Gene expression profiling related to powdery mildew resistance in wheat with the method of suppression subtractive hybridization

文献类型: 外文期刊

第一作者: Luo, M

作者: Luo, M;Kong, XY;Huo, NX;Zhou, RH;Jia, JZ

作者机构:

关键词: wheat;powdery mildew;suppression subtractive hybridization;disease resistance-related genes;gene expression profiling

期刊名称:CHINESE SCIENCE BULLETIN ( 影响因子:1.649; 五年影响因子:1.738 )

ISSN: 1001-6538

年卷期: 2002 年 47 卷 23 期

页码:

收录情况: SCI

摘要: "Bainong 3217 X Mardler" BC5F4 wheat line at the initial stage of inoculation with powdery mildew pathogen (Erysiphe graminis DC) was used to construct a suppression subtractive hybridization (SSH) cDNA library. Totally 760 ESTs were obtained through sequencing. Similarity analysis of ESTs based on BLASTn and BLASTx with the sequences in GenBank, in combination with macroarray differential screening, revealed that 199 ESTs of 65 kinds were known to be functionally disease resistance related. Based on the gene expression profiling in the present study, it is postulated that salicylic acid (SA) and MAP-related signal transduction pathways were involved in powdery mildew resistance in wheat. System acquired resistance genes were predominant in terms of kinds and quantity. With the initiation of cell defense reaction, the genes conferring anti-oxidation substances were largely expressed and thus cell protection mechanism was activated. Much evidence revealed that phenylpropanes metabolic pathway was involved in phytoalexin synthesis in wheat powdery mildew resistance. Genes conferring some enzymes of structural modification of cell walls and proteinase inhibitors inhibiting pathogen growth were also detected. The genes controlling a few proteinases (mainly cysteine proteinase) had a considerable redundancy of expression.

分类号:

  • 相关文献

[1]Molecular cloning, functional verification, and evolution of TmPm3, the powdery mildew resistance gene of Triticum monococcum L.. Zhao, C. Z.,Li, Y. H.,Dong, H. T.,Geng, M. M.,Liu, W. H.,Li, F.,Ni, Z. F.,Xie, C. J.,Sun, Q. X.,Zhao, C. Z.,Dong, H. T.,Geng, M. M.,Liu, W. H.,Li, F.,Ni, Z. F.,Xie, C. J.,Sun, Q. X.,Zhao, C. Z.,Wang, X. J.. 2016

[2]Intercropping influenced the occurrence of stripe rust and powdery mildew in wheat. Luo, Huisheng,Jin, Ming'an,Jin, Shelin,Jia, Qiuzhen,Zhang, Bo,Huang, Jin,Wang, Xiaoming,Sun, Zhenyu,Shang, Xunwu,Cao, Shiqin,Duan, Xiayu,Zhou, Yilin,Chen, Wanquan,Liu, Taiguo.

[3]AvrPm2 encodes an RNase-like avirulence effector which is conserved in the two different specialized forms of wheat and rye powdery mildew fungus. Praz, Coraline R.,Bourras, Salim,Sanchez-Martin, Javier,Menardo, Fabrizio,Roffler, Stefan,Boni, Rainer,Herren, Gerard,McNally, Kaitlin E.,Parlange, Francis,Oberhaensli, Simone,Fluckiger, Simon,Schafer, Luisa K.,Wicker, Thomas,Keller, Beat,Zeng, Fansong,Xue, Minfeng,Yang, Lijun,Yu, Dazhao,Zeng, Fansong,Xue, Minfeng,Yang, Lijun,Yu, Dazhao,Zeng, Fansong,Xue, Minfeng,Yang, Lijun,Yu, Dazhao,Ben-David, Roi.

[4]Molecular Characterization of a New Wheat-Thinopyrum intermedium Translocation Line with Resistance to Powdery Mildew and Stripe Rust. Zhan, Haixian,Li, Guangrong,Pan, Zhihui,Yang, Zujun,Zhan, Haixian,Zhang, Xiaojun,Hu, Jin,Li, Xin,Qiao, Linyi,Guo, Huijuan,Chang, Zhijian,Jia, Juqing,Chang, Zhijian. 2015

[5]Microsatellite markers linked to 2 powdery mildew resistance genes introgressed from Triticum carthlicum accession PS5 into common wheat. Zhu, ZD,Zhou, RH,Kong, XY,Dong, YC,Jia, JZ. 2005

[6]Molecular cytogenetic identification of a wheat-Thinopyron intermedium (Host) Barkworth & DR Dewey partial amphiploid resistant to powdery mildew. Wang, HG,Zhang, XY,Li, XF,Li, DY,Duan, XY,Zhou, YL. 2005

[7]Comparative analysis of early H2O2 accumulation in compatible and incompatible wheat-powdery mildew interactions. Li, AL,Wang, ML,Zhou, RH,Kong, XY,Huo, NX,Wang, WS,Jia, JZ. 2005

[8]Microsatellite marker identification of a Triticum aestivum Aegilops umbellulata substitution line with powdery mildew resistance. Zhu, Zhendong,Zhou, Ronghua,Kong, Xiuying,Kong, Xiuying,Dong, Yuchen,Jia, Jizeng. 2006

[9]Leaf rust resistance gene LR34 is involved in powdery mildew resistance of CIMMYT bread wheat line Saar. Lillemo, M.,Singh, R. P.,Huerta-Espino, J.,He, Z. H.,Brown, J. K. M.. 2007

[10]Analysis of differential transcriptional profiling in wheat infected by Blumeria graminis f. sp tritici using GeneChip. Wang, Jun-Mei,Liu, Hong-Yan,Wang, Jun-Mei,Liu, Hong-Yan,Xu, Hong-Ming,Li, Min,Wang, Jun-Mei,Liu, Hong-Yan,Kang, Zhen-Sheng,Kang, Zhen-Sheng,Kang, Zhen-Sheng. 2012

[11]Genome-wide identification and functional prediction of novel and fungi-responsive lincRNAs in Triticum aestivum. Zhang, Hong,Hu, Weiguo,Hao, Jilei,Lv, Shikai,Wang, Changyou,Tong, Wei,Wang, Yajuan,Wang, Yanzhen,Liu, Xinlun,Ji, Wanquan,Hu, Weiguo. 2016

[12]Comparative transcriptome analysis of basal and zygote-located tip regions of peanut ovaries provides insight into the mechanism of light regulation in peanut embryo and pod development. Zhang, Ye,Wang, Pengfei,Xia, Han,Zhao, Chuanzhi,Hou, Lei,Li, Changsheng,Zhao, Shuzhen,Wang, Xingjun,Zhang, Ye,Gao, Chao,Wang, Xingjun. 2016

[13]Genome-wide profiling of changes in gene expression in response to infection of the japonica rice variety Yunyin by Magnaporthe oryzae. Huang, Feng,Lian, Ling,He, Wei,Zhu, Yongsheng,Cai, Qiuhua,Xie, Huaan,Zhang, Jianfu,Huang, Feng,Lian, Ling,He, Wei,Zhu, Yongsheng,Cai, Qiuhua,Xie, Huaan,Zhang, Jianfu,Huang, Feng,Lian, Ling,He, Wei,Zhu, Yongsheng,Cai, Qiuhua,Xie, Huaan,Zhang, Jianfu,Huang, Feng,Lian, Ling,He, Wei,Zhu, Yongsheng,Cai, Qiuhua,Xie, Huaan,Zhang, Jianfu,Huang, Feng.

[14]Molecular identification, polymorphism, and expression analysis of major histocompatibility complex class IIA and B genes of turbot (Scophthalmus maximus). Zhang, Yu-Xi,Chen, Song-Lin.

[15]Transcriptome analysis of peach [Prunus persica (L.) Batsch] stigma in response to low-temperature stress with digital gene expression profiling. Jiao, Yun,Jiao, Yun,Shen, Zhijun,Yan, Juan.

[16]Physiological and transcriptional responses of two contrasting Populus clones to nitrogen stress. Wang, Xiaoli,Wang, Xiaoli,Li, Xiaodong,Zhang, Sheng,Korpelainen, Helena,Li, Chunyang.

[17]Characterization and Comparative Expression Profiling of Browning Response in Medinilla formosana after Cutting. Wang, Yan,Wang, Yiting,Song, Xijiao,Chen, Jianping,Liz, Kunfeng. 2016

[18]Gene expression profiling reveals U1 snRNA regulates cancer gene expression. Cheng, Zhi,Sun, Yu,Niu, Xiaoran,Shang, Yingchun,Gao, Shan,Zhang, Tao,Cheng, Zhi,Sun, Yu,Niu, Xiaoran,Shang, Yingchun,Gao, Shan,Zhang, Tao,Sun, Yu,Gao, Shan,Ruan, Jishou,Cheng, Zhi,Chen, Ze,Cheng, Zhi,Chen, Ze. 2017

[19]Quantitative trait loci identification, fine mapping and gene expression profiling for ovicidal response to whitebacked planthopper (Sogatella furcifera Horvath) in rice (Oryza sativa L.). Yang, Yaolong,Xu, Jie,Leng, Yujia,Hu, Jiang,Huang, Lichao,Wang, Lan,Guo, Longbiao,Qian, Qian,Zeng, Dali,Xiong, Guosheng,Li, Jiayang,Zeng, Dali,Chen, Feng. 2014

[20]Screening and analyzing genes associated with Amur tiger placental development. Li, Q.,Ma, J. Z.,Zhang, M. H.,Lu, T. F.,Hu, P. F.,Sun, B.,Wang, W. J.,Wang, K. F.,Zhang, W. X.,Guan, W. J.,Ma, Y. H.,Liu, D.,Chen, J.. 2014

作者其他论文 更多>>

微信小程序