Comparative transcriptome profiling of potassium starvation responsiveness in two contrasting watermelon genotypes

文献类型: 外文期刊

第一作者: Fan, Molin

作者: Fan, Molin;Huang, Yuan;Zhong, Yaqin;Kong, Qiusheng;Xie, Junjun;Niu, Mengliang;Bie, Zhilong;Xu, Yong

作者机构:

关键词: Citrullus lanatus;Gene expression;Potassium deficiency;RNA -seq;Root;Stress response

期刊名称:PLANTA ( 影响因子:4.116; 五年影响因子:4.316 )

ISSN:

年卷期:

页码:

收录情况: SCI

摘要: Potassium (K) is one of the essential nutrients for crops, and K~+ deficiency highly restricts crop yield and quality. Watermelon [Citrullus lanatus (Thunb.) Matsum. & Nakai] is an economically important crop that often suffers from K~+ deficiency. To elucidate the underlying tolerance mechanism of watermelon to K~+ deficiency and to improve K efficiency of watermelon and other crops in the future, two watermelon genotypes, namely, YS and 8424, that exhibit contrasting K efficiencies were studied to compare their response mechanisms to K~+ deficiency. YS was more tolerant of K~+ deficiency and displayed less inhibited root growth than 8424. Roots of YS and 8424 seedlings with or without K~+ supply were harvested at 6 and 120 h after treatment (HAT), and their transcriptomes were analyzed by Illumina RNA sequencing. Different regulation mechanisms of the root K~+-uptake genes for short- and long-term stress were observed. Genes involved in jasmonic acid and reactive oxygen species production; Ca~(2+) and receptorlike kinase signaling; lignin biosynthesis; and other stressrelated genes were repressed in YS, whereas a large number of such stress-related genes were induced in 8424 at 120 HAT. These results suggested that repressed defense and stress response can save energy for better root growth in YS, which can facilitate K~+ uptake and increase K efficiency and tolerance to K~+ deficiency. This study presents the first global root transcriptome in watermelon and provides new insights into the molecular mechanisms underlying tolerance to K~+ deficiency of K-efficient watermelon genotypes.

分类号: Q94

  • 相关文献

[1]Proteomic analysis of responsive root proteins of Fusarium oxysporum-infected watermelon seedlings. Zhang, Man,Xu, Jinhua,Liu, Guang,Yao, Xiefeng,Ren, Runsheng,Yang, Xingping. 2018

[2]Dynamic characteristics of enzymes and transcriptome related to sugar metabolism and accumulation in sweet and non-sweet watermelon fruits. Xu, Y.,Guo, S.,Liu, J.,He, H.,Zhang, H.,Ren, Y.,Sun, H.,Gong, G.,Fei, Z.,Zheng, Y.,Huang, M.,Zhong, S.,Liu, J.. 2012

[3]Comparative Proteomic Analysis Reveals Differential Root Proteins in Medicago sativa and Medicago truncatula in Response to Salt Stress. Long, Ruicai,Zhang, Tiejun,Kang, Junmei,Cong, Lili,Gao, Yanli,Yang, Qingchuan,Li, Mingna,Sun, Yan,Liu, Fengqi. 2016

[4]Transcription profiles of boron-deficiency-responsive genes in citrus rootstock root by suppression subtractive hybridization and cDNA microarray. Zhou, Gao-Feng,Liu, Yong-Zhong,Sheng, Ou,Wei, Qing-Jiang,Yang, Cheng-Quan,Peng, Shu-Ang,Zhou, Gao-Feng,Sheng, Ou,Wei, Qing-Jiang. 2015

[5]Cloning and characterization of a putative 12-oxophytodienoic acid reductase cDNA induced by osmotic stress in roots of foxtail millet. Zhang, Jin-Peng,Liu, Ting-Song,Zheng, Jun,Jin, Zheng,Zhu, Yun,Guo, Jiu-Feng,Wang, Guo-Ying.

[6]Physiological and Molecular Responses Under Fe Deficiency in Two Rice (Oryza sativa) Genotypes Differing in Iron Accumulation Ability in Seeds. Chen, Lin,Ding, Chengqiang,Wang, Shaohua,Ding, Yanfeng,Zhao, Xiufeng.

[7]Genome-wide identification, expression profiling, and SSR marker development of the bZIP transcription factor family in Medicago truncatula. Zhang, Zhengshe,Liu, Wenxian,Liu, Zhipeng,Xie, Wengang,Wang, Yanrong,Qi, Xiao,Qi, Xiao.

[8]Comparative Transcriptional Profiling of Melatonin Synthesis and Catabolic Genes Indicates the Possible Role of Melatonin in Developmental and Stress Responses in Rice. Wei, Yunxie,Zeng, Hongqiu,He, Chaozu,Shi, Haitao,Hu, Wei,Chen, Lanzhen. 2016

[9]Gene expression profiles of arabidopsis under the stress of methyl viologen: a microarray analysis. Han, Hong-Juan,Peng, Ri-He,Zhu, Bo,Fu, Xiao-Yan,Zhao, Wei,Shi, Biao,Yao, Quan-Hong.

[10]Alterations of growth, antioxidant system and gene expression in Stylosanthes guianensis during Colletotrichum gloeosporioides infection. Wang, Hui,Jia, Yanxing,Luo, Lijuan,Chen, Zhijian,Liu, Guodao,Bai, Changjun,Qiu, Hong. 2017

[11]Gene expression profile of Arabidopsis under sodium bisulfite treatment by oligo-microarray analysis. Zhu, Bo,Han, Hong-Juan,Fu, Xiao-Yan,Zhao, Wei,Gao, Jian-Jie,Xue, Yong,Peng, Ri-He,Yao, Quan-Hong,You, Shuang-Hong.

[12]Structure and expression profile of the sucrose synthase gene family in the rubber tree: indicative of roles in stress response and sucrose utilization in the laticifers. Xiao, Xiaohu,Tang, Chaorong,Fang, Yongjun,Zhou, Binhui,Qi, Jiyan,Zhang, Yi,Xiao, Xiaohu,Zhou, Binhui,Zhang, Yi,Yang, Meng. 2014

[13]Effects of potassium deficiency on photosynthesis and photoprotection mechanisms in soybean (Glycine max (L.) Merr.). Wang Xiao-guang,Zhao Xin-hua,Jiang Chun-ji,Li Chun-hong,Cong Shan,Wu Di,Yu Hai-qiu,Chen Yan-qiu,Wang Chun-yan. 2015

[14]Potassium deficiency inhibits lateral root development in tobacco seedlings by changing auxin distribution. Song, Wenjing,Meng, Lin,Wang, Chengdong,Liu, Guangliang,Wang, Shusheng,Dong, Jianxin,Liu, Shangjun,Xue, Ren,Dong, Caixia,Zhang, Yali.

[15]EFFECTS OF POTASSIUM DEFICIENCY AND REPLACEMENT OF POTASSIUM BY SODIUM ON SUGAR BEET PLANTS. Pi, Z.,Yv, L. H.,Geng, G.,Guo, X. L.,Yang, Y.,Peng, C. X.,Kong, X. S.,Stevanato, P.,Yv, L. H.,Geng, G..

[16]Response of root morphology, physiology and endogenous hormones in maize (Zea mays L.) to potassium deficiency. Zhao Xin-hue,Yu Hai-qiu,Wen Jing,Wang Xiao-guang,Du Qi,Wang Jing,Wang Qiao,Wen Jing. 2016

[17]Comparative metabolic activity related to flavonoid synthesis in leaves and flowers of Chrysanthemum morifolium in response to K deficiency. Liu, Wei,Zhu, Duanwei,Liu, Dahui,Geng, Mingjian,Liu, Dahui,Lu, Xiao.

[18]Mutation in the gene encoding 1-aminocyclopropane-1-carboxylate synthase 4 (CitACS4) led to andromonoecy in watermelon. Ji, Gaojie,Zhang, Jie,Zhang, Haiying,Sun, Honghe,Gong, Guoyi,Shi, Jianting,Tian, Shouwei,Guo, Shaogui,Ren, Yi,Xu, Yong,Ji, Gaojie,Shen, Huolin,Gao, Junping. 2016

[19]Effects of chilling and high temperatures on photosynthesis and chlorophyll fluorescence in leaves of watermelon seedlings. Hou, W.,Yang, F. S.,Hou, W.,Pan, J. L.,Guan, M. Y.,Sun, A. H.,Chen, H. L..

[20]Effects of 5-aminolevulinic acid on nitrogen metabolism and ion distribution of watermelon seedlings under salt stress. Chen, G.,Fan, P. S.,Feng, W. M.,Guan, A. Q.,Lu, Y. Y.,Wan, Y. L..

作者其他论文 更多>>

微信小程序