Expression of maize heat shock transcription factor gene ZmHsf06 enhances the thermotolerance and drought-stress tolerance of transgenic Arabidopsis

文献类型: 外文期刊

第一作者: Li, Hui-cong

作者: Li, Hui-cong;Zhang, Hua-ning;Li, Guo-liang;Liu, Zi-hui;Zhang, Yan-min;Zhang, Hong-mei;Guo, Xiu-lin

作者机构:

关键词: drought-stress tolerance;heat shock transcription factor;transformation;thermotolerance;ZmHsf06

期刊名称:FUNCTIONAL PLANT BIOLOGY ( 影响因子:3.101; 五年影响因子:3.248 )

ISSN:

年卷期:

页码:

收录情况: SCI

摘要: Based on the information of 25 heat shock transcription factor (Hsf) homologues in maize according to a genome-wide analysis, ZmHsf06 was cloned from maize leaves and transformed into Arabidopsis thaliana (L. Heynh.) (ecotype, Col-0). Three transgenic positive lines were selected to assess the basic and acquired thermotolerance and drought-stress tolerance under stresses and for some physiological assays. The sequence analysis indicates that ZmHsf06 contained the characteristic domains of class A type plant Hsfs. The results of qRT-PCR showed that the expression levels of ZmHsf06 were elevated by heat shock and drought stress to different extents in three transgenic lines. Phenotypic observation shows that compared with the Wt (wild-type) controls, the overexpressing ZmHsf06 of Arabidopsis plants have enhanced basal and acquired thermotolerance, stronger drought-stress tolerance and growth advantages under mild heat stress conditions. These results are further confirmed by physiological and biochemical evidence that transgenic Arabidopsis plants exhibit higher seed germination rate, longer axial-root length, higher activities of superoxide dismutase (SOD), peroxidase (POD) and catalase (CAT), higher leaf chlorophyll content, but lower relative electrical conductivity (REC), malondialdehyde (MDA) and osmotic potential (OP) than the Wt controls after heat shock and drought treatments. ZmHsf06 may be a central representative of maize Hsfs and could be useful in molecular breeding of maize or other crops for enhanced tolerances, particularly during terminal heat and drought stresses.

分类号: Q94

  • 相关文献

[1]Over-expression of LlHsfA2b, a lily heat shock transcription factor lacking trans-activation activity in yeast, can enhance tolerance to heat and oxidative stress in transgenic Arabidopsis seedlings. Xin, Haibo,Zhong, Xionghui,Yi, Mingfang,Xin, Haibo,Zhang, Hua,Dong, Aixiang,Cong, Richen,Lian, Qinglong,Cao, Li.

[2]Histological and Ultrastructural Observation Reveals Significant Cellular Differences between Agrobacterium Transformed Embryogenic and Non-embryogenic Calli of Cotton. Shang, Hai-Hong,Liu, Chuan-Liang,Zhang, Chao-Jun,Li, Feng-Lian,Hong, Wei-Dong,Li, Fu-Guang.

[3]Genome-Wide Dissection of the Heat Shock Transcription Factor Family Genes in Arachis. Wang, Pengfei,Song, Hui,Li, Changsheng,Li, Pengcheng,Li, Aiqin,Guan, Hongshan,Hou, Lei,Wang, Xingjun,Wang, Xingjun. 2017

[4]Genome-wide identification and analysis of heat shock transcription factor family in cucumber (Cucumis sativus L.). Zhou, Shengjun,Zhang, Peng,Jing, Zange,Shi, Jianlei. 2013

[5]Overexpression of TaHSF3 in Transgenic Arabidopsis Enhances Tolerance to Extreme Temperatures. Zhang, Shuangxi,Li, Pansong,Zhang, Gaisheng,Zhang, Shuangxi,Xu, Zhao-Shi,Yang, Le,Chen, Ming,Li, Liancheng,Ma, Youzhi,Zhang, Shuangxi,Wei, Yiqin.

[6]Effects of calmodulin on DNA-binding activity of heat shock transcription factor in vitro. Li, B,Liu, HT,Mu, RL,Sun, DY,Zhou, RG.

[7]Identification of candidate thermotolerance genes during early seedling stage in upland cotton (Gossypium hirsutum L.) revealed by comparative transcriptome analysis. Peng, Zhen,Cao, Moju,Xu, Jie,Lu, Yanli,Peng, Zhen,He, Shoupu,Gong, Wenfang,Sun, Junling,Pan, Zhaoe,Du, Xiongming,Sun, Gaofei.

[8]The Arabidopsis J-protein AtDjB1 facilitates thermotolerance by protecting cells against heat-induced oxidative damage. Zhou, Wei,Zhou, Ting,Li, Mi-Xin,Zhao, Chun-Lan,Jia, Ning,Wang, Xing-Xing,Sun, Yong-Zhen,Xu, Meng,Li, Bing,Zhou, Wei,Li, Guo-Liang,Zhou, Ren-Gang,Zhou, Wei. 2012

[9]Molecular cloning of heat shock protein 60 from Marsupenaeus japonicus and its expression profiles at early developmental stages and response to heat stress. Zheng, Jinbin,Li, Lijun,Mao, Yong,Su, Yongquan,Wang, Jun,Dong, Hongbiao,Mao, Yong. 2018

[10]Toxoplasma gondii Clp family protein: TgClpB1 plays a crucial role in thermotolerance. Cao, Shinuo,Du, Nali,Chen, Heming,Pang, Yu,Zhang, Zhaoxia,Zheng, Jun,Jia, Honglin. 2017

[11]cDNA Cloning of Heat Shock Protein Genes and Their Expression in an Indigenous Cryptic Species of the Whitefly Bemisia tabaci Complex from China. Wan Fang-hao,Guo Jian-ying,Yu Hao. 2012

[12]Phosphoinositide-specific phospholipase C9 is involved in the thermotolerance of Arabidopsis. Zheng, Shu-Zhi,Liu, Yu-Liang,Li, Bing,Shang, Zhong-lin,Sun, Da-Ye,Zhou, Ren-Gang. 2012

[13]Differential gene expression in whitefly (Bemisia tabaci) B-biotype females and males under heat-shock condition. Wan, Fang-Hao,Wan, Fang-Hao.

[14]The transport of C-14-salicylic acid in heat-stressed young Vitis vinifera plants. Wang, LJ,Huang, WD,Zhan, JC,Yu, FY.

[15]Arabidopsis thaliana Phosphoinositide-Specific Phospholipase C Isoform 3 (AtPLC3) and AtPLC9 have an Additive Effect on Thermotolerance. Gao, Kang,Liu, Yu-Liang,Li, Bing,Sun, Da-Ye,Zheng, Shu-Zhi,Gao, Kang,Liu, Yu-Liang,Li, Bing,Sun, Da-Ye,Zheng, Shu-Zhi,Gao, Kang,Liu, Yu-Liang,Li, Bing,Sun, Da-Ye,Zheng, Shu-Zhi,Zhou, Ren-Gang.

[16]Drought-responsive WRKY transcription factor genes TaWRKY1 and TaWRKY33 from wheat confer drought and/or heat resistance in Arabidopsis. He, Guan-Hua,Xu, Ji-Yuan,Liu, Jia-Ming,Li, Pan-Song,Chen, Ming,Ma, You-Zhi,Xu, Zhao-Shi,Wang, Yan-Xia. 2016

[17]A heat-activated calcium-permeable channel - Arabidopsis cyclic nucleotide-gated ion channel 6 - is involved in heat shock responses. Gao, Fei,Zhou, Rengang,Gao, Fei,Han, Xiaowei,Wu, Jianhai,Zheng, Shuzhi,Shang, Zhonglin,Sun, Daye,Li, Bing,Gao, Fei.

[18]Variant Amino Acid Residues Alter the Enzyme Activity of Peanut Type 2 Diacylglycerol Acyltransferases. Zheng, Ling,Wan, Shubo,Peng, Zhenying,Zheng, Ling,Bian, Fei,Chen, Gao,Shan, Lei,Li, Xinguo,Wan, Shubo,Peng, Zhenying,Shockey, Jay. 2017

[19]Transformation of Liquidambar formosana L. via Agrobacterium tumefaciens using a mannose selection system and recovery of salt tolerant lines. Qiao, Guirong,Zhou, Jing,Jiang, Jing,Sun, Yuehua,Pan, Luanyin,Song, Honggai,Jiang, Jingmin,Zhuo, Renying,Sun, Yuehua,Wang, Xiaojuan,Sun, Zongxiu,Sun, Yuehua. 2010

[20]Improvement of Agrobacterium-mediated transformation efficiency of maize (Zea mays L.) genotype Hi-II by Optimizing Infection and Regeneration Conditions. Xu, You,Ren, Wen,Liu, Ya,Zhao, Jiuran,Xu, You. 2016

作者其他论文 更多>>