Genome-wide transcriptomic profiling of ramie (Boehmeria nivea L. Gaud) in response to cadmium stress

文献类型: 外文期刊

第一作者: Liu, Touming

作者: Liu, Touming;Zhu, Siyuan;Tang, Qingming;Tang, Shouwei

作者机构:

关键词: Ramie;Cadmium stress;Illumina sequencing;qRT-PCR

期刊名称:GENE ( 影响因子:3.688; 五年影响因子:3.329 )

ISSN:

年卷期:

页码:

收录情况: SCI

摘要: Cadmium (Cd) contamination in agricultural soils has become a major environmental problem in China. Ramie, a fiber crop, has frequently been proposed for use as a phytoremediation crop for the restoration of Cd-contaminated farmlands. However, high levels of Cd can greatly inhibit stem growth in ramie, which reduces its economic value as a crop. To understand the potential mechanisms behind this phenomenon, the ramie genes involved in the Cd stress response were identified using Illumina pair-end sequencing on two Cd-stressed plants (CdS1 and CdS2) and two control plants (CO1 and CO2). Approximately 48.7, 51.6, 41.2, and 47.1 million clean sequence reads were generated from the libraries of CO1, CO2, CdS1, and CdS2, respectively, and de novo assembled to yield 56,932 non-redundant unigenes. A total of 26,686 (46.9%) genes were annotated for their function. Comparison of gene expression levels in CO and CdS ramie revealed 155 differentially expressed genes (DEGs) between treatment and control conditions. Sixteen DEGs were further analyzed for expression differences by using real-time quantitative PCR (qRT-PCR). Among these 16 DEGs, 2 genes encoding GA2-oxidase (a major enzyme for deactivating bioactive gibberellins [GAS]) showed markedly up-regulated expression in Cd stressed ramie. This might be responsible for the growth inhibition of Cd-stressed ramie. Pathway enrichment analysis revealed that the cutin, suberine and wax biosynthesis pathway was markedly enriched by DEGs. The discovery of these Cd stress-responsive genes and pathways will be helpful in further understanding the mechanism of Cd-stress response and improving Cd stress tolerance in ramie. (C) 2015 Elsevier B.V. All rights reserved.

分类号: R394

  • 相关文献

[1]Identification of drought, cadmium and root-lesion nematode infection stress-responsive transcription factors in ramie. Zheng, Xia,Zhu, Siyuan,Tang, Shouwei,Liu, Touming,Zheng, Xia,Zhu, Siyuan,Tang, Shouwei,Liu, Touming. 2016

[2]Genome-wide transcriptional changes of ramie (Boehmeria nivea L. Gaud) in response to root-lesion nematode infection. Tang, Shouwei.

[3]Identification of drought stress-responsive transcription factors in ramie (Boehmeria nivea L. Gaud). Liu, Touming. 2013

[4]Hydrogen Peroxide-Mediated Growth of the Root System Occurs via Auxin Signaling Modification and Variations in the Expression of Cell-Cycle Genes in Rice Seedlings Exposed to Cadmium Stress. Zhao, Feng-Yun,Han, Ming-Ming,Wang, Kai,Zhang, Cheng-Ren,Liu, Tao,Liu, Wen,Zhang, Shi-Yong. 2012

[5]Effects of Cadmium Stress on Alternative Oxidase and Photosystem II in Three Wheat Cultivars. Xu, Fei,Zhang, Zhong-Wei,Chen, Yang-Er,Wang, Xiao,Shang, Jing,Lin, Hong-Hui,Duan, Yong-Ping,Tu, Shi-Hua,Feng, Wen-Qiang. 2010

[6]Effects of Applying Accumulator Straw in Soil on Nutrient Uptake and Soil Enzyme Activity of Capsella bursa-pastoris under Cadmium Stress. Yang, Shuting,Shi, Jun,Lv, Xiulan. 2016

[7]Effects of Cd2+ exposure on key life history traits and activities of four metabolic enzymes in Helicoverpa armigera (Lepidopteran: Noctuidae). Chen, Zhu,Huang, Yongjie,Yang, Shiyong,Zhang, Jinping,Ruuhola, Teija,Yang, Shiyong.

[8]Overexpression of Iris. lactea var. chinensis metallothionein IIMT2a enhances cadmium tolerance in Arabidopsis thaliana. Gu, Chun-Sun,Zhao, Yan-Hai,Huang, Su-Zhen,Gu, Chun-Sun,Zhao, Yan-Hai,Huang, Su-Zhen,Liu, Liang-qin,Zhu, Xu-dong,Deng, Yan-ming. 2014

[9]Methane alleviates alfalfa cadmium toxicity via decreasing cadmium accumulation and reestablishing glutathione homeostasis. Gu, Quan,Chen, Ziping,Cui, Weiti,Zhang, Yihua,Yu, Xiuli,Wang, Qingya,Shen, Wenbiao,Hu, Huali. 2018

[10]MAPKs regulate root growth by influencing auxin signaling and cell cycle-related gene expression in cadmium-stressed rice. Zhao, Feng Yun,Hu, Fan,Wang, Kai,Zhang, Cheng Ren,Liu, Tao,Zhang, Shi Yong.

[11]Crosstalk between ABA, auxin, MAPK signaling, and the cell cycle in cadmium-stressed rice seedlings. Zhao, Feng Yun,Wang, Kai,Ren, Jing,Liu, Tao,Wang, Xue,Zhang, Shi Yong.

[12]Physiological response to cadmium stress in kenaf (Hibiscus cannabinus L.) seedlings. Deng, Yong,Li, Defang,Huang, Yumin,Huang, Siqi. 2017

[13]Changes by cadmium stress in lipid peroxidation and activities of lipoxygenase and antioxidant enzymes in Arabidopsis are associated with extracellular ATP. Hou, Qin-zheng,Jia, Ling-yun,Liang, Jun-yu,Feng, Han-qing,Wen, Jing,Shi, Dai-long,Wang, Qing-wen,Ye, Guang-ji,Wang, Rong-fang. 2017

[14]Isolation and characterization of three cadmium-inducible promoters from Oryza sativa. Qiu, Chun-Hong,Li, Hao,Li, Juan,Qin, Rui-Ying,Xu, Rong-Fang,Yang, Ya-Chun,Ma, Hui,Song, Feng-Shun,Li, Li,Wei, Peng-Cheng,Yang, Jian-Bo.

[15]The effect of salinity pretreatment on Cd accumulation and Cd-induced stress in BADH-transgenic and nontransgenic rice seedlings. Shao, Guosheng,Zhang, Guoping,Shao, Guosheng,Chen, Mingxue,Wang, Weixia. 2008

[16]Cadmium-induced oxidative stress and response of the ascorbate-glutathione cycle in Bechmeria nivea (L.) Gaud. Liu, Yunguo,Wang, Xin,Zeng, Guangming,Qu, Dan,Gu, Jiajia,Zhou, Ming,Chal, Liyuan. 2007

[17]Isolation, identification, and environmental adaptability of heavy-metal-resistant bacteria from ramie rhizosphere soil around mine refinery. Jiang, Jie,Pan, Chaohu,Zhang, Guimin,Xiao, Aiping,Yang, Xiai. 2017

[18]Constitutional tolerance to heavy metals of a fiber crop, ramie (Boehmeria nivea), and its potential usage. Yang, B.,Zhou, M.,Shu, W. S.,Lan, C. Y.,Ye, Z. H.,Yang, B.,Zhou, M.,Shu, W. S.,Lan, C. Y.,Ye, Z. H.,Qiu, R. L.,Qiu, R. L.,Jie, Y. C.,Cui, G. X.,Wong, M. H.,Wong, M. H..

[19]Construction and co-expression of polycistronic plasmids encoding bio-degumming-related enzymes to improve the degumming process of ramie fibres. Cheng, Yi,Liu, Zhengchu,Zeng, Jie,Cheng, Lifeng,Yan, Zhun,Duan, Shengwen,Feng, Xiangyuan,Zheng, Ke,Zheng, Xia,Wang, Ruijun.

[20]Senescence is delayed when ramie (Boehmeria nivea L.) is transformed with the isopentyl transferase (ipt) gene under control of the SAG12 promoter. An, Xia,Zhang, Jingyu,Liao, Yiwen,Liu, Lijun,Peng, Dingxiang,Wang, Bo,An, Xia. 2017

作者其他论文 更多>>

微信小程序