The Complete Mitochondrial Genome of Aleurocanthus camelliae: Insights into Gene Arrangement and Genome Organization within the Family Aleyrodidae

文献类型: 外文期刊

第一作者: Chen, Shi-Chun

作者: Chen, Shi-Chun;Wang, Xiao-Qing;Hu, Xiang;Peng, Ping;Li, Pin-Wu;Wang, Jin-Jun

作者机构:

关键词: Aleurocanthus camelliae;whitefly;mitochondrial genome;rearrangement;genome evolution

期刊名称:INTERNATIONAL JOURNAL OF MOLECULAR SCIENCES ( 影响因子:4.9; 五年影响因子:5.6 )

ISSN: 1422-0067

年卷期: 2016 年 17 卷 11 期

页码:

收录情况: SCI

摘要: There are numerous gene rearrangements and transfer RNA gene absences existing in mitochondrial (mt) genomes of Aleyrodidae species. To understand how mt genomes evolved in the family Aleyrodidae, we have sequenced the complete mt genome of Aleurocanthus camelliae and comparatively analyzed all reported whitefly mt genomes. The mt genome of A. camelliae is 15,188 bp long, and consists of 13 protein-coding genes, two rRNA genes, 21 tRNA genes and a putative control region (GenBank: KU761949). The tRNA gene, trnI, has not been observed in this genome. The mt genome has a unique gene order and shares most gene boundaries with Tetraleurodes acaciae. Nineteen of 21 tRNA genes have the conventional cloverleaf shaped secondary structure and two (trnS(1) and trnS(2)) lack the dihydrouridine (DHU) arm. Using ARWEN and homologous sequence alignment, we have identified five tRNA genes and revised the annotation for three whitefly mt genomes. This result suggests that most absent genes exist in the genomes and have not been identified, due to be lack of technology and inference sequence. The phylogenetic relationships among 11 whiteflies and Drosophila melanogaster were inferred by maximum likelihood and Bayesian inference methods. Aleurocanthus camelliae and T. acaciae form a sister group, and all three Bemisia tabaci and two Bemisia afer strains gather together. These results are identical to the relationships inferred from gene order. We inferred that gene rearrangement plays an important role in the mt genome evolved from whiteflies.

分类号:

  • 相关文献

[1]Analysis of the complete mitochondrial genome of Pochonia chlamydosporia suggests a close relationship to the invertebrate-pathogenic fungi in Hypocreales. Lin, Runmao,Liu, Chichuan,Shen, Baoming,Ling, Jian,Chen, Guohua,Mao, Zhenchuan,Xie, Bingyan,Shen, Baoming,Bai, Miao,Cheng, Xinyue. 2015

[2]Mycoreovirus genome alterations: similarities to and differences from rearrangements reported for other reoviruses. Tanaka, Toru,Eusebio-Cope, Ana,Suzuki, Nobuhiro,Sun, Liying. 2012

[3]Characterization of the Transgenic Rice Event TT51-1 and Construction of a Reference Plasmid. Cao, Yinglong,Wu, Gang,Wu, Yuhua,Nie, Shujing,Zhang, Li,Lu, Changming.

[4]Mycoreovirus 1 S4-coded protein is dispensable for viral replication but necessary for efficient vertical transmission and normal symptom induction. Eusebio-Cope, Ana,Suzuki, Nobuhiro,Sun, Liying,Hillman, Bradley I.. 2010

[5]Horizontal Transfer of Non-LTR Retrotransposons from Arthropods to Flowering Plants. Gao, Dongying,Xia, Han,Xu, Chunming,Abernathy, Brian,Jackson, Scott A.,Chu, Ye,Ozias-Akins, Peggy,Xia, Han,Heyduk, Karolina,Leebens-Mack, James H.. 2018

[6]Genome evolutionary dynamics followed by diversifying selection explains the complexity of the Sesamum indicum genome. Yu, Jingyin,Wang, Linhai,Liao, Boshou,Zhang, Xiurong,Guo, Hui,King, Graham,King, Graham. 2017

[7]Comparative Genomic Analysis of Bacillus amyloliquefaciens and Bacillus subtilis Reveals Evolutional Traits for Adaptation to Plant-Associated Habitats. Zhang, Nan,Yang, Dongqing,Kendall, Joshua R. A.,Shen, Qirong,Zhang, Ruifu,Zhang, Nan,Yang, Dongqing,Kendall, Joshua R. A.,Shen, Qirong,Zhang, Ruifu,Kendall, Joshua R. A.,Borriss, Rainer,Druzhinina, Irina S.,Kubicek, Christian P.,Zhang, Ruifu. 2016

[8]LTRtype, an Efficient Tool to Characterize Structurally Complex LTR Retrotransposons and Nested Insertions on Genomes. Zeng, Fan-Chun,Zhao, You-Jie,Gao, Li-Zhi,Zhang, Que-Jie,Gao, Li-Zhi,Zhang, Que-Jie. 2017

[9]Conserved globulin gene across eight grass genomes identify fundamental units of the loci encoding seed storage proteins. Gu, Yong Qiang,Wanjugi, Humphrey,Coleman-Derr, Devin,Anderson, Olin D.,Kong, Xiuying.

[10]Molecular evolution of the rice miR395 gene family. Guddeti, S,Zhang, DC,Li, AL,Leseberg, CH,Kang, H,Li, XG,Zhai, WX,Johns, MA,Mao, L.

[11]Rapid evolution and complex structural organization in genomic regions harboring multiple prolamin genes in the polyploid wheat genome. Gao, Shuangcheng,Gu, Yong Qiang,Wu, Jiajie,Coleman-Derr, Devin,Huo, Naxin,Crossman, Curt,Jia, Jizeng,Zuo, Qi,Ren, Zhenglong,Anderson, Olin D.,Kong, Xiuying.

[12]Escape from preferential retention following repeated whole genome duplications in plants. Schnable, James C.,Freeling, Michael,Wang, Xiaowu,Pires, J. Chris. 2012

[13]Identification and expression profiling of five chemosensory protein genes in the whitefly MED, Bemisia tabaci. Wang, Ran,Zhang, Xiao-man,Guo, Xiao-jun,Luo, Chen,Li, Hong-liang. 2016

[14]Diversity and Genetic Differentiation of the Whitefly Bemisia tabaci Species Complex in China Based on mtCOI and cDNA-AFLP Analysis. Guo Xiao-jun,Rao Qiong,Zhang Fan,Luo Chen,Guo Xiao-jun,Gao Xi-wu,Rao Qiong,Zhang Hong-yu. 2012

[15]Identification of plant chemicals attracting and repelling whiteflies. Li, Yaofa,Zhong, Suting,Qin, Yuchuan,Li, Yaofa,Gao, Zhanlin,Dang, Zhihong,Pan, Wenliang,Zhang, Shangqing. 2014

[16]Cloning of a putative extracellular Cu/Zn superoxide dismutase and functional differences of superoxide dismutases in invasive and indigenous whiteflies. Gao, Xian-Long,Xu, Hong-Xing,Yan, Gen-Hong,Liu, Shu-Sheng,Wang, Xiao-Wei,Li, Jun-Min,Jiu, Min. 2015

[17]Cloning, Expression and Characterization of Mitochondrial Manganese Superoxide Dismutase from the Whitefly, Bemisia tabaci. Gao, Xian-Long,Wang, Yong-Liang,Yan, Gen-Hong,Liu, Shu-Sheng,Wang, Xiao-Wei,Li, Jun-Min,Jiu, Min. 2013

[18]Host instar suitability in two invasive whiteflies for the naturally occurring parasitoid Eretmocerus hayati in China. Yang, Nian-Wan,Wan, Fang-Hao,Zhang, Yi-Bo,Sun, Li-Ying.

[19]BIOTYPE EXPRESSION AND INSECTICIDE RESPONSE OF Bemisia tabaci CHEMOSENSORY PROTEIN-1. Liu, Guo Xia,Xuan, Ning,Chu, Dong,Xie, Hong Yan,Fan, Zhong Xue,Bi, Yu Ping,Picimbon, Jean-Francois,Qin, Yu Chuan,Zhong, Su Ting,Li, Yao Fa,Gao, Zhan Lin,Pan, Wen Liang,Wang, Guo Ying,Rajashekar, Balaji.

[20]Dissipation rate of thiacloprid and its control effect against Bemisia tabaci in greenhouse tomato after soil application. Dong, Sa,Qiao, Kang,Zhu, Yukun,Xia, Xiaoming,Wang, Kaiyun,Wang, Hongyan.

作者其他论文 更多>>

微信小程序