yanli;Crossa, Jose;Araus, Jose-Luis;Taba, Suketoshi;Xu, Yunbi;Lu, Yanli;Gao, Shibin;Pan, Guangtang;Rong, Tingzhao;Vivek, Bindiganavile S.;Magorokosho, Cosmos;Mugo, Stephen;Makumbi, Dan;Xu, Yunbi

作者机构:

关键词: chlorophyll;genetic diversity;developmental stage;genetic correlation;drought resistance;germplasm;water-stress;root capacitance;well-watered environment;global breeding program;final grain yield

期刊名称:FIELD CROPS RESEARCH ( 影响因子:5.224; 五年影响因子:6.19 )

ISSN:

年卷期:

页码:

收录情况: SCI

摘要: A total of 550 maize inbred lines collected from global breeding programs were evaluated for drought resistance under both well-watered and water-stressed environments. The evaluation was based on multiple measurements of biomass taken before and after the drought stress was applied using the normalized difference vegetation index (NDVI), along with other selection criteria including anthesis-silking interval, leaf senescence, chlorophyll content, root capacitance, final grain yield, and grain yield components. Kernel weight was the most stable trait under drought stress. Correlations between the primary trait (grain yield) and the secondary traits, except the root capacitance and ASI under water-stressed condition, were all significant. Root capacitance had relatively low heritability and low genetic correlation with other drought resistance criteria, and is not recommended as a drought resistance criterion. Significant reduction of NDVI values measured in the afternoon when the leaves became rolling, compared to those measured in the morning when the leaves were open, provides a reliable index for leaf rolling, which however was not significantly correlated with grain yield. NDVIs measured across different developmental stages were highly correlated with each other and with most of the secondary traits as well as, grain yield, indicating that NDVI can be used as a secondary trait for large-scale drought resistance screening. Regression models built based on non-yield drought criteria and yield components explained about 40% and 95% of the variation for the grain yield, respectively. Some maize lines developed in China for temperate regions showed strong drought resistance comparable to tropical maize lines when tested under tropical condition, indicating that temperate lines with a wide adaptability can be used in drought resistance breeding for both temperate and tropical environments

分类号: S

  • 相关文献

[1]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.

[2]Genetic diversity and phenotypic variation for drought resistance in alfalfa (Medicago sativa L.) germplasm collected for drought tolerance. Zhang, Tiejun,Kesoju, Sandya,Hu, Jinguo,Yu, Long-Xi,Zhang, Tiejun,Kesoju, Sandya,Greene, Stephanie L.,Fransen, Steven. 2018

[3]Genetic Diversity Revealed by Fluorescent-AFLP Markers for Apricot Germplasms in Shandong, China. Yuan, Z. H.,Yin, Y. L.,Feng, L. J.,Zhao, X. Q.,Wang, J. Z.,An, G. N.,Zhang, C. Y.. 2011

[4]The genetic diversity of annual wild soybeans grown in China. Dong, YS,Zhuang, BC,Zhao, LM,Sun, H,He, MY. 2001

[5]Genetic Diversity of Common Carpetgrass Revealed by Amplified Fragment Length Polymorphism Markers. Wang, Zan,Kenworthy, Kevin E.,Wang, Zan,Wu, Yanqi,Wang, Zan.

[6]Evaluation of genetic diversity and relationships in orchardgrass (Dactylis glomerata L.) germplasm based on SRAP markers. Zhang, Xin-Quan,Zeng, Bing,Lan, Ying,Yang, Wu-Yun.

[7]Genetic diversity within Oryza rufipogon germplasms preserved in Chinese field gene banks of wild rice as revealed by microsatellite markers. Zhang, Chi-Hong,Li, Dao-Yuan,Pan, Da-Jian,Jia, Ji-Zeng,Dong, Yu-Shen.

[8]Genetic diversity in oil and vegetable mustard (Brassica juncea) landraces revealed by SRAP markers. Wu, Xiao-ming,Song, Yunchun,Wu, Xiao-ming,Chen, Bi-yun,Lu, Guangyuan,Wang, Han-zhong,Xu, Kun,Gao Guizhan.

[9]Molecular diversity and population structure of Chinese green foxtail [Setaria viridis (L.) Beauv.] revealed by microsatellite analysis. Jia, Guanqing,Shi, Shenkui,Wang, Chunfang,Niu, Zhengang,Chai, Yang,Zhi, Hui,Diao, Xianmin.

[10]Genome composition and genetic diversity of Musa germplasm from China revealed by PCR-RFLP and SSR markers. Ning, Shu-Ping,Xu, Lin-Bing,Lu, Yan,Huang, Bing-Zhi,Ge, Xue-Jun. 2007

[11]Isolation and characterization of microsatellite loci from the mulberry, Morus L.. Zhao, WG,Mia, XX,Jia, SH,Pan, YL,Huang, Y.

[12]Generation and characterization of 24 novel EST derived microsatellites from tea plant (Camellia sinensis) and cross-species amplification in its closely related species and varieties. Zhao, Li-Ping,Liu, Zhen,Chen, Liang,Yao, Ming-Zhe,Wang, Xin-Chao.

[13]Molecular cloning and characterization of kiss1 in Brandt's voles (Lasiopodomys brandtii). Liu, Lan,Guo, Cong,Chen, Yan,Liu, Lan,Li, Zhengguang,Wang, Dawei,Li, Ning,Song, Ying,Liu, Xiaohui. 2017

[14]QTL mapping for resistance to SCMV in chinese maize germplasm. Zhang, SH,Li, XH,Wang, ZH,George, ML,Jeffers, D,Wang, FG,Liu, XD,Li, MS,Yuan, LX. 2003

[15]Expression of cadherin, aminopeptidase N and alkaline phosphatase genes in Cry1Ac-susceptible and Cry1Ac-resistant strains of Plutella xylostella (L.). Yang, Z-X.,Wu, Q-J.,Wang, S-L.,Chang, X-L.,Wang, J-H.,Guo, Z-J.,Lei, Y-Y.,Xu, B-Y.,Zhang, Y-J.,Yang, Z-X.. 2012

[16]Sensitivity of Bemisia Tabaci (Hemiptera: Aleyrodidae) to Several New Insecticides in China: Effects of Insecticide Type and Whitefly Species, Strain, and Stage. Xie, Wen,Liu, Yang,Wang, Shaoli,Wu, Qingjun,Pan, Huipeng,Yang, Xin,Guo, Litao,Zhang, Youjun. 2014

[17]Stage-Specific Expression of Resistance to Different Acaricides in Four Field Populations of Tetranychus urticae (Acari: Tetranychidae). Tang, Xiaofeng,Zhang, Youjun,Wu, Qingjun,Xie, Wen,Wang, Shaoli.

[18]Impact of epistasis and QTL x environment interaction on the accumulation of seed mass of soybean (Glycine max L. Merr.). Han, Yingpeng,Teng, Weili,Sun, Desheng,Du, Yuping,Li, Wenbin,Qiu, Lijuan,Han, Yingpeng,Xu, Xiangling.

[19]Construction of a sequence-based bin map and mapping of QTLs for downy mildew resistance at four developmental stages in Chinese cabbage (Brassica rapa L. ssp pekinensis). Yu, Shuancang,Su, Tongbing,Zhi, Shenghua,Zhang, Fenglan,Wang, Weihong,Zhang, Deshuang,Zhao, Xiuyun,Yu, Yangjun,Yu, Shuancang,Su, Tongbing,Zhi, Shenghua,Zhang, Fenglan,Wang, Weihong,Zhang, Deshuang,Zhao, Xiuyun,Yu, Yangjun,Yu, Shuancang,Su, Tongbing,Zhi, Shenghua,Zhang, Fenglan,Wang, Weihong,Zhang, Deshuang,Zhao, Xiuyun,Yu, Yangjun.

[20]Automated detection and identification of white-backed planthoppers in paddy fields using image processing. Yao Qing,Chen Guo-te,Wang Zheng,Zhang Chao,Yang Bao-jun,Tang Jian. 2017

作者其他论文 更多>>

微信小程序