Literature DB >> 25245166

Genome-wide analysis of the GRAS gene family in Prunus mume.

Jiuxing Lu1, Tao Wang, Zongda Xu, Lidan Sun, Qixiang Zhang.   

Abstract

Prunus mume is an ornamental flower and fruit tree in Rosaceae. We investigated the GRAS gene family to improve the breeding and cultivation of P. mume and other Rosaceae fruit trees. The GRAS gene family encodes transcriptional regulators that have diverse functions in plant growth and development, such as gibberellin and phytochrome A signal transduction, root radial patterning, and axillary meristem formation and gametogenesis in the P. mume genome. Despite the important roles of these genes in plant growth regulation, no findings on the GRAS genes of P. mume have been reported. In this study, we discerned phylogenetic relationships of P. mume GRAS genes, and their locations, structures in the genome and expression levels of different tissues. Out of 46 identified GRAS genes, 45 were located on the 8 P. mume chromosomes. Phylogenetic results showed that these genes could be classified into 11 groups. We found that Group X was P. mume-specific, and three genes of Group IX clustered with the rice-specific gene Os4. We speculated that these genes existed before the divergence of dicotyledons and monocotyledons and were lost in Arabidopsis. Tissue expression analysis indicated that 13 genes showed high expression levels in roots, stems, leaves, flowers and fruits, and were related to plant growth and development. Functional analysis of 24 GRAS genes and an orthologous relationship analysis indicated that many functioned during plant growth and flower and fruit development. Our bioinformatics analysis provides valuable information to improve the economic, agronomic and ecological benefits of P. mume and other Rosaceae fruit trees.

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Year:  2014        PMID: 25245166     DOI: 10.1007/s00438-014-0918-1

Source DB:  PubMed          Journal:  Mol Genet Genomics        ISSN: 1617-4623            Impact factor:   3.291


  47 in total

1.  [MapDraw: a microsoft excel macro for drawing genetic linkage maps based on given genetic linkage data].

Authors:  Ren-Hu Liu; Jin-Ling Meng
Journal:  Yi Chuan       Date:  2003-05

2.  Unraveling ancient hexaploidy through multiply-aligned angiosperm gene maps.

Authors:  Haibao Tang; Xiyin Wang; John E Bowers; Ray Ming; Maqsudul Alam; Andrew H Paterson
Journal:  Genome Res       Date:  2008-10-02       Impact factor: 9.043

3.  The gibberellin signaling pathway is regulated by the appearance and disappearance of SLENDER RICE1 in nuclei.

Authors:  Hironori Itoh; Miyako Ueguchi-Tanaka; Yutaka Sato; Motoyuki Ashikari; Makoto Matsuoka
Journal:  Plant Cell       Date:  2002-01       Impact factor: 11.277

4.  Synergistic derepression of gibberellin signaling by removing RGA and GAI function in Arabidopsis thaliana.

Authors:  A Dill; T Sun
Journal:  Genetics       Date:  2001-10       Impact factor: 4.562

5.  Cleavage of Scarecrow-like mRNA targets directed by a class of Arabidopsis miRNA.

Authors:  Cesar Llave; Zhixin Xie; Kristin D Kasschau; James C Carrington
Journal:  Science       Date:  2002-09-20       Impact factor: 47.728

6.  The GA-signaling repressor RGL3 represses testa rupture in response to changes in GA and ABA levels.

Authors:  Urszula Piskurewicz; Luis Lopez-Molina
Journal:  Plant Signal Behav       Date:  2009-01

7.  Two GRAS proteins, SCARECROW-LIKE21 and PHYTOCHROME A SIGNAL TRANSDUCTION1, function cooperatively in phytochrome A signal transduction.

Authors:  Patricia Torres-Galea; Birgit Hirtreiter; Cordelia Bolle
Journal:  Plant Physiol       Date:  2012-10-29       Impact factor: 8.340

8.  Molecular analysis of SCARECROW function reveals a radial patterning mechanism common to root and shoot.

Authors:  J W Wysocka-Diller; Y Helariutta; H Fukaki; J E Malamy; P N Benfey
Journal:  Development       Date:  2000-02       Impact factor: 6.868

9.  Gibberellin-mediated proteasome-dependent degradation of the barley DELLA protein SLN1 repressor.

Authors:  Xiangdong Fu; Donald E Richards; Tahar Ait-Ali; Llewelyn W Hynes; Helen Ougham; Jinrong Peng; Nicholas P Harberd
Journal:  Plant Cell       Date:  2002-12       Impact factor: 11.277

10.  The genome of Prunus mume.

Authors:  Qixiang Zhang; Wenbin Chen; Lidan Sun; Fangying Zhao; Bangqing Huang; Weiru Yang; Ye Tao; Jia Wang; Zhiqiong Yuan; Guangyi Fan; Zhen Xing; Changlei Han; Huitang Pan; Xiao Zhong; Wenfang Shi; Xinming Liang; Dongliang Du; Fengming Sun; Zongda Xu; Ruijie Hao; Tian Lv; Yingmin Lv; Zequn Zheng; Ming Sun; Le Luo; Ming Cai; Yike Gao; Junyi Wang; Ye Yin; Xun Xu; Tangren Cheng; Jun Wang
Journal:  Nat Commun       Date:  2012       Impact factor: 14.919
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  26 in total

1.  Molecular cloning, phylogenetic analysis, and expression patterns of LATERAL SUPPRESSOR-LIKE and REGULATOR OF AXILLARY MERISTEM FORMATION-LIKE genes in sunflower (Helianthus annuus L.).

Authors:  Marco Fambrini; Mariangela Salvini; Claudio Pugliesi
Journal:  Dev Genes Evol       Date:  2016-12-29       Impact factor: 0.900

2.  A novel SCARECROW-LIKE3 transcription factor LjGRAS36 in Lotus japonicus regulates the development of arbuscular mycorrhizal symbiosis.

Authors:  Yunjian Xu; Fang Liu; Fulang Wu; Manli Zhao; Ruifan Zou; Jianping Wu; Xiaoyu Li
Journal:  Physiol Mol Biol Plants       Date:  2022-03-29

3.  Integrative Analysis of the GRAS Genes From Chinese White Pear (Pyrus bretschneideri): A Critical Role in Leaf Regeneration.

Authors:  Xinya Wang; Muhammad Aamir Manzoor; Mengna Wang; Yu Zhao; Xiaofeng Feng; Pravej Alam; Xujing Chi; Yongping Cai
Journal:  Front Plant Sci       Date:  2022-06-06       Impact factor: 6.627

4.  Comprehensive analysis of multi-tissue transcriptome data and the genome-wide investigation of GRAS family in Phyllostachys edulis.

Authors:  Hansheng Zhao; Lili Dong; Huayu Sun; Lichao Li; Yongfeng Lou; Lili Wang; Zuyao Li; Zhimin Gao
Journal:  Sci Rep       Date:  2016-06-21       Impact factor: 4.379

5.  Genome-wide identification and characterization of GRAS transcription factors in sacred lotus (Nelumbo nucifera).

Authors:  Yu Wang; Shenglu Shi; Ying Zhou; Yu Zhou; Jie Yang; Xiaoqing Tang
Journal:  PeerJ       Date:  2016-08-31       Impact factor: 2.984

6.  Genome-wide identification, expression analysis, and functional study of the GRAS transcription factor family and its response to abiotic stress in sorghum [Sorghum bicolor (L.) Moench].

Authors:  Yu Fan; Jun Yan; Dili Lai; Hao Yang; Guoxing Xue; Ailing He; Tianrong Guo; Long Chen; Xiao-Bin Cheng; Da-Bing Xiang; Jingjun Ruan; Jianping Cheng
Journal:  BMC Genomics       Date:  2021-07-06       Impact factor: 3.969

7.  Genome-wide identification, phylogeny and expression analysis of GRAS gene family in tomato.

Authors:  Wei Huang; Zhiqiang Xian; Xia Kang; Ning Tang; Zhengguo Li
Journal:  BMC Plant Biol       Date:  2015-08-25       Impact factor: 4.215

8.  Structural and Functional Analysis of the GRAS Gene Family in Grapevine Indicates a Role of GRAS Proteins in the Control of Development and Stress Responses.

Authors:  Jérôme Grimplet; Patricia Agudelo-Romero; Rita T Teixeira; Jose M Martinez-Zapater; Ana M Fortes
Journal:  Front Plant Sci       Date:  2016-03-30       Impact factor: 5.753

9.  Identification of Known and Novel microRNAs and Their Targets in Peach (Prunus persica) Fruit by High-Throughput Sequencing.

Authors:  Chunhua Zhang; Binbin Zhang; Ruijuan Ma; Mingliang Yu; Shaolei Guo; Lei Guo; Nicholas Kibet Korir
Journal:  PLoS One       Date:  2016-07-28       Impact factor: 3.240

10.  Genome-Wide Identification, Evolutionary Analysis, and Stress Responses of the GRAS Gene Family in Castor Beans.

Authors:  Wei Xu; Zexi Chen; Naeem Ahmed; Bing Han; Qinghua Cui; Aizhong Liu
Journal:  Int J Mol Sci       Date:  2016-06-24       Impact factor: 5.923
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