Root genetic research, an opportunity and challenge to rice improvement

文献类型: 外文期刊

第一作者: Cheng, Shihua

作者: Cheng, Shihua

作者机构:

关键词: Rice (Oryza sativa L.);Root;Genetic research

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: Rice is one of the most important cereal crops, feeding more than 50% population of the world. To meet the demand of increasing population, rice production has to be improved continually. As a very important part of rice plant, root system plays multiple roles in rice growth: anchorage of the plant, acquisition of water and nutrient elements, and biosynthesis of amino acids and hormones, etc. Almost all of the hot spots about rice research are associated with rice root: drought tolerance, lodging resistance, and efficient use of nutrition, the goal is to increase the grain yield with desirable seed quality. Although the understanding about rice root has been expanded in the last decades, there remain much to be done about root morphology and physiology, especially in root genetics. Rice root research is an exciting and focusing field in recent years. More and more researches on rice root genetics have been made. There is a close relation between above ground traits and underground roots, providing an alternative approach for rice genetic improvement. A number of genes associated with root architecture and physiological functions have been identified, or cloned. It provides an opportunity to further improve rice based on molecular assisted selection. Root traits improvement should be taken into account in future breeding programs in rice. However, root research is still a consuming and difficult work, because it was largely influenced by the complex underground environment. This paper reviewed the progress in rice root genetic research, and discussed its prospects

分类号: S

  • 相关文献

[1]Differential regulation of proteins in rice (Oryza sativa L.) under iron deficiency. Chen, Lin,Ding, Chengqiang,Xu, Junxu,Wang, Shaohua,Ding, Yanfeng,Zhao, Xiufeng,Mohammad, Alim Abdul.

[2]Comparative Proteomic Analysis Reveals Differential Root Proteins in Medicago sativa and Medicago truncatula in Response to Salt Stress. Long, Ruicai,Zhang, Tiejun,Kang, Junmei,Cong, Lili,Gao, Yanli,Yang, Qingchuan,Li, Mingna,Sun, Yan,Liu, Fengqi. 2016

[3]OsEF3, a homologous gene of Arabidopsis ELF3, has pleiotropic effects in rice. Fu, C.,Yang, X. O.,Chen, W.,Ma, Y.,Hu, J.,Li, S.,Fu, C.,Yang, X. O.,Chen, W.,Ma, Y.,Hu, J.,Li, S.,Fu, C.,Chen, X.. 2009

[4]Transcription profiles of boron-deficiency-responsive genes in citrus rootstock root by suppression subtractive hybridization and cDNA microarray. Zhou, Gao-Feng,Liu, Yong-Zhong,Sheng, Ou,Wei, Qing-Jiang,Yang, Cheng-Quan,Peng, Shu-Ang,Zhou, Gao-Feng,Sheng, Ou,Wei, Qing-Jiang. 2015

[5]Proteomic analysis of responsive root proteins of Fusarium oxysporum-infected watermelon seedlings. Zhang, Man,Xu, Jinhua,Liu, Guang,Yao, Xiefeng,Ren, Runsheng,Yang, Xingping. 2018

[6]De novo sequencing and analysis of root transcriptome using 454 pyrosequencing to discover putative genes associated with drought tolerance in Ammopiptanthus mongolicus. Zhou, Yijun,Gao, Fei,Liu, Ran,Feng, Jinchao,Gao, Fei,Li, Hongjie. 2012

[7]Effects of phosphorus and zinc fertilizer on cadmium uptake and distribution in flax and durum wheat. Jiao, Y,Grant, CA,Bailey, LD. 2004

[8]Individual and combined effects of soil waterlogging and compaction on physiological characteristics of wheat in southwestern China. Tang, Yonglu,Li, Chaosu,Li, Zhuo,Wu, Chun,McHugh, A. D.. 2018

[9]Ammonium affects cell viability to inhibit root growth in Arabidopsis. Qin, Cheng,Wu, Ping,Yi, Ke-ke. 2011

[10]iTRAQ-based quantitative proteomic analysis of wheat roots in response to salt stress. Jiang, Qiyan,Niu, Fengjuan,Sun, Xianjun,Hu, Zheng,Zhang, Hui,Li, Xiaojuan.

[11]Effects of NPK Deficiencies on Root Architecture and Growth of Cucumber. Zhang, Bai-Ge,Chen, Qiong-Xian,Luo, Shao-Bo,Zhang, Chang-Yuan,Yang, Qiu. 2012

[12]Identification of differentially expressed genes in sunflower (Helianthus annuus) leaves and roots under drought stress by RNA sequencing. Liang, Chunbo,Huang, Xutang,Liang, Chunbo,Wang, Wenjun,Wang, Jing,Ma, Jun,Li, Cen,Zhou, Fei,Zhang, Shuquan,Yu, Ying,Zhang, Liguo,Huang, Xutang,Li, Weizhong. 2017

[13]Isolation and Characterization of Indole Acetic Acid Producing Root Endophytic Bacteria and Their Potential for Promoting Crop Growth. Yu, J.,Yu, J.,Yu, Z. H.,Wang, G. H.,Liu, X. B.,Fan, G. Q.. 2016

[14]Rhizobium wenxiniae sp nov., an endophytic bacterium isolated from maize root. Gao, Jun-lian,Wang, Xu-ming,Sun, Pengbo,Lv, Fan-yang,Mao, Xiao-jie,Sun, Jian-guang.

[15]Cloning and characterization of a putative 12-oxophytodienoic acid reductase cDNA induced by osmotic stress in roots of foxtail millet. Zhang, Jin-Peng,Liu, Ting-Song,Zheng, Jun,Jin, Zheng,Zhu, Yun,Guo, Jiu-Feng,Wang, Guo-Ying.

[16]Locating QTLs controlling several adult root traits in an elite Chinese hybrid rice. Cao, Li Yong.

[17]A distinctive root-inhabiting denitrifying community with high N2O/(N2O+N-2) product ratio. Ai, Chao,Liang, Guoqing,Wang, Xiubin,Sun, Jingwen,He, Ping,Zhou, Wei,He, Ping.

[18]Proteomic analysis reveals growth inhibition of soybean roots by manganese toxicity is associated with alteration of cell wall structure and lignification. Chen, Zhijian,Yan, Wei,Sun, Lili,Tian, Jiang,Liao, Hong,Chen, Zhijian,Yan, Wei,Sun, Lili,Liao, Hong.

[19]Effects of Organic Fertilizer on the Contents and Distribution of Heavy Metals in Spinach. Rui Yukui,Zheng Chuangmu,Wu Wei.

[20]Responses of Wheat Roots to Exogenous Selenium Supply Under Enhanced Ultraviolet-B. Yao, Xiaoqin,Chu, Jianzhou,Ba, Chaojie,Yao, Xiaoqin. 2010

作者其他论文 更多>>

微信小程序