A Novel Sucrose-Regulatory MADS-Box Transcription Factor GmNMHC5 Promotes Root Development and Nodulation in Soybean (Glycine max [L.] Merr.)

文献类型: 外文期刊

第一作者: Liu, Wei

作者: Liu, Wei;Han, Xiangdong;Zhan, Ge;Zhao, Zhenfang;Wu, Cunxiang;Han, Xiangdong;Zhan, Ge;Zhao, Zhenfang;Feng, Yongjun

作者机构:

关键词: Glycine max;GmNMHC5;lateral roots development;MADS-box protein;sucrose;nodule building

期刊名称:INTERNATIONAL JOURNAL OF MOLECULAR SCIENCES ( 影响因子:5.923; 五年影响因子:6.132 )

ISSN: 1422-0067

年卷期: 2015 年 16 卷 9 期

页码:

收录情况: SCI

摘要: The MADS-box protein family includes many transcription factors that have a conserved DNA-binding MADS-box domain. The proteins in this family were originally recognized to play prominent roles in floral development. Recent findings, especially with regard to the regulatory roles of the AGL17 subfamily in root development, have greatly broadened their known functions. In this study, a gene from soybean (Glycine max [L.] Merr.), GmNMHC5, was cloned from the Zigongdongdou cultivar and identified as a member of the AGL17 subfamily. Real-time fluorescence quantitative PCR analysis showed that GmNMHC5 was expressed at much higher levels in roots and nodules than in other organs. The activation of expression was first examined in leaves and roots, followed by shoot apexes. GmNMHC5 expression levels rose sharply when the plants were treated under short-day conditions (SD) and started to pod, whereas low levels were maintained in non-podding plants under long-day conditions (LD). Furthermore, overexpression of GmNMHC5 in transgenic soybean significantly promoted lateral root development and nodule building. Moreover, GmNMHC5 is upregulated by exogenous sucrose. These results indicate that GmNMHC5 can sense the sucrose signal and plays significant roles in lateral root development and nodule building.

分类号:

  • 相关文献

[1]Effects of Lysiphlebia japonica (Ashmead) on cotton-melon aphid Aphis gossypii Glover lipid synthesis. S. Zhang,J.-Y. Luo,L.-M. Lv,C.-Y. Wang,C.-H. Li,X.-Z. Zhu,J.-J. Cui.

[2]Sucrose and citric acid accumulations in melon genotypes with different sugar and acid contents. Tang, Mi,Zhang, Bao-cai,Xie, Jun-jun,Bie, Zhi-long,Wu, Ming-zhu,Yi, Hong-ping,Feng, Jong-xin,Tang, Mi. 2012

[3]MdSnRK1.1 interacts with MdJAZ18 to regulate sucrose-induced anthocyanin and proanthocyanidin accumulation in apple. Liu, Xiao-Juan,An, Xiu-Hong,Liu, Xin,Hu, Da-Gang,Wang, Xiao-Fei,You, Chun-Xiang,Hao, Yu-Jin,An, Xiu-Hong.

[4]Preparation of high-purity fructo-oligosaccharides by Aspergillus japonicus beta-fructofuranosidase and successive cultivation with yeast. Yang, Ya-Lin,Wang, Jian-Hua,Teng, Da,Zhang, Fan.

[5]Cloning, silencing, and prokaryotic expression of strawberry sucrose synthase gene FaSus1. Hua, L. N.,Zang, M.,Wang, S. F.,Shen, Y. Y.,Guo, J. X.,Li, Y. Z..

[6]Sucrose synthase FaSS1 plays an important role in the regulation of strawberry fruit ripening. Zhao, Cheng,Hua, Li-Na,Liu, Xiao-Feng,Shen, Yuan-Yue,Guo, Jia-Xuan,Li, Yu-Zhong.

[7]Synthesis of empty capsid-like particles of Asia I foot-and-mouth disease virus in insect cells and their immunogenicity in guinea pigs. Cao, Yimei,Lu, Zengjun,Sun, Jiachuan,Bai, Xingwen,Sun, Pu,Bao, Huifang,Chen, Yingli,Guo, Jianhong,Li, Dong,Liu, Xiangtao,Liu, Zaixin.

[8]Cloning and expression of genes related to the sucrose-metabolizing enzymes and carbohydrate changes in peach. Zhang, Chunhua,Shen, Zhijun,Ma, Ruijuan,Yu, Mingliang,Zhang, Yanping,Han, Jian,Korir, Nicholas Kibet.

[9]Exogenous sucrose treatment accelerates postharvest tomato fruit ripening through the influence on its metabolism and enhancing ethylene biosynthesis and signaling. Li, Dongdong,Mou, Wangshu,Li, Li,Mao, Linchun,Ying, Tiejin,Luo, Zisheng,Wang, Yansheng.

[10]Shading Contributes to the Reduction of Stem Mechanical Strength by Decreasing Cell Wall Synthesis in Japonica Rice (Oryza sativa L.). Wu, Longmei,Ding, Yanfeng,Zhang, Jianwei,Cambula, Elidio D.,Weng, Fei,Liu, Zhenghui,Ding, Chengqiang,Tang, She,Chen, Lin,Wang, Shaohua,Li, Ganghua,Wu, Longmei,Ding, Yanfeng,Zhang, Jianwei,Cambula, Elidio D.,Weng, Fei,Liu, Zhenghui,Ding, Chengqiang,Tang, She,Chen, Lin,Wang, Shaohua,Li, Ganghua,Wu, Longmei,Ding, Yanfeng,Zhang, Jianwei,Cambula, Elidio D.,Weng, Fei,Liu, Zhenghui,Ding, Chengqiang,Tang, She,Chen, Lin,Wang, Shaohua,Li, Ganghua,Zhang, Wujun. 2017

[11]Rheological properties of waxy maize starch and xanthan gum mixtures in the presence of sucrose. Wang, Bao,Li, Dong,Mao, Zhi-Huai,Wang, Li-Jun,Ozkan, Necad,Li, Shu-Jun.

[12]Using Movable Light-emitting Diodes for Electricity Savings in a Plant Factory Growing Lettuce. Lil, Kun,Yang, Qi-Chang,Tong, Yu-Xin,Cheng, Ruifeng,Lil, Kun,Yang, Qi-Chang,Tong, Yu-Xin,Cheng, Ruifeng.

[13]Relationship between Sucrose Metabolism and Anthocyanin Biosynthesis During Ripening in Chinese Bayberry Fruit. Shi, Liyu,Shao, Jiarong,Chen, Wei,Yang, Zhenfeng,Cao, Shifeng,Zheng, Yonghua,Jiang, Yueming.

[14]Changes in carbohydrates and organic acids in leaves and mesocarp tissues during melon (Cucumis melo L.) fruit development. Fu, Q. S.,Zhang, X. Y.,Zhu, H. Q.,Lv, L. H.,Wang, H. S.. 2012

[15]Changes in Sucrose Content and Related Enzyme Activities during Pineapple Inflorescence Development. Lu, Xinhua,Sun, Guangmin,Zhang, Xiumei,Dou, Meian. 2011

[16]Sugar Accumulation in 'Smooth Cayenne' Pineapple Fruits in Different Harvest Seasons. Zhang, X. M.,Dou, M. A.,Yao, Y. L.,Du, L. Q.,Sun, G. M.,Li, J. G.. 2011

[17]Metabolic responses of alfalfa (Medicago Sativa L.) leaves to low and high temperature induced stresses. Mo, Yiwei,Shi, Weiqi,Xie, Jianghui,Liang, Guobin. 2011

[18]Dynamic analysis of sugar metabolism in different harvest seasons of pineapple (Ananas comosus L. (Merr.)). Sun, G. M.. 2011

[19]Sugar Accumulation Difference between the Various Sections during Pineapple Development. Dou, M. A.,Yao, Y. L.,Du, L. Q.,Sun, G. M.,Zhang, X. M.,Li, J. G.. 2011

[20]Soluble Sugar Content and Metabolism as Related to the Heat-Induced Chilling Tolerance of Loquat Fruit During Cold Storage. Shao, Xingfeng,Wang, Hongfei,Song, Yuxing,Zhu, Yong,Cao, Shifeng. 2013

作者其他论文 更多>>

微信小程序