Analysis of the Antennal Transcriptome and Identification of Olfaction-related Genes of Trialeurodes vaporariorum
CAI Sai-Bo1,2, YIN Chao-Kun3, ZHANG Man1,2, LIN Lian-Bing1,2, ZHANG Qi-Lin1,2*
1. Faculty of Life Science and Technology,Kunming University of Science and Technology,Kunming 650500,China; 2. Engineering Research Center for Replacement Technology of Feed Antibiotics of Yunnan College,Kunming 650500,China; 3. School of Electrical and Information Engineering,Changzhou Institute of Technology,Changzhou 213032,China
Abstract:Trialeurodes vaporariorum is a worldwide pest with the characteristics of multi feeding and wide host range. Antennae is an important organ for insect information exchange,and its olfaction-related genes are an important molecular basis for regulating insect feeding behavior. However,to date,there are few reports about gene data of T. vaporariorum antennae,and little is known about the number and type of primary olfaction-related genes. The purpose of this study is to establish a transcriptomic database of T. vaporariorum antennae,and to investigate the number of genes encoding olfaction-related proteins. The antennal transcriptomes of adult T. vaporariorum were sequenced using Illumina HiSeq 4000 platform,and bioinformatic analyses were conducted. In this study,32 890 unigenes were obtained through assembling after transcriptome sequencing,with mean length of 1 616 bp and an N50 value of 3 059 bp,and 14 206 unigenes over 1 000 bp in size.After annotating for unigenes in gene function database,17 846 unigenes obtained functional annotation information. Sequences searched into NR database (non-redundant protein sequence database) accounted for 88.77% of all annotated unigenes,most of which was optimally hit to genes of Bemisia tabaci (87.12%) species. Annotated results in GO database showed that unigenes were divided into 54 subcategories included into 3 categories,and a lot of unigenes were annotated to be associated with metabolic process and catalytic activity. In KEGG database,5 964 unigenes were annotated in 228 metabolic pathways. Among them,most unigenes (189) were involved in metabolic pathways of ribosome. Based on further annotated information of unigenes,33 genes encoding olfaction-related proteins of T. vaporariorum including 21 genes encoding odorant binding proteins (OBPs),5 genes encoding chemosensory proteins (CSPs),2 genes encoding olfactory receptor proteins (OLRs),3 genes encoding odorant receptor proteins (ORs),1 gene encoding ionotropic receptor protein (IR) and 1 gene encoding sensory neuron membrane protein (SNMP). This study obtained the antennal transcriptomic data of adult T. vaporariorum,its characteristics were preliminarily elucidated,as well as genes encoding olfaction-related proteins were identified. This result provides a reference for further investigation on behavior regulation and new control strategies of T. vaporariorum at molecular levels,and also enriches the gene database of horticultural pests.
[1] 杜迎刚,季清娥,赖钟雄.2019.南亚实蝇转录组及嗅觉相关基因的初步分析[J].热带作物学报,4(9):1796-1803. (Du Y,Ji Q,Lai Z.2019.Preliminary analysis of transcriptome and olfaction-related genes inBactrocera tau(Walker)[J].Chinese Journal of Tropical Crops,4(9):1796-1803.) [2] 巩中军,周文武,祝增荣,等.2008.昆虫嗅觉受体的研究进展[J].昆虫学报,51(7):761-768. (Gong Z J,Zhou W W,Zhu Z R,et al.2018.Advances in the study of olfactory receptors in insects[J].Acta Entomologica Sinica,51(7):761-768.) [3] 李卫华,涂洪涛,苗雪霞,等.2006.昆虫嗅觉相关蛋白的研究进展[J].应用昆虫学报,43(6):757-762. (Li W H,Tu H T,Miao X X,et al.2006.Advances in olfactory related proteins in insects[J].Chinese Journal of Applied Entomology,43(6):757-762.) [4] 王书平,郭殿豪,李飞.2016.烟粉虱基因组和转录组研究及展望[J].植物保护学报,043(1):18-23. (Wang S P,Guo D H,Li F.2016.The progress of genome and transcriptome analysis ofBemisia tabaciand its future perspectives[J].Journal of Plant Protection,043(1):18-23.) [5] 王兴春,谭河林,陈钊,等.2015.基于RNA-Seq技术的连翘转录组组装与分析及SSR分子标记的开发[J].中国科学:生命科学,45(3):301-310. (Wang X C,Tan H L,Chen Z,et al.2015.Assembly and characterization of the transcriptome and development of SSR markers inForsythia suspensabased on RNA-seq technology[J].Scientia Sinica Vitae,45(3):301-310.) [6] 张棋麟,袁明龙,2013.基于新一代测序技术的昆虫转录组学研究进展[J].昆虫学报,56(12):1489-1508. (Zhang Q L,Yuan M L.2013.Progress in insect transcriptomics based on the next generation sequencing technique[J].Acta Entomologica Sinica,56(12):1489-1508.) [7] 郑海霞,张耀文,张仙红,等.2018.绿豆象触角转录组及嗅觉相关基因的分析[J].昆虫学报,61(2):168-177. (Zheng H X,Zhang Y W,Zhang X H,et al.2018.Analysis of the antennal transcriptome and olfaction-related genes ofCallosobruchus chinensis(Coleoptera:Bruchuidae)[J].Acta Entomologica Sinica,61(2):168-177.) [8] An X K,Sun L,Liu H W,et al.2016.Identification and expression analysis of an olfactory receptor gene family in green plant bugApolygus lucorum(Meyer-Dür)[J].Scientific Reports,6:37870. [9] Antony B,Soffan A,Jakše J,et al.2016.Identification of the genes involved in odorant reception and detection in the palm weevilRhynchophorus ferrugineus,an important quarantine pest,by antennal transcriptome analysis[J].BMC Genomics,17:69. [10] Benton R,Vannice K,Gomez-Diaz C,et al.2009.Variant ionotropic glutamate receptors as chemosensory receptors inDrosophila[J].Cell,136(1):149-162. [11] Bolger A M,Lohse M,Usadel B.2014.Trimmomatic:A flexible trimmer for Illumina sequence data[J].Bioinformatics,30(15):2114-2120. [12] Brown E,Layne J,Zhu C,et al.2013.Genome-wide association mapping of natural variation in odor-guided behavior inDrosophila[J].Genes,Brain,and Behavior,12:503-515. [13] Brown J.1994.Current status ofBemisia tabacias plant pest and virus vector in agroecosystem worldwide FAO[J].FAO Plant Protection Bulletin,42(1/2):3-32. [14] Cao D,Liu Y,Walker W,et al.2014.Molecular characterization of theAphis gossypiiolfactory receptor gene families[J].PLOS ONE,9:e101187. [15] Chen W B,Hasegawa D K,Kaur N,et al.2016.The draft genome of whiteflyBemisia tabaciMEAM1,a global crop pest,provides novel insights into virus transmission,host adaptation,and insecticide resistance[J].BMC Biology,14:110. [16] Field L,Pickett J,Wadhams L.2001.Molecular studies in insect olfaction[J].Insect Molecular Biology,9:545-551. [17] Gadenne C,Barrozo R B,Anton S.2016.Plasticity in insect olfaction:To smell or not to smell?[J].Annual Review Entomology,61:317-333. [18] Gorman K,Devine G,Bennison J,et al.2007.Report of resistance to the neonicotinoid insecticide imidacloprid inTrialeurodes vaporariorum(Hemiptera:Aleyrodidae)[J].Pest Management Science,63(6):555-558. [19] Haas B,Papanicolaou A,Yassour M,et al.2013.De novo transcript sequence reconstruction from RNA-Seq using the Trinity platform for reference generation and analysis[J].Nature Protocol,8(8):1494-1512. [20] He M,He P.2014.Molecular characterization,expression profiling,and binding properties of odorant binding protein genes in the whitebacked planthopper,Sogatella furcifera[J].Comparative Biochemistry and Physiology Part B,Biochemistry Molecular Biology,174:1-8. [21] Hekmat-Scafe D S,Scafe C R,McKinney A J,et al.2002.Genome-wide analysis of the odorant-binding protein gene family inDrosophila melanogaster[J].Genome Research,12(9):1357-1369. [22] Hu P,Wang J,Cui M,et al.2016.Antennal transcriptome analysis of the Asian longhorned beetleAnoplophora glabripennis[J].Scientific Reports,6:26652. [23] Jones D.2003.Plant viruses transmitted by whiteflies[J].European Journal of Plant Pathology,109(3):195-219. [24] Kevin G,Ian D,Ritika C,et al.2011.Pyrosequencing the transcriptome of the greenhouse whitefly,Trialeurodes vaporariorumreveals multiple transcripts encoding insecticide targets and detoxifying enzymes[J].BMC Genomics,12(1):56. [25] Leal W.2012.Odorant reception in insects:Roles of receptors,binding proteins,and degrading enzymes[J].Annual Review Entomology,58:373-391. [26] Li G,Du J,Li Y,et al.2015.Identification of putative olfactory genes from the oriental fruit mothGrapholita molestavia an antennal transcriptome analysis[J].PLOS ONE,10:e0142193. [27] Li W,Godzik A.2006.Cd-hit:A fast program for clustering and comparing large sets of protein or nucleotide sequences[J].Bioinformatics,22(13):1658-1659. [28] Liu S,Rao X J,Li MY,et al.2015.Identification of candidate chemosensory genes in the antennal transcriptome ofTenebrio molitor(Coleoptera:Tenebrionidae)[J].Comparative Biochemistry and Physiology Part D,Genomics Proteomics,13:44-51. [29] Pelosi P,Iovinella I,Felicioli A,et al.2014.Soluble proteins of chemical communication:An overview across arthropods[J].Frontiers in Physiology,5:320. [30] Simao F A,Waterhouse R M,Ioannidis P,et al.2015.BUSCO:Assessing genome assembly and annotation completeness with single-copy orthologs[J].Bioinformatics,31(19):3210-3212. [31] Smadja C,Shi P,Butlin R K,et al.2009.Large gene family expansions and adaptive evolution for odorant and gustatory receptors in the pea aphid,Acyrthosiphon pisum[J].Molecular Biology Evolution,26(9):2073-2086. [32] Tamura K,Stecher G,Peterson D,et al.2013.MEGA6:Molecular evolutionary genetics analysis version 6.0[J].Molecular Biology Evolution,30(12):2725-2729. [33] Theissinger K,Falckenhayn C,Blande D,et al.2016.De Novo assembly and annotation of the freshwater crayfishAstacus astacustranscriptome[J].Marine Genomics,28:7-10. [34] Wang J,Hu P,Gao P,et al.2017.Antennal transcriptome analysis and expression profiles of olfactory genes inAnoplophora chinensis[J].Scientific Reports,7:15470. [35] Wang X W,Luan J B,Li J M,et al.2010.De novo characterization of a whitefly transcriptome and analysis of its gene expression during development[J].BMC Genomics,11:400. [36] Wang Y,Xiao D,Wang R,et al.2016.Deep sequencing-based transcriptome analysis reveals the regulatory mechanism ofBemisia tabaci(Hemiptera:Aleyrodidae) nymph parasitized byEncarsia sophia(Hymenoptera:Aphelinidae)[J].PLOS ONE,11(6):e0157684. [37] Wu Z Z,Qu M Q,Pu X H,et al.2017.Transcriptome sequencing ofTessaratoma papillosaantennae to identify and analyze expression patterns of putative olfaction genes[J].Scientific Reports,7:3070. [38] Xiao Y,Sun L,Ma X Y,et al.2017.Identification and characterization of the distinct expression profiles of candidate chemosensory membrane proteins in the antennal transcriptome ofAdelphocoris lineolatus(Goeze)[J].Insect Molecular Biology,26(1):74-91. [39] Zeng Y,Yang Y T,Wu Q J,et al.2019.Genome-wide analysis of odorant-binding proteins and chemosensory proteins in the sweet potato whitefly,Bemisia tabaci[J].Insect Science,26(4):620-634. [40] Zhang L W,Kang K,Jiang S C,et al.2016.Analysis of the antennal transcriptome and insights into olfactory genes inHyphantria cunea(Drury)[J].PLOS ONE,11:e0164729. [41] Zhang S,Pang B,Zhang L.2015.Novel odorant-binding proteins and their expression patterns in grasshopper,Oedaleus asiaticus[J].Biochemical and Biophysical Research Communications,460(2):274-280. [42] Zhang S,Zhang Z,Wang H,et al.2014.Antennal transcriptome analysis and comparison of olfactory genes in two sympatric defoliators,Dendrolimus houiandDendrolimus kikuchii(Lepidoptera:Lasiocampidae)[J].Insect Biochemistry and Molecular Biology,52:69-81. [43] Zhou J J,He X L,Pickett J A,et al.2008.Identification of odorant-binding proteins of the yellow fever mosquitoAedes aegypti:Genome annotation and comparative analyses[J].Insect Molecular Biology,17(2):147-163. [44] Zhou S S,Sun Z,Ma W,et al.2014.De novo analysis of theNilaparvata lugens(Stal) antenna transcriptome and expression patterns of olfactory genes[J].Comparative Biochemistry and Physiology Part D,Genomics Proteomics,9:31-39.
