江苏省农业科学院机构知识库

A novel nuclear protein phosphatase 2C negatively regulated by ABL1 is involved in abiotic stress and panicle development in rice

收藏
分享
全文链接

文献类型：外文期刊

作者： Li, Yu-Sheng ¹ ; Sun, Hui ² ; Wang, Zhou-Fei ² ; Duan, Min ² ; Huang, Sheng-Dong ¹ ; Yang, Juan ¹ ; Huang, Ji ¹ ; Zhang, ¹ ;

作者机构： 1.Jiangsu Acad Agr Sci, Inst Food Crops, Nanjing 210014, Jiangsu, Peoples R China

2.Nanjing Agr Univ, Coll Agr, State Key Lab Crop Genet & Germplasm Enhancement, Nanjing 210095, Jiangsu, Peoples R China

关键词： Abiotic stress;ABL1;Panicle development;Protein phosphatase 2C;Rice

期刊名称：MOLECULAR BIOTECHNOLOGY （影响因子：2.695；五年影响因子：2.303 ）

ISSN：

年卷期：

页码：

收录情况： SCI

摘要： Type 2C protein phosphatase plays an important role in the signal transduction of stress response in plants. In this paper, we identified a novel stress-induced type 2C protein phosphatase gene OsSIPP2C1 from rice. OsSIPP2C1 contains a complete open reading frame of 1,074 bp, encoding a protein with 357 amino acids. OsSIPP2C1 expression was up-regulated by high salt, PEG6000 and exogenous ABA, and enhanced in the abl1 mutant under normal, salt, or drought condition. Interestingly, OsSIPP2C1 expression was increased during the early panicle development. Subcellular localization assay using rice protoplast cells indicated that OsSIPP2C1 was predominantly located in the nucleus. Together, it is suggested that a nuclear PP2C protein OsSIPP2C1 negatively regulated by ABL1 is involved in abiotic stress and panicle development in rice.

相关文献

[1]Regulation of ATG6/Beclin-1 homologs by abiotic stresses and hormones in rice (Oryza sativa L.). Rana, R. M.,Dong, S.,Huang, J.,Zhang, H. S.,Rana, R. M.,Ali, Z.,Ali, Z.. 2012

[2]Validation of reference genes for RT-qPCR normalization in Iris. lactea var. chinensis leaves under different experimental conditions. Gu, Chun-Sun,Lu, Xiao-Qing,Huang, Su-Zhen,Liu, Liang-Qin,Zhu, Xu-Dong,Deng, Yan-Ming.

[3]Salinity Tolerance Mechanism of Osmotin and Osmotin-like Proteins: A Promising Candidate for Enhancing Plant Salt Tolerance. Qun Wan,Shao Hongbo,Xu Zhaolong,Liu Jia,Zhang Dayong,Huang Yihong,Shao Hongbo.

[4]Physiological and transcriptional responses in the iron-sulphur cluster assembly pathway under abiotic stress in peach (Prunus persica L.) seedlings. Song, Zhizhong,Yang, Yong,Xu, Jianlan,Ma, Ruijuan,Yu, Mingliang.

[5]A set of miRNAs from Brassica napus in response to sulphate deficiency and cadmium stress. Huang, Si Qi,Xiang, An Ling,Che, Li Ling,Li, Hui,Song, Jian Bo,Yang, Zhi Min,Chen, Song.

[6]Recent Advances in Utilizing Transcription Factors to Improve Plant Abiotic Stress Tolerance by Transgenic Technology. Wang, Hongyan,Wang, Honglei,Shao, Hongbo,Shao, Hongbo,Tang, Xiaoli. 2016

[7]Characterization and expression profile of CaNAC2 pepper gene. Guo, Wei-Li,Chen, Ru-Gang,Yin, Yan-Xu,Gong, Zhen-Hui,Guo, Wei-Li,Chen, Bi-Hua,Du, Xiao-Hua,Zhang, Yu-Yuan,Wang, Shu-Bin. 2015

[8]Whole-genome identification and expression analysis of K+ efflux antiporter (KEA) and Na+/H+ antiporter (NHX) families under abiotic stress in soybean. Chen Hua-tao,Chen Xin,Wu Bing-yue,Yuan Xing-xing,Zhang Hong-mei,Cui Xiao-yan,Liu Xiao-qing. 2015

[9]Genome-wide identification and expression analysis of the BTB domain-containing protein gene family in tomato. Li, Jinhua,Su, Xiaoxing,Yang, Wei,Pan, Yu,Su, Chenggang,Zhang, Xingguo,Li, Jinhua,Su, Xiaoxing,Yang, Wei,Pan, Yu,Su, Chenggang,Zhang, Xingguo,Wang, Yinlei. 2018

[10]Measuring Spatial and Temporal Ca2+ Signals in Arabidopsis Plants. Zhu, Xiaohong,Zhang, Shenyu,Zhang, Dayong,Feng, Ying,Liang, Gaimei,Zhu, Jian-Kang,Taylor, Aaron,Zhang, Dayong,Feng, Ying,Zhu, Jian-Kang. 2014

[11]A Novel RNA-Binding Protein Involves ABA Signaling by Post-transcriptionally Repressing ABI2. Xu, Jianwen,Chen, Yihan,Qian, Luofeng,Mu, Rong,Yuan, Xi,Fang, Huimin,Huang, Xi,Xu, Enshun,Zhang, Hongsheng,Huang, Ji,Xu, Jianwen,Chen, Yihan,Qian, Luofeng,Mu, Rong,Yuan, Xi,Fang, Huimin,Huang, Xi,Xu, Enshun,Zhang, Hongsheng,Huang, Ji. 2017

[12]NAC transcription factors in plant multiple abiotic stress responses: progress and prospects. Shao, Hongbo,Shao, Hongbo,Shao, Hongbo,Wang, Hongyan,Tang, Xiaoli,Wang, Hongyan. 2015

[13]Characterization of Grain Quality and Starch Fine Structure of Two Japonica Rice (Oryza Sativa) Cultivars with Good Sensory Properties at Different Temperatures during the Filling Stage. Zhang, Changquan,Zhou, Lihui,Lu, Huwen,Zhou, Xingzhong,Qan, Yiting,Li, Qianfeng,Lu, Yan,Gu, Minghong,Liu, Qiaoquan,Zhou, Lihui,Zhu, Zhengbin.

[14]A novel, in vivo, indoor method to preserve rice black-streaked dwarf virus in small brown planthopper using wheat seedling as a bridge host. Ren, Chunmei,Cheng, Zhaobang,Yang, Liu,Miao, Qian,Fan, Yongjian,Zhou, Yijun.

[15]Delivery of roxarsone via chicken diet -> chicken -> chicken manure -> soil -> rice plant. Lu, Weisheng,Bai, Cuihua,Huang, Lianxi,He, Zhaohuan,Zhou, Changmin.

[16]Natural Variations in SLG7 Regulate Grain Shape in Rice. Miao, Jun,Peng, Xiurong,Leburu, Mamotshewa,Yuan, Fuhai,Gu, Houwen,Gao, Yun,Tao, Yajun,Gong, Zhiyun,Yi, Chuandeng,Gu, Minghong,Yang, Zefeng,Liang, Guohua,Gu, Haiyong,Zhu, Jinyan.

[17]Periphyton growth reduces cadmium but enhances arsenic accumulation in rice (Oryza sativa) seedlings from contaminated soil. Shi, Gao Ling,Ma, Hong Xiang,Lu, Hai Ying,Liu, Jun Zhuo,Wu, Yong Hong,Lou, Lai Qing,Tang, Xian Jin.

[18]Changes in Violaxanthin Deepoxidase Activity and Unsaturation of Thylakoid Membrane Lipids in Indica and Japonica Rice Under Chilling Condition and Strong Light. Ji, BH,Cao, YY,Xie, HS,Zhu, SQ,Ma, Q,Jian, DM.

[19]In Situ Field-Scale Remediation of Low Cd-Contaminated Paddy Soil Using Soil Amendments. Ai, Shao-ying,Wang, Yan-hong,Tang, Ming-deng,Li, Yi-Chun,Li, Lin-feng,Ai, Shao-ying,Wang, Yan-hong,Tang, Ming-deng,Li, Yi-Chun,Li, Lin-feng,Ai, Shao-ying,Wang, Yan-hong,Tang, Ming-deng,Li, Yi-Chun.

[20]Photosynthesis performance, antioxidant enzymes, and ultrastructural analyses of rice seedlings under chromium stress. Ma, Jing,Lv, Chunfang,Xu, Minli,Chen, Guoxiang,Gao, Zhiping,Lv, Chuangen.

作者其他论文更多>>

Development of a Crop Spectral Reflectance Sensor

作者：Liu, Naisen;Liu, Fuxia;Du, Chenggong;Ji, Shuwen;Sun, Hui;Liu, Naisen;Liu, Fuxia;Du, Chenggong;Ji, Shuwen;Sun, Hui;Liu, Naisen;Liu, Fuxia;Du, Chenggong;Ji, Shuwen;Sun, Hui;Zhang, Wenyu;Zhang, Meina;Sun, Chuanliang;Cao, Jing;Zhang, Wenyu;Zhang, Meina;Sun, Chuanliang;Cao, Jing;Zhang, Wenyu;Zhang, Meina;Sun, Chuanliang;Cao, Jing;Zhang, Wenyu;Zhang, Meina

关键词：crop growth information sensor; crop spectral reflectance; spectral monitoring; automatic balancing; theoretical calibration method
Population structural analysis of an in-situ conservation site for wild rice in Laos

作者：Wang, Yan-Ping;Zhang, Hong-Sheng;Bounphanousay, Chay;Kanyavong, Kongpanh;Nakamura, Ikuo;Sato, Yo-Ichiro;Sato, Tadashi;Wang, Yan-Ping;Tang, Ling-hua;Ishikawa, Ryuji

关键词：annual-perennial differentiation;in-situ conservation;life history;Oryza rufipogon;population structure

A novel nuclear protein phosphatase 2C negatively regulated by ABL1 is involved in abiotic stress and panicle development in rice

作者其他论文 更多>>

Development of a Crop Spectral Reflectance Sensor

Population structural analysis of an in-situ conservation site for wild rice in Laos

意 见 箱

作者其他论文更多>>

意见箱