Comparisons of four testers in evaluating 27 CIMMYT and Chinese maize populations

文献类型: 外文期刊

第一作者: Li, M. S.

作者: Li, M. S.;Li, X. H.;Deng, L. W.;Zhang, D. G.;Bai, L.;Zhang, S. H.

作者机构:

关键词: maize;tester;heterotic group;heterotic pattern

期刊名称:MAYDICA ( 影响因子:0.542; 五年影响因子:0.605 )

ISSN: 0025-6153

年卷期: 2007 年 52 卷 2 期

页码:

收录情况: SCI

摘要: The choice of testers is important for evaluating combining ability, and defining heterotic groups and patterns of maize germplasm effectively and accurately. This research was conducted on 108 testcrosses among 27 populations and four testers in order to (i) determine the effectiveness of testers to estimate general combining ability; (ii) select the best testers to determine heterotic groups and patterns. Seven trials were carried out in China. Each trial was arranged in alpha-lattice design (11 x 11) with three replications. Data for grain yield and agronomic traits were recorded. The variations among locations and genotypes were highly significant for all seven traits evaluated. The testers and populations showed significant variation for all seven traits evaluated. A high correlations between testers was observed for all traits. Testers HZ4 and Ye478 had large genetic distance and lowest correlation for grain yield when crossed with 27 populations, a finding that indicated these two lines as the best testers for classifying new germplasm into different heterotic groups and defining heterotic patterns in China.

分类号:

  • 相关文献

[1]Breeding potential of US maize germplasm for utilization in Chinese temperate conditions. Yong, Hongjun,Zhang, Xiaocong,Zhang, Degui,Zhang, Huanxin,Li, Mingshun,Weng, Jianfeng,Hao, Zhuanfang,Ci, Xiaoke,Bai, Li,Li, Xinhai,Zhang, Shihuang,Wang, Jianjun,Liu, Wenguo.

[2]Molecular characterization of global maize breeding germplasm based on genome-wide single nucleotide polymorphisms. Lu, Yanli,Yan, Jianbing,Taba, Suketoshi,Hao, Zhuanfang,Shah, Trushar,Crouch, Jonathan H.,Xu, Yunbi,Lu, Yanli,Gao, Shibin,Rong, Tingzhao,Guimaraes, Claudia T.,Parentoni, Sidney N.,Hao, Zhuanfang,Zhang, Shihuang,Chen, Shaojiang,Li, Jiansheng,Vivek, Bindiganavile S.,Magorokosho, Cosmos,Mugo, Stephen,Makumbi, Dan.

[3]Breeding potential of maize germplasm populations to improve yield and predominant heterotic pattern in Northeast China. Yong, Hongjun,Zhang, Fangjun,Zhang, Xiaocong,Zhang, Degui,Li, Mingshun,Weng, Jianfeng,Hao, Zhuanfang,Zhang, Shihuang,Li, Xinhai,Jin, Zhenguo,Gao, Li,Zhang, Lin,Liu, Xianjun.

[4]RFLP detection of genetic variation of maize inbred lines. Li, XH,Fu, JH,Zhang, SH,Yuan, LX,Li, MS. 2000

[5]Construction and characterization of a bacterial artificial chromosome library of the maize inbred line Qi319. Mu, Chun Hua,Zhang, Fa Jun,Li, Wen Cai,Lu, Shou Ping,Meng, Zhao Dong,Liu, Xia,Mu, Chun Hua,Liu, Xia,Yang, Yu,Li, Guang Cun. 2016

[6]Genome-wide high-resolution mapping of DNA methylation identifies epigenetic variation across embryo and endosperm in Maize (Zea may). Wang, Pengfei,Ma, Chuanxi,Wang, Pengfei,Xia, Han,Zhang, Ye,Zhao, Shuzhen,Zhao, Chuanzhi,Hou, Lei,Li, Changsheng,Li, Aiqin,Wang, Xingjun. 2015

[7]ZmFKBP20-1 improves the drought and salt tolerance of transformed Arabidopsis. Yu, Yanli,Li, Yanjiao,Zhao, Meng,Li, Wencai,Sun, Qi,Li, Wenlan,Meng, Zhaodong,Jia, Fengjuan,Jia, Fengjuan,Li, Nana. 2017

[8]Effects of pollination-prevention on leaf senescence and post-silking nitrogen accumulation and remobilization in maize hybrids released in the past four decades in China. Guo, Song,Chen, Fanjun,Yuan, Lixing,Mi, Guohua,Guo, Song.

[9]Determination of 16 Mycotoxins in Maize by Ultrahigh-Performance Liquid Chromatography-Tandem Mass Spectrometry. Li, Xia,Liu, Bin,Wang, Fengen,Ma, Xinfeng,Li, Zengmei,Guo, Dongliang,Wang, Yutao,Deng, Ligang,Zhang, Shuqiu,Wan, Fachun. 2018

[10]Meta-analysis of constitutive QTLs for disease resistance in maize and its synteny conservation in the rice genome. Zhao, L.,Wang, Q. Y.,Liu, H. J.,Zhang, C. X.,Li, X. H.. 2015

[11]Genome-wide identification, expression analysis of auxin-responsive GH3 family genes in maize (Zea mays L.) under abiotic stresses. Feng, Shangguo,Yang, Yanjun,Xu, Mingfeng,Wang, Huizhong,Shen, Chenjia,Yue, Runqing,Zhang, Lei. 2015

[12]Silver nanoparticles deteriorate the mutual interaction between maize (Zea mays L.) and arbuscular mycorrhizal fungi: a soil microcosm study. Cao, Jiling,Feng, Youzhi,Lin, Xiangui,Cao, Jiling,Feng, Youzhi,Lin, Xiangui,Cao, Jiling,Feng, Youzhi,Lin, Xiangui,Cao, Jiling,He, Shiying. 2017

[13]The changes of organelle ultrastructure and Ca2+ homeostasis in maize mesophyll cells during the process of drought-induced leaf senescence. Ma, Yuan-Yuan,Guo, Xiu-Lin,Liu, Zi-Hui,Ma, Yuan-Yuan,Shao, Hong-Bo,Shao, Hong-Bo,Liu, Bin-Hui. 2011

[14]Establishment of a core collection for maize germplasm preserved in Chinese National Genebank using geographic distribution and characterization data. Li, Y,Shi, YS,Cao, YS,Wang, TY. 2004

[15]Genome-wide analysis of maize NLP transcription factor family revealed the roles in nitrogen response. Ge, Min,Jiang, Lu,Wang, Yuancong,Lv, Yuanda,Zhou, Ling,Liang, Shuaiqiang,Bao, Huabin,Zhao, Han,Liu, Yuhe. 2018

[16]Maize production emulation system based on cooperative models. Li, Shijuan,Zhu, Yeping. 2008

[17]Dissection of Recombination Attributes for Multiple Maize Populations Using a Common SNP Assay. Guan, Haiying,Guan, Haiying,Guan, Haiying,Ali, Farhan,Pan, Qingchun. 2017

[18]Genome-wide analysis of the maize (Zea may L.) CPP-like gene family and expression profiling under abiotic stress. Song, X. Y.,Zhang, Y. Y.,Wu, F. C.,Zhang, L.. 2016

[19]Expression analysis of genes encoding double B-box zinc finger proteins in maize. Li, Wenlan,Sun, Qi,Li, Wencai,Yu, Yanli,Zhao, Meng,Meng, Zhaodong,Wang, Jingchao. 2017

[20]Candidate Loci for Yield-Related Traits in Maize Revealed by a Combination of MetaQTL Analysis and Regional Association Mapping. Chen, Lin,An, Yixin,Li, Yong-Xiang,Li, Chunhui,Shi, Yunsu,Song, Yanchun,Zhang, Dengfeng,Wang, Tianyu,Li, Yu. 2017

作者其他论文 更多>>

微信小程序