农科机构知识库联盟

Using Next-Generation Sequencing to Detect Differential Expression Genes in Bradysia odoriphaga after Exposure to Insecticides

文献类型：外文期刊

第一作者： Chen, Haoliang

作者： Chen, Haoliang;Lin, Lulu;Ali, Farman;Xie, Minghui;Zhang, Guangling;Su, Weihua;Ali, Farman

作者机构：

关键词： next-generation sequencing;Bradysia odoriphaga;differential expression genes;insecticide

期刊名称：INTERNATIONAL JOURNAL OF MOLECULAR SCIENCES （影响因子：5.923；五年影响因子：6.132 ）

ISSN： 1422-0067

年卷期： 2017 年 18 卷 11 期

页码：

收录情况： SCI

摘要： Bradysia odoriphaga (Diptera: Sciaridae) is the most important pest of Chinese chive. Insecticides are used widely and frequently to control B. odoriphaga in China. However, the performance of the insecticides chlorpyrifos and clothianidin in controlling the Chinese chive maggot is quite different. Using next generation sequencing technology, different expression unigenes (DEUs) in B. odoriphaga were detected after treatment with chlorpyrifos and clothianidin for 6 and 48 h in comparison with control. The number of DEUs ranged between 703 and 1161 after insecticide treatment. In these DEUs, 370-863 unigenes can be classified into 41-46 categories of gene ontology (GO), and 354-658 DEUs can be mapped into 987-1623 Kyoto Encyclopedia of Genes and Genomes (KEGG) pathways. The expressions of DEUs related to insecticide-metabolism-related genes were analyzed. The cytochrome P450-like unigene group was the largest group in DEUs. Most glutathione S-transferase-like unigenes were down-regulated and most sodium channel-like unigenes were up-regulated after insecticide treatment. Finally, 14 insecticide-metabolism-related unigenes were chosen to confirm the relative expression in each treatment by quantitative Real Time Polymerase Chain Reaction (qRT-PCR). The results of qRT-PCR and RNA Sequencing (RNA-Seq) are fairly well-established. Our results demonstrate that a next-generation sequencing tool facilitates the identification of insecticide-metabolism-related genes and the illustration of the insecticide mechanisms of chlorpyrifos and clothianidin.

分类号：

相关文献

[1]Target site insensitivity mutations in the AChE and LdVssc1 confer resistance to pyrethroids and carbamates in Leptinotarsa decemlineata in northern Xinjiang Uygur autonomous region. Jiang, Wei-Hua,Lu, Wei-Ping,Shi, Xiao-Qin,Xiong, Man-Hui,Wang, Zhi-Tian,Li, Guo-Qing,Guo, Wen-Chao.

[2]Effects of pyrethroids on neuronal excitability of adult honeybees Apis mellifera. Zhang, Yi-Li,Sun, Ji-Hu,Zhou, Ting,Zhou, Wei,Wang, Qiang,Dai, Ping-Li,Liu, Feng,Zhou, Ting,Zhou, Wei,Wang, Qiang,Dai, Ping-Li.

[3]Toxicity of chlorantraniliprole to Cry1Ac-susceptible and resistant strains of Helicoverpa armigera. Lu, Qiong,Zhang, Lili,Guo, Fang,Liang, Gemei,Wu, Kongming,Guo, Yuyuan,Wyckhuys, Kris A. G..

[4]Effects of Heat Shock on the Bradysia odoriphaga (Diptera: Sciaridae). Cheng, Jiaxu,Su, Qi,Shi, Caihua,Yang, Yuting,Cheng, Jiaxu,Han, Haolin,Xie, Wen,Guo, Zhaojiang,Wu, Qingjun,Xu, Baoyun,Wang, Shaoli,Zhang, Youjun,Jiao, Xiaoguo.

[5]Efficacy of entomopathogenic nematodes (Rhabditida: Steinernematidae and Heterorhabditidae) against the chive gnat, Bradysia odoriphaga. Ma, Juan,Chen, Shulong,Ma, Juan,Moens, Maurice,De Clercq, Patrick,Moens, Maurice,Han, Richou. 2013

[6]Effects of Temperature on the Age-Stage, Two-Sex Life Table of Bradysia odoriphaga (Diptera: Sciaridae). Li, Wenxiang,Xie, Wen,Wu, Qingjun,Xu, Baoyun,Wang, Shaoli,Zhu, Xun,Zhang, Youjun,Li, Wenxiang,Wang, Shijun,Yang, Yuting.

[7]Development of Bradysia odoriphaga (Diptera: Sciaridae) as affected by humidity: an age-stage, two-sex, life-table study. Yang, Yuting,Li, Chuanren,Yang, Yuting,Li, Wenxiang,Xie, Wen,Wu, Qingjun,Xu, Baoyun,Wang, Shaoli,Zhang, Youjun,Li, Wenxiang.

[8]Synergistic effect of entomopathogenic nematodes and thiamethoxam in controlling Bradysia odoriphaga Yang and Zhang (Diptera: Sciaridae). Wu, Haibin,Xu, Yongyu,Wu, Haibin,Gong, Qingtao,Fan, Kun,Sun, Ruihong,Zhang, Kunpeng.

[9]De novo sequencing and characterization of the Bradysia odoriphaga (Diptera: Sciaridae) larval transcriptome. Chen, Haoliang,Lin, Lulu,Xie, Minghui,Zhang, Guangling,Su, Weihua.

[10]Control of Bradysia odoriphaga (Diptera: Sciaridae) With Allyl Isothiocyanate Under Field and Greenhouse Conditions. Shi, Cai-hua,Hu, Jing-rong,Yang, Yu-ting,Shi, Cai-hua,Xie, Wen,Wang, Shao-li,Zhang, You-jun.

[11]Chlorfenapyr, a Potent Alternative Insecticide of Phoxim To Control Bradysia odoriphaga (Diptera: Sciaridae). Zhao, Yunhe,Wang, Qiuhong,Wang, Yao,Wei, Yan,Liu, Feng,Mu, Wei,Zhang, Zhengqun,Zhou, Chenggang,Wang, Qiuhong.

[12]Transcriptomic Identification of Drought-Related Genes and SSR Markers in Sudan Grass Based on RNA-Seq. Wang, Xia,Huang, Linkai,Zhang, Xinquan,Li, Zhou,Yan, Haidong,Zhu, Yongqun,Lin, Chaowen,Xu, Wenzhi,Luo, Fuxiang,Wang, Xie,Yao, Li,Peng, Dandan,Peng, Jianhua. 2017

[13]De novo assembly and transcriptome analysis of two contrary tillering mutants to learn the mechanisms of tillers outgrowth in switchgrass (Panicum virgatum L.). Kaijie Xu,Fengli Sun,Guaiqiang Chai,Yongfeng Wang,Lili Shi,Shudong Liu,Yajun Xi. 2015

[14]The complete chloroplast genome of Arabidopsis lyrata. Wu, Zhiqiang,Gu, Cuihua,Tembrock, Luke R.,Sun, Cheng. 2016

[15]De novo assembly and characterization of the transcriptome of the pancreatic fluke Eurytrema pancreaticum (trematoda: Dicrocoeliidae) using Illumina paired-end sequencing. Liu, Guo-Hua,Xu, Min-Jun,Song, Hui-Qun,Zhu, Xing-Quan,Wang, Chun-Ren,Zhu, Xing-Quan. 2016

[16]Complete mitochondrial genome of the kawakawa tuna Euthynnus affinis. Li, Mingming,Guo, Liang,Yang, Sen,Chen, Xinghan,Meng, Zining,Lin, Haoran,Zhang, Heng. 2016

[17]High-throughput development of simple sequence repeat markers for genetic diversity research in Crambe abyssinica. Qi, Weicong,Lin, Feng,Zhao, Han,Liu, Yuhe,Huang, Bangquan,Cheng, Jihua,Zhang, Wei. 2016

[18]Next-Generation Sequencing from Bulked-Segregant Analysis Accelerates the Simultaneous Identification of Two Qualitative Genes in Soybean. Guo, Yong,Qiu, Li-Juan. 2017

[19]Next-generation sequencing of the mitochondrial genome of Dolichovespula panda (Hymenoptera: Vespidae) with a phylogenetic analysis of Vespidae. Fan, Xu-Lei,Tan, Qing-Qing,Tan, Jiang-Li,Fan, Xu-Lei,Gong, Ya-Jun,Chen, Peng-Yan,Wei, Shu-Jun. 2017

[20]Apple necrotic mosaic virus, a novel ilarvirus from mosaic-diseased apple trees in Japan and China. Yamagishi, Noriko,Yoshikawa, Nobuyuki,Yaegashi, Hajime,Ito, Tsutae,Xing, Fei,Li, Shifang,Xie, Jipeng,Zhou, Tao,Xie, Jipeng,Zhou, Tao.

作者其他论文更多>>

Identification of Host-Protein Interaction Network of Canine Parvovirus Capsid Protein VP2 in F81 Cells

作者：Zhou, Hongzhuan;Zhang, Huanhuan;Su, Xia;Xu, Fuzhou;Xiao, Bing;Zhang, Jin;Qi, Qi;Lin, Lulu;Cui, Kaidi;Li, Qinqin;Li, Songping;Yang, Bing;Zhang, Huanhuan;Cui, Kaidi;Li, Qinqin;Li, Songping

关键词：CPV; VP2; protein interaction network; FHL2
The biological and agronomic nexus behind the resistance to protoporphyrinogen IX oxidase-inhibiting herbicides in crops

作者：Ali, Farman;Qiu, Zeyu;Yang, Yuwen;Zhang, Baolong;Fazal, Aliya

关键词：Crop breeding; herbicide resistance; protoporphyrinogen oxidase (PPO); sustainable agriculture; transgenic crops; weed management strategies
Coriander Derived E-2-Decenal Repels Fall Armyworm through Dedicated Olfactory Coding Involving SfruOBP13

作者：Zhong, Yongzhi;Lin, Lulu;Xie, Minghui;Chen, Haoliang;Zhao, Wen;Tang, Rui;Chai, Yaru;Li, Xiuxia;Zhang, Feng;Li, Fengqi

关键词：Integrated pest management; Push-pull; Insect-plant interaction; Odorant binding protein; Volatiles
Comprehensive transcriptome and metabolome analysis of the adaptability and detoxification ability of Spodoptera frugiperda larvae to tobacco

作者：Xie, Minghui;Zhong, Yongzhi;Lin, Lulu;Zhang, Guangling;Wei, Ning;Chen, Haoliang;Xie, Minghui;Zhong, Yongzhi;Lin, Lulu;Zhang, Guangling;Wei, Ning;Chen, Haoliang;Zhang, Feng

关键词：Spodoptera frugiperda; Transcriptomic; Metabolomic; Cytochrome P450
A comprehensive analysis of the WRKY family in soybean and functional analysis of GmWRKY164-GmGSL7c in resistance to soybean mosaic virus

作者：Zhao, Zhihua;Wang, Rongna;Su, Weihua;Sun, Tianjie;Qi, Mengnan;Zhang, Xueyan;Wei, Fengju;Zhang, Jie;Wang, Dongmei;Yu, Zhouliang;Xiao, Fuming;Yan, Long;Yang, Chunyan

关键词：Soybean; SMV; WRKY gene family; Callose deposition
Transcriptional Differential Analysis of Nitazoxanide-Mediated Anticanine Parvovirus Effect in F81 Cells

作者：Su, Xia;Zhou, Hongzhuan;Han, Ziwei;Xu, Fuzhou;Xiao, Bing;Zhang, Jin;Qi, Qi;Lin, Lulu;Zhang, Huanhuan;Li, Songping;Yang, Bing;Han, Ziwei;Zhang, Huanhuan;Li, Songping

关键词：canine parvovirus; nitazoxanide; RNA-seq; cell cycle
Chaperonin TRiC/CCT subunit CCT7 is involved in the replication of canine parvovirus in F81 cells

作者：Su, Xia;Zhou, Hongzhuan;Xu, Fuzhou;Zhang, Jin;Xiao, Bing;Qi, Qi;Lin, Lulu;Yang, Bing

关键词：canine parvovirus; CCT7; VP2; replication; stability

Using Next-Generation Sequencing to Detect Differential Expression Genes in Bradysia odoriphaga after Exposure to Insecticides

作者其他论文 更多>>

Identification of Host-Protein Interaction Network of Canine Parvovirus Capsid Protein VP2 in F81 Cells

The biological and agronomic nexus behind the resistance to protoporphyrinogen IX oxidase-inhibiting herbicides in crops

Coriander Derived E-2-Decenal Repels Fall Armyworm through Dedicated Olfactory Coding Involving SfruOBP13

Comprehensive transcriptome and metabolome analysis of the adaptability and detoxification ability of Spodoptera frugiperda larvae to tobacco

A comprehensive analysis of the WRKY family in soybean and functional analysis of GmWRKY164-GmGSL7c in resistance to soybean mosaic virus

Transcriptional Differential Analysis of Nitazoxanide-Mediated Anticanine Parvovirus Effect in F81 Cells

Chaperonin TRiC/CCT subunit CCT7 is involved in the replication of canine parvovirus in F81 cells

作者其他论文更多>>