Genome-Wide Gene/Genome Dosage Imbalance Regulates Gene Expressions in Synthetic Brassica napus and Derivatives (AC, AAC, CCA, CCAA)

文献类型: 外文期刊

第一作者: Pan, Qi

作者: Pan, Qi;Xiang, Yi;Ge, Xianhong;Li, Zaiyun;Cui, Cheng

作者机构:

关键词: dosage imbalance;gene expression;cisltrans effects;Brassica;polyploids

期刊名称:FRONTIERS IN PLANT SCIENCE ( 影响因子:5.753; 五年影响因子:6.612 )

ISSN: 1664-462X

年卷期: 2016 年 7 卷

页码:

收录情况: SCI

摘要: Gene/genome dosage balance is an essential evolutionary mechanism for organisms to ensure a normal function, but the underlying causes of dosage-imbalance regulation remain poorly understood. Herein, the serial Brassica hybrids/polyploids (AC, MC, CCA, CCAA) with different copies of A and C subgenomes from the same two parents of Brassica rapa and Brassica oleracea were synthesized to investigate the effects of genome dosages on gene expressions and interactions by using RNA-Seq. The expression changes of A- and C-subgenome genes were consistent with dosage alterations. Dosage-dependent and-independent genes were grouped according to the correlations between dosage variations and gene expressions. Expression levels of dosage-dependent genes were strongly correlated with dosage changes and mainly contributed to dosage effects, while those of dosage-independent genes gave weak correlations with dosage variations and mostly facilitated dosage compensation. More protein protein interactions were detected for dosage-independent genes than dosage-dependent ones, as predicted by the dosage balance hypothesis. Dosage-dependent genes more likely impacted the expressions by trans effects, whereas dosage-independent genes preferred to play by cis effects. Furthermore, dosage-dependent genes were mainly associated with the basic biological processes to maintain the stability of the growth and development, while dosage-independent genes were more enriched in the stress response related processes to accelerate adaptation. The present comprehensive analysis of gene expression dependent/independent on dosage alterations in Brassica polyploids provided new insights into gene/genome dosage-imbalance regulation of gene expressions.

分类号:

  • 相关文献

[1]Rapid alterations of gene expression and cytosine methylation in newly synthesized Brassica napus allopolyploids. Xu, Yanhao,Zhong, Lan,Wang, Jianbo,Wu, Xiaoming,Fang, Xiaoping.

[2]Genomic and transcriptomic alterations following hybridisation and genome doubling in trigenomic allohexaploid Brassica carinata x Brassica rapa. Xu, Y.,Zhao, Q.,Wang, J.,Xu, Y.,Mei, S.. 2012

[3]Effect of Gibberellin on the Biosynthesis of Tocopherols in Oilseed Rape (Brassica napus L.) and Arabidopsis. Du, Xue,Hussain, Nazim,Li, Zhilan,Jiang, Lixi,Chen, Xiaoyang,Hua, Shuijin,Zhang, Dongqing.

[4]Inheritance of anthocyanin content in the ripe berries of a tetraploid x diploid grape cross population. Liang, Zhenchang,Li, Shaohua,Liang, Zhenchang,Wu, Benhong,Liang, Zhenchang,Wu, Benhong,Sang, Min,Ma, Aihong,Zhao, Shengjian,Zhong, Gan-Yuan.

[5]Widespread and evolutionary analysis of a MITE family Monkey King in Brassicaceae. Dai, Shutao,Hou, Jinna,Long, Yan,Wang, Jing,Li, Cong,Xiao, Qinqin,Jiang, Xiaoxue,Zou, Xiaoxiao,Zou, Jun,Meng, Jinling,Hou, Jinna. 2015

[6]Cloning of fatty acid elongase 1 gene and molecular identification of A and C genome in Brassica species. Wu Yuhua,Xiao Ling,Wu Gang,Lu ChangMing. 2007

[7]Selective modes determine evolutionary rates, gene compactness and expression patterns in Brassica. Liu, Jing,Du, Jianchang,Zhang, Jiefu,Du, Jianchang,Liu, Shengyi,Du, Jianchang. 2017

[8]Mining for Candidate Genes in an Introgression Line by Using RNA Sequencing: The Anthocyanin Overaccumulation Phenotype in Brassica. Xie, Lulu,Li, Fei,Zhang, Shifan,Zhang, Hui,Qian, Wei,Li, Peirong,Zhang, Shujiang,Sun, Rifei. 2016

[9]Comparative proteome analysis of metabolic changes by low phosphorus stress in two Brassica napus genotypes. Yao, Yinan,Sun, Haiyan,Zhang, Xuejiang,Liu, Shengyi,Yao, Yinan,Xu, Fangsen.

[10]Crossover rate between homologous chromosomes and interference are regulated by the addition of specific unpaired chromosomes in Brassica. Suay, Loreto,Zhang, Deshuang,Eber, Frederique,Jouy, Helene,Lode, Maryse,Huteau, Virginie,Coriton, Olivier,Szadkowski, Emmanuel,Paillard, Sophie,Chevre, Anne-Marie,Zhang, Deshuang,Leflon, Martine,Martin, Olivier C.,Falque, Matthieu,Jenczewski, Eric.

[11]Seed coat development and its evolutionary implications in diploid and amphidiploid Brassica species. Zeng, Chang-Li,Wu, Xiao-Ming,Wang, Jian-Bo.

[12]Different fertility and meiotic regularity in allohexaploids derived from trigenomic hybrids between three cultivated Brassica allotetraploids and B. maurorum. Yao, Xingcheng,Ge, Xianhong,Li, Zaiyun,Yao, Xingcheng. 2012

[13]New host resistances to Pseudocercosporella capsellae and implications for white leaf spot management in Brassicaceae crops. Gunasinghe, Niroshini,You, Ming Pei,Barbetti, Martin J.,Barbetti, Martin J.,Li, Xi Xiang,Banga, Surinder S.,Banga, Shashi K..

[14]Evaluation of genetic diversity and relationships in orchardgrass (Dactylis glomerata L.) germplasm based on SRAP markers. Zhang, Xin-Quan,Zeng, Bing,Lan, Ying,Yang, Wu-Yun.

[15]Genome-wide microsatellite characterization and marker development in the sequenced brassica crop species. Shi, Jiaqin,Huang, Shunmou,Zhan, Jiepeng,Yu, Jingyin,Wang, Xinfa,Hua, Wei,Liu, Shengyi,Liu, Guihua,Wang, Hanzhong.

[16]Genetic and histological characterization of a novel recessive genic male sterile line of Brassica napus derived from a cross with Capsella bursa-pastoris. Chen, Hai-Feng,Ge, Xian-Hong,Du, Xue-Zhu,Zhao, Zhi-Gang,Li, Zai-Yun,Chen, Hai-Feng.

[17]A Phylogenetic Analysis of Chloroplast Genomes Elucidates the Relationships of the Six Economically Important Brassica Species Comprising the Triangle of U. Li, Peirong,Zhang, Shujiang,Li, Fei,Zhang, Shifan,Zhang, Hui,Wang, Xiaowu,Sun, Rifei,Li, Peirong,Bonnema, Guusje,Borm, Theo J. A.. 2017

[18]Comparative genotype reactions to Sclerotinia sclerotiorum within breeding populations of Brassica napus and B-juncea from India and China. Barbetti, M. J.,Ge, X. T.,Barbetti, M. J.,Banga, S. K.,Banga, S. S.,Fu, T. D.,Li, Y. C.,Liu, S. Y.,Singh, D..

[19]A fitness cost for Turnip mosaic virus to overcome host resistance. Jenner, CE,Wang, XW,Ponz, F,Walsh, JA. 2002

[20]Genome-wide analysis of UDP-glycosyltransferase super family in Brassica rapa and Brassica oleracea reveals its evolutionary history and functional characterization. Yu, Jingyin,Dossa, Komivi,Ke, Tao,Hu, Fan,Wang, Zhaokai,Yu, Jingyin,Dossa, Komivi. 2017

作者其他论文 更多>>

微信小程序