农科机构知识库联盟

Over-expression of ZmPti1, a homologue to Pti1, increases salt tolerance of Arabidopsis thaliana

文献类型：外文期刊

第一作者： Zou, Huawen

作者： Zou, Huawen;Wu, Zhongyi;Zhang, Xiuhai;Wang, Yongqin;Huang, Conglin;Zou, Huawen

作者机构：

关键词： ZmPti1;transgenic Arabidopsis;salt resistance

期刊名称：AFRICAN JOURNAL OF BIOTECHNOLOGY （影响因子：0.573；五年影响因子：0.794 ）

ISSN： 1684-5315

年卷期： 2010 年 9 卷 5 期

页码：

收录情况： SCI

摘要： Studies have shown that Pti1 plays an important role in plant disease resistance pathway. However, Pti1 have not been studied for its roles under salt stress condition. Previous study has shown that maize ZmPti1 is induced by salicylic acid (SA), low-temperature, mannitol and salt. In order to analyze the further biological functions of ZmPti1, ZmPti1 was over-expressed in Arabidopsis. Under salt stress, compared to wild type, transgenic plants grew better, had higher seedling fresh and dry weight (FW, DW), seed yields and the superoxide dismutase (SOD) activity; Seedling FW and DW of S1-1, S2-1 transgenic plants increased significantly than that of WT; Seed weight of S1-1, S2-1 transgenic plants increased 71 and 106% respectively; However malondialdehyde (MDA) content and relative electric conductivity (ion leakage) of transgenic plants were kept to a relative lower level. Based on the present knowledge, this is the first report that showed that the over-expression of Pti1-like gene enhances the salt resistance in plants.

分类号：

相关文献

[1]Zmspk1, a member of plant snrk2 subfamily in maize enhances tolerance to salt in transgenic Arabidopsis. Zou, Huawen,Liu, Hongfang,Li, Zhaojun,Ma, Guohui,Zou, Huawen,Li, Cuihua,Zhao, Mingmin,Tian, Xiaohai. 2011

[2]Isolation and analysis of ZmPto from maize, a homologue to Pto. Zou, Huawen,Song, Zhongjian,Wu, Zhongyi,Zhang, Xiuhai,Huang, Conglin,Zou, Huawen,Liu, Hongfang,Ma, Guohui. 2011

[3]Expression of Aquaporin BnPIP-like Gene from Rapeseed (Brassica napus) Enhances Salt Resistance in Yeast (Pichia pastoris). Li, Hao-Jie,Zhang, Jin-Fang,Cui, Cheng,Jiang, Jun,Zheng, Ben-Chuan,Jiang, Liang-Cai,Tan, Hao,Zhang, Bi. 2016

[4]Overexpression of Arabidopsis thaliana Na+/H+ antiporter gene enhanced salt resistance in transgenic poplar (Populus x euramericana 'Neva'). Jiang, Chaoqiang,Zheng, Qingsong,Liu, Zhaopu,Liu, Ling,Zhao, Gengmao,Long, Xiaohua,Jiang, Chaoqiang,Xu, Wenjun. 2012

[5]Expression of the Arabidopsis vacuolar H+-pyrophosphatase gene AVP1 in peanut to improve drought and salt tolerance. Qin, Hua,Zhang, Yizheng,Gu, Qiang,Kuppu, Sundaram,Sun, Li,Zhu, Xunlu,Mishra, Neelam,Hu, Rongbin,Zhang, Hong,Shen, Guoxin,Zhang, Junling,Burow, Mark,Zhu, Longfu,Zhang, Xianlong,Payton, Paxton. 2013

[6]Temporal and spatial distributions of sodium and polyamines regulated by brassinosteroids in enhancing tomato salt resistance. Zheng, Qingsong,Liu, Jinlong,Liu, Ran,Wang, Changhai,Wu, Hao,Guan, Yongxiang,Jiang, Chaoqiang.

[7]Molecular cloning and expression analysis of the MaASR1 gene in banana and functional characterization under salt stress. Miao, Hongxia,Wang, Yuan,Liu, Juhua,Jia, Caihong,Hu, Wei,Xu, Biyu,Sun, Peiguang,Jin, Zhiqiang. 2014

[8]Two P5CS genes from common bean exhibiting different tolerance to salt stress in transgenic Arabidopsis. Chen, Ji Bao,Yang, Jian Wei,Zhang, Zhao Yuan,Feng, Xiao Fan,Wang, Shu Min.

[9]The short C-terminal hydrophilic domain of NhaH Na+/H+ antiporter from Halobacillus dabanensis with roles in resistance to salt and in pH sensing. Yang LiFu,Zhang Bo,Wang Lei,Yang SuSheng,Yang LiFu,Zhang Bo,Wang Lei,Yang SuSheng,Yang LiFu,Yang LiFu.

[10]Phytoremediation of triphenylmethane dyes by overexpressing a Citrobacter sp triphenylmethane reductase in transgenic Arabidopsis. Fu, Xiao-Yan,Zhao, Wei,Xiong, Ai-Sheng,Tian, Yong-Sheng,Zhu, Bo,Peng, Ri-He,Yao, Quan-Hong. 2013

[11]Overexpression of a new Cys(2)/His(2) zinc finger protein ZmZF1 from maize confers salt and drought tolerance in transgenic Arabidopsis. Huai, Junling,Zheng, Jun,Wang, Guoying,Huai, Junling. 2009

[12]Bioinformatic Analyses of Subgroup-A Members of the Wheat bZIP Transcription Factor Family and Functional Identification of TabZIP174 Involved in Drought Stress Response. Li, Xueyin,Ma, Lingjian,Feng, Biane,Zhang, Fengjie,Tang, Yimiao,Zhang, Liping,Zhao, Changping,Gao, Shiqing,Feng, Biane,Zhang, Fengjie. 2016

[13]Overexpression of the maize E3 ubiquitin ligase gene ZmAIRP4 enhances drought stress tolerance in Arabidopsis. Yang, Junpin,Tan, Jun,Yang, Liang,Chang, Wei,Li, Zhi,Miao, Mingjun,Li, Yuejian,Yang, Liang,Chang, Wei,Li, Zhi,Miao, Mingjun,Li, Yuejian,Wu, Lintao,Liu, Zhibin. 2018

[14]Isolation and drought-tolerant function analysis of ZmPti1-1, a homologue to Pti1, from maize (Zea mays L.). Li, Zhiliang,Bian, Mingdi,Wu, Zhongyi,Zhang, Xiuhai,Huang, Conglin,Li, Zhiliang,Yang, Qing,Li, Zhiliang. 2011

[15]Transgenic expression of a sorghum gene (SbLRR2) encoding a simple extracellular leucine-rich protein enhances resistance against necrotrophic pathogens in Arabidopsis. Zhu, Fu-Yuan,Lo, Clive,Zhu, Fu-Yuan,Zhang, Jianhua,Zhu, Fu-Yuan,Zhang, Jianhua,Li, Lei.

[16]Molecular cloning and functional analysis of the drought tolerance gene MsHSP70 from alfalfa (Medicago sativa L.). Li, Zhenyi,Long, Ruicai,Zhang, Tiejun,Wang, Zhen,Zhang, Fan,Yang, Qingchuan,Kang, Junmei,Sun, Yan.

[17]Molecular cloning and characterization of the promoter for the multiple stress-inducible gene BjCHI1 from Brassica juncea. Wu, Xue-Feng,Wang, Chun-Lian,Xie, En-Bei,Gao, Ying,Fan, Ying-Lun,Zhao, Kai-Jun,Wu, Xue-Feng,Liu, Pi-Qing.

[18]Tomato SlDREB1 gene conferred the transcriptional activation of drought-induced gene and an enhanced tolerance of the transgenic Arabidopsis to drought stress. Jiang, Linlin,Cheng, Xianguo,Jiang, Linlin,Wang, Yingbo,Li, Wei,Cheng, Xianguo,Jiang, Linlin,Wang, Yingbo,Li, Wei,Cheng, Xianguo,Zhang, Shuhui,He, Rui,Han, Jiao.

[19]Phytoremediation of 2,4,6-trinitrotoluene by Arabidopsis plants expressing a NAD(P)H-flavin nitroreductase from Enterobacter cloacae. You, Shuang-Hong,Zhu, Bo,Han, Hong-Juan,Wang, Bo,Peng, Ri-He,Yao, Quan-Hong.

[20]Identification of a novel bZIP transcription factor in Camellia sinensis as a negative regulator of freezing tolerance in transgenic arabidopsis. Wang, Lu,Cao, Hongli,Qian, Wenjun,Yao, Lina,Hao, Xinyuan,Li, Nana,Yang, Yajun,Wang, Xinchao,Wang, Lu,Hao, Xinyuan,Yang, Yajun,Wang, Xinchao,Qian, Wenjun.

作者其他论文更多>>

Auxin regulates bulbil development by affecting carbohydrate metabolism in Lilium lancifolium

作者：Wang, Mengdi;Li, Jiamin;Zhang, Xuemin;Kang, Shengnan;Yu, Xiaonan;Wang, Mengdi;Li, Jiamin;Pan, Wenqiang;Sang, Qianzi;Liang, Jiahui;Zhang, Xuemin;Kang, Shengnan;Zhang, Mingfang;Zhang, Xiuhai;Du, Yunpeng;Wang, Mengdi;Li, Jiamin;Pan, Wenqiang;Sang, Qianzi;Liang, Jiahui;Zhang, Xuemin;Kang, Shengnan;Zhang, Mingfang;Zhang, Xiuhai;Du, Yunpeng;Sang, Qianzi

关键词：Lilium lancifolium; Bulbil development; Transcriptome; Auxin; Carbohydrate metabolism
Salicylic acid influences the resistance of colored calla lily to soft rot (Pectobacterium carotovorum) via the TGA2-LNC88940-miR528-SOD module

作者：Wang, Yi;Wang, Di;Gou, Rongxin;Jiang, Yin;Zeng, Zhen;Zhang, Xiuhai;Wei, Zunzheng;Yang, Tuo;Wang, Di;Gou, Rongxin;Jiang, Yin;Zhang, Guojun

关键词：soft rot; Zantedeschia elliottiana; lncRNA; miRNA; salicylic acid
The giant genome of lily provides insights into the hybridization of cultivated lilies

作者：Liang, Yuwei;Gao, Qiang;Zhang, Liangsheng;Li, Fan;Duan, Qing;Li, Shenchong;Jin, Chunlian;Zhang, Peihua;Wang, Jihua;Li, Fan;Duan, Qing;Li, Shenchong;Jin, Chunlian;Zhang, Peihua;Wang, Jihua;Du, Yunpeng;Pan, Wenqiang;Zhang, Xiuhai;Zhang, Mingfang;Wu, Jian;Pan, Wenqiang;Wang, Shaokun;Song, Xiaoming;Zhong, Linlin;Zhang, Fan;Li, Yan;Wang, Zhiwei;Li, Danqing;Gu, Yang;Chen, Zhong-Hua;Chen, Zhong-Hua;Mayer, Klaus F. X.;Mayer, Klaus F. X.;Zhou, Xiaofan;Zhang, Liangsheng;Zhang, Liangsheng

关键词：
The TIFY transcription factor ZmJAZ13 enhances plant tolerance to drought and salt stress by interacting with ZmbHLH161 and ZmA0A1D6GLB9

作者：Zhang, Shipeng;Lu, Yuncai;Zhang, Shipeng;Zheng, Dengyu;Gao, Yuqi;She, Meng;Wu, Zhongyi;Zhang, Zhongbao;Gao, Yuqi

关键词：Maize; ZmJAZ13; Drought stress; Salt stress; Response to adversity
Molecular Elucidation of Anthocyanin Accumulation Mechanisms in Hippeastrum hybridum Cultivars

作者：Guo, Pengyu;Xing, Chuanji;Ye, Jiacheng;Xue, Jing;Zhang, Xiuhai;Chen, Xuqing;Guo, Pengyu;Hu, Zongli;Chen, Guoping;Ye, Jiacheng;Mur, Luis A. J.;Di, Bao

关键词：Hippeastrum; petals; anthocyanins; transcriptomics; metabolomics; WGCNA; Y2H
The NAC transcription factor LpNAC48 promotes trichome formation in Lilium pumilum

作者：Xin, Yin;Pan, Wenqiang;Wu, Jingxiang;Zhang, Mingfang;Ma, Yang;Zhang, Xiuhai;Du, Yunpeng;Xin, Yin;Pan, Wenqiang;Zhao, Yajie;Li, Jingru;Wang, Shaokun;Wu, Jingxiang;Shi, Jinxin;Ma, Yang;Wu, Jian;Pan, Wenqiang;Zhang, Xiuhai;Du, Yunpeng;Yang, Chenglong;Fang, Shaozhong;Liang, Yuwei;Zaccai, Michele

关键词：
A natural variation of flavone synthase II gene enhances flavone accumulation and confers drought adaptation in chrysanthemum

作者：Luo, Jiayi;Han, Mingzheng;Song, Zhenzhen;Zhang, Haixia;Zhao, Yafei;Ma, Chao;Luo, Chang;Huang, Conglin;Wang, Qinrui;Gao, Qiang;Lin, Tao

关键词：Chrysanthemum; drought; flavone; FNSII; GWAS

Over-expression of ZmPti1, a homologue to Pti1, increases salt tolerance of Arabidopsis thaliana

作者其他论文 更多>>

Auxin regulates bulbil development by affecting carbohydrate metabolism in Lilium lancifolium

Salicylic acid influences the resistance of colored calla lily to soft rot (Pectobacterium carotovorum) via the TGA2-LNC88940-miR528-SOD module

The giant genome of lily provides insights into the hybridization of cultivated lilies

The TIFY transcription factor ZmJAZ13 enhances plant tolerance to drought and salt stress by interacting with ZmbHLH161 and ZmA0A1D6GLB9

Molecular Elucidation of Anthocyanin Accumulation Mechanisms in Hippeastrum hybridum Cultivars

The NAC transcription factor LpNAC48 promotes trichome formation in Lilium pumilum

A natural variation of flavone synthase II gene enhances flavone accumulation and confers drought adaptation in chrysanthemum

作者其他论文更多>>