农科机构知识库联盟

Young but not relatively old retrotransposons are preferentially located in gene-rich euchromatic regions in tomato (Solanum lycopersicum) plants

文献类型：外文期刊

第一作者： Yingxiu Xu

作者： Yingxiu Xu;Jianchang Du

作者机构：

关键词： targeting specificity;purifying selection;recombination;retrotransposon;tomato

期刊名称：PLANT JOURNAL （影响因子：6.417；五年影响因子：7.627 ）

ISSN：

年卷期：

页码：

收录情况： SCI

摘要： Long terminal repeat (LTR) retrotransposons are the major DNA components of flowering plants. They are generally enriched in pericentromeric heterochromatin regions of their host genomes, which could result from the preferential insertion of LTR retrotransposons and the low effectiveness of purifying selection in these regions. To estimate the relative importance of the actions of these two factors on their distribution pattern, the LTR retrotransposons in Solanum lycopersicum (tomato) plants were characterized at the genome level, and then the distribution of young elements was compared with that of relatively old elements. The current data show that old elements are mainly located in recombination-suppressed heterochromatin regions, and that young elements are preferentially located in the gene-rich euchromatic regions. Further analysis showed a negative correlation between the insertion time of LTR retrotransposons and the recombination rate. The data also showed there to be more solo LTRs in genic regions than in intergenic regions or in regions close to genes. These observations indicate that, unlike in many other plant genomes, the current LTR retrotransposons in tomatoes have a tendency to be preferentially located into euchromatic regions, probably caused by their severe suppression of activities in heterochromatic regions. These elements are apt to be maintained in heterochromatin regions, probably as a consequence of the pericentromeric effect in tomatoes. These results also indicate that local recombination rates and intensities of purifying selection in different genomic regions are largely responsible for structural variation and non-random distribution of LTR retrotransposons in tomato plants.

分类号： Q94

相关文献

[1]Genome-Wide Dissection of the Heat Shock Transcription Factor Family Genes in Arachis. Wang, Pengfei,Song, Hui,Li, Changsheng,Li, Pengcheng,Li, Aiqin,Guan, Hongshan,Hou, Lei,Wang, Xingjun,Wang, Xingjun. 2017

[2]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

[3]Population size may shape the accumulation of functional mutations following domestication. Chen, Jianhai,Ni, Pan,Li, Xinyun,Zhao, Shuhong,Chen, Jianhai,Ni, Pan,Li, Xinyun,Zhao, Shuhong,Han, Jianlin,Han, Jianlin,Jakovlic, Ivan,Zhang, Chengjun. 2018

[4]Genetic Variation and Divergence of Genes Involved in Leaf Adaxial-Abaxial Polarity Establishment in Brassica rapa. Liang, Jianli,Liu, Bo,Wu, Jian,Cheng, Feng,Wang, Xiaowu. 2016

[5]Shifts in the evolutionary rate and intensity of purifying selection between two Brassica genomes revealed by analyses of orthologous transposons and relics of a whole genome triplication. Zhao, Meixia,Tong, Chaobo,Yu, Jingyin,Huang, Shunmou,Liu, Shengyi,Zhao, Meixia,Du, Jianchang,Lin, Feng,Ma, Jianxin,Wang, Xiaowu. 2013

[6]Contribution of Multiple Inter-Kingdom Horizontal Gene Transfers to Evolution and Adaptation of Amphibian-Killing Chytrid, Batrachochytrium dendrobatidis. Sun, Baofa,Xiao, Jinhua,Zhang, Peng,He, Shunmin,Huang, Dawei,Sun, Baofa,Li, Tong,Liu, Li,Murphy, Robert W.,Huang, Dawei. 2016

[7]Genetic deviation in geographically close populations of the dengue vector Aedes aegypti (Diptera: Culicidae): influence of environmental barriers in South India. Vadivalagan, Chithravel,Murugan, Kadarkarai,Panneerselvam, Chellasamy,Paulpandi, Manickam,Madhiyazhagan, Pari,Dinesh, Devakumar,Karthika, Pushparaj,Wei, Hui,Aziz, Al Thabiani,Alsalhi, Mohamad Saleh,Devanesan, Sandhanasamy,Nicoletti, Marcello,Paramasivan, Rajaiah,Benelli, Giovanni.

[8]Retrotransposon- and microsatellite sequence-associated genomic changes in early generations of a newly synthesized allotetraploid Cucumis x hytivus Chen & Kirkbride. Lou, Qunfeng,Wu, Zhiming,Wang, Dong,Mbira, Kere George,Chen, Jinfeng,Jiang, Biao,Wu, Zhiming,Zhang, Wanping,Weng, Yiqun. 2011

[9]Wheat centromeric retrotransposons: the new ones take a major role in centromeric structure. Li, Baochun,Heng, Yanfang,Hao, Weiwei,Liu, Zhao,Yue, Wei,Zhang, Xueyong,Choulet, Frederic,Paux, Etienne,Feuillet, Catherine,Choulet, Frederic,Paux, Etienne,Feuillet, Catherine,Heng, Yanfang,Jin, Weiwei. 2013

[10]Structural organization of the barley D-hordein locus in comparison with its orthologous regions of wheat genomes. Gu, YQ,Anderson, OD,Londeore, CF,Kong, XY,Chibbar, RN,Lazo, GR. 2003

[11]Genome-wide characterization of long terminal repeat-retrotransposons in apple reveals the differences in heterogeneity and copy number between Ty1-copia and Ty3-gypsy retrotransposons. Sun, Hai-Yue,Dai, Hong-Yan,Zhao, Gui-Ling,Ma, Yue,Ou, Chun-Qing,Li, He,Li, Lin-Guang,Zhang, Zhi-Hong,Zhao, Gui-Ling,Li, Lin-Guang. 2008

[12]DKRE1-The first full-length Ty1-copia-like retrotransposon in persimmon: Isolation, characteristic and potential involvement in occurrence of bud mutations. Du, Xiaoyun,Wang, Yanbo,Zeng, Ming,Xie, Feng,Guan, Changfei,Mo, Rongli,Zhang, Qinglin,Luo, Zhengrong.

[13]Identification and characterization of a LTR retrotransposon from the genome of Cyprinus carpio var. Jian. Cao, Liping,Yin, Guojun,Cao, Zheming,Bing, Xuwen,Ding, Weidong.

[14]Isolation of two new retrotransposon sequences and development of molecular and cytological markers for Dasypyrum villosum (L.). Jiang, Yun,Guo, Yuanlin,Deng, Guangbing,Yu, Maoqun,Long, Hai,Xuan, Pu,Zhang, Jie.

[15]LTR retrotransposons cause expression changes of adjacent genes in early generations of the newly formed allotetraploid Cucumis hytivus. Jia, Li,Lou, Qunfeng,Wang, Dong,Chen, Jinfeng,Jiang, Biao.

[16]Complete genomic sequence analyses of Turnip mosaic virus basal-BR isolates from China. Wang, Hong-Yan,Liu, Jin-Liang,Gao, Rui,Chen, Jia,Shao, Yun-Hua,Li, Xiang-Dong,Wang, Hong-Yan,Liu, Jin-Liang,Gao, Rui. 2009

[17]Evolution of MHC class I genes in two ancient fish, paddlefish (Polyodon spathula) and Chinese sturgeon (Acipenser sinensis). Wang, Dengqiang,Zhong, Lei,Gan, Xiaoni,He, Shunping,Wang, Dengqiang,Wei, Qiwei,Wang, Dengqiang. 2010

[18]GISH characterization of Erianthus arundinaceus chromosomes in three generations of sugarcane intergeneric hybrids. Piperidis, Nathalie,Piperidis, George,Chen, Jian-wen,Deng, Hai-hua,Wang, Li-Ping,Jackson, Phillip. 2010

[19]Genomic analysis of a recombinant NADC30-like porcine reproductive and respiratory syndrome virus in china. Wang, Lin-jian,Guo, Zhenhua,Qiao, Songlin,Li, Rui,Xie, Sha,Chen, Xin-xin,Zhang, Gaiping,Wang, Lin-jian,Zhang, Gaiping,Wan, Bo,Zhang, Gaiping. 2018

[20]Genomic organization and sequence dynamics of the AvrPiz-t locus in Magnaporthe oryzae. Li, Ping,Bai, Bin,Zhang, Hong-yan,Zhou, Heng,Zhou, Bo,Li, Ping,Zhou, Heng. 2012

作者其他论文更多>>

GrTEdb: the first web-based database of transposable elements in cotton (Gossypium raimondii)

作者：Zhenzhen Xu;Jing Liu;Du, Jianchang;Shen, Xinlian;Wanchao Ni;Zhen Peng;Yue Guo;Wuwei Ye;Fang Huang;Xianggui Zhang;Peng Xu;Qi Guo;Xinlian Shen;Jianchang Du

关键词：

Young but not relatively old retrotransposons are preferentially located in gene-rich euchromatic regions in tomato (Solanum lycopersicum) plants

作者其他论文 更多>>

GrTEdb: the first web-based database of transposable elements in cotton (Gossypium raimondii)

作者其他论文更多>>