Wing patterning genes of Nilaparvata lugens identification by transcriptome analysis, and their differential expression profile in wing pads between brachypterous and macropterous morphs

doi:10.1016/S2095-3119(14)60948-5

Journal of Integrative Agriculture ›› 2015, Vol. 14 ›› Issue (9): 1796-1807.DOI: 10.1016/S2095-3119(14)60948-5

Wing patterning genes of Nilaparvata lugens identification by transcriptome analysis, and their differential expression profile in wing pads between brachypterous and macropterous morphs

LI Kai-yin, HU Ding-bang, LIU Fang-zhou, LONG Man, LIU Si-yi, ZHAO Jing, HE Yue-ping

Hubei Insect Resources Utilization and Sustainable Pest Management Key Laboratory, College of Plant Science and Technology, Huazhong Agricultural University, Wuhan 430070, P.R.China

收稿日期:2014-11-14 出版日期:2015-09-03 发布日期:2015-09-05
通讯作者: HUA Hong-xia,E-mail: huahongxia@mail.hzau.edu.cn
作者简介:LI Kai-yin, E-mail: 970777174@qq.com; HU Ding-bang,E-mail: hudingb@163.com;* These authors contributed equally to this study.
基金资助:
This work was supported by the National Natural Science Foundation of China (31171846).

Wing patterning genes of Nilaparvata lugens identification by transcriptome analysis, and their differential expression profile in wing pads between brachypterous and macropterous morphs

LI Kai-yin, HU Ding-bang, LIU Fang-zhou, LONG Man, LIU Si-yi, ZHAO Jing, HE Yue-ping

Hubei Insect Resources Utilization and Sustainable Pest Management Key Laboratory, College of Plant Science and Technology, Huazhong Agricultural University, Wuhan 430070, P.R.China

Received:2014-11-14 Online:2015-09-03 Published:2015-09-05
Contact: HUA Hong-xia,E-mail: huahongxia@mail.hzau.edu.cn
About author:LI Kai-yin, E-mail: 970777174@qq.com; HU Ding-bang,E-mail: hudingb@163.com;* These authors contributed equally to this study.
Supported by:
This work was supported by the National Natural Science Foundation of China (31171846).

摘要/Abstract

摘要： The brown planthopper, Nilaparvata lugens is an economically important pest on rice plants. This species produces macropterous and brachypterous morphs in response to environmental cues, which makes it very difficult to control. The molecular basis of wing patterning in N. lugens is still unknown. It is necessary to identify wing patterning genes of N. lugens, and also to clarify the expression differences of wing patterning genes between macropterous and brachypterous morphs. High-throughput deep sequencing of transcriptome of N. lugens wing pad yielded 116 744 580 raw reads and 113 042 700 clean reads. All the reads were assembled into 55 963 unigenes with an average length of 804 bp. With the E-value cut-off of 1.0E–5,18 359 and 2 883 unigens had hits in NCBI-NR (NCBI non-redundant protein sequences) and NCBI-NT (NCBI nucleotide sequences) databases, respectively. A total of 16 502 unigenes were assigned to GO (gene ontology) classification, 9 709 ungenes were grouped into 26 COG (cluster of orthologous groups of proteins) classifications, and 6 724 unigenes were assigned to different KEGG (Kyoto encyclopedia of genes and genomes) pathways. In total, 56 unigenes which are homologous to wing patterning genes of Drosophila melanogaster or Tribolium castaneum were identified. Out of the 56 unigenes, 24 unigenes were selected, and their expression levels across the five nymphal stages between macropterous strain and brachypterous strain were examined by qRT-PCR. Two-way ANOVA analysis showed that development stage had significant effects on the expression level of all the 24 genes (P<0.05). The expression levels of 8 genes (Nlen, Nlhh, Nlsal, NlAbd-A, Nlwg, Nlvg, Nlexd and NlUbx) were significantly affected by wing morph. This is the first transcriptome analysis of wing pads of hemimetabolous insect, N. lugens. The identified wing patterning genes would be useful resource for future exploration of molecular basis of wing development. The 8 differentially expressed wing patterning genes between macropterous strain and brachypterous strain would contribute to explain molecular mechanism of wing-morph differentiation in N. lugens.

关键词: Nilaparvata lugens , wing pad , transcriptome , wing patterning genes

Abstract: The brown planthopper, Nilaparvata lugens is an economically important pest on rice plants. This species produces macropterous and brachypterous morphs in response to environmental cues, which makes it very difficult to control. The molecular basis of wing patterning in N. lugens is still unknown. It is necessary to identify wing patterning genes of N. lugens, and also to clarify the expression differences of wing patterning genes between macropterous and brachypterous morphs. High-throughput deep sequencing of transcriptome of N. lugens wing pad yielded 116 744 580 raw reads and 113 042 700 clean reads. All the reads were assembled into 55 963 unigenes with an average length of 804 bp. With the E-value cut-off of 1.0E–5,18 359 and 2 883 unigens had hits in NCBI-NR (NCBI non-redundant protein sequences) and NCBI-NT (NCBI nucleotide sequences) databases, respectively. A total of 16 502 unigenes were assigned to GO (gene ontology) classification, 9 709 ungenes were grouped into 26 COG (cluster of orthologous groups of proteins) classifications, and 6 724 unigenes were assigned to different KEGG (Kyoto encyclopedia of genes and genomes) pathways. In total, 56 unigenes which are homologous to wing patterning genes of Drosophila melanogaster or Tribolium castaneum were identified. Out of the 56 unigenes, 24 unigenes were selected, and their expression levels across the five nymphal stages between macropterous strain and brachypterous strain were examined by qRT-PCR. Two-way ANOVA analysis showed that development stage had significant effects on the expression level of all the 24 genes (P<0.05). The expression levels of 8 genes (Nlen, Nlhh, Nlsal, NlAbd-A, Nlwg, Nlvg, Nlexd and NlUbx) were significantly affected by wing morph. This is the first transcriptome analysis of wing pads of hemimetabolous insect, N. lugens. The identified wing patterning genes would be useful resource for future exploration of molecular basis of wing development. The 8 differentially expressed wing patterning genes between macropterous strain and brachypterous strain would contribute to explain molecular mechanism of wing-morph differentiation in N. lugens.

Key words: Nilaparvata lugens , wing pad , transcriptome , wing patterning genes

LI Kai-yin, HU Ding-bang, LIU Fang-zhou, LONG Man, LIU Si-yi, ZHAO Jing, HE Yue-ping. Wing patterning genes of Nilaparvata lugens identification by transcriptome analysis, and their differential expression profile in wing pads between brachypterous and macropterous morphs[J]. Journal of Integrative Agriculture, 2015, 14(9): 1796-1807.

参考文献

Abouheif E, Wray G A. 2002. Evolution of the gene networkunderlying wing polyphenism in ants. Science, 297,249-252

Aspland S E, White R. 1997. Nucleocytoplasmic localisationof extradenticle protein is spatially regulated throughoutdevelopment in Drosophila. Development, 124, 741-747

Azpiazu N, Morata G. 2000. Function and regulation ofhomothorax in the wing imaginal disc of Drosophila.Development, 127, 2685-2693

Basler K, Struhl G. 1994. Compartment boundaries and thecontrol of Drosophila limb pattern by Hedgehog protein.Nature, 368, 208-214

Bertuso A G, Morooka S, Tojo S. 2002. Sensitive periods forwing development and precocious metamorphosis afterprecocene treatment of the brown planthopper, Nilaparvatalugens. Journal of Insect Physiology, 48, 221-229

Brisson J A, Ishikawa A, Miura T. 2010. Wing developmentgenes of the pea aphid and differential gene expressionbetween winged and unwinged morphs. Insect MolecularBiology, 19, 63-73

Campbell G, Tomlinson A. 1998. The roles of the homeoboxgenes aristaless and Distal-less in patterning the legs andwings of Drosophila. Development, 125, 4483-4493

Campbell G, Tomlinson A. 1999. Transducing the Dppmorphogen gradient in the wing of Drosophila: Regulationof Dpp targets by brinker. Cell, 96, 553-562

Campbell G, Weaver T, Tomlinson A. 1993. Axis specification inthe developing Drosophila appendage: The role of wingless,decapentaplegic, and the homeobox gene aristaless. Cell,74, 1113-1123

Carroll S B, Weatherbee S D, Langeland J A. 1995. Homeoticgenes and the regulation and evolution of insect wingnumber. Nature, 375, 58-61

Casares F, Calleja M, Sánchez-Herrero E. 1996. Functionalsimilarity in appendage specification by the Ultrabithoraxand abdominal-A Drosophila HOX genes. The EMBOJournal, 15, 3934-3942

Casares F, Mann R S. 2000. A dual role for homothoraxin inhibiting wing blade development and specifyingproximal wing identities in Drosophila. Development, 127,1499-1508

de Celis J F, Llimargas M, Casanova J. 1995. Ventralveinless, the gene encoding the Cf1a transcription factor,links positional information and cell differentiation duringembryonic and imaginal development in Drosophilamelanogaster. Development, 121, 3405-3416

Cheng X N, Chen R C, Xi X, Yang L M, Zhu Z L, Wu J C, QianR G, Yang J S. 1979. Studies on the migrations of brownplanthoppers, Nilaparvata lugens Stål. Acta EntomologicaSinica, 22, 1-21 (in Chinese)

Cohen B, McGuffin M E, Pfeifle C, Segal D, Cohen S M. 1992.apterous, a gene required for imaginal disc developmentin Drosophila encodes a member of the LIM family ofdevelopmental regulatory proteins. Genes & Development,6, 715-729

Couso J P, Bate M, Martínez-Arias A. 1993. A wingless dependent polar coordinate system in Drosophila imaginaldiscs. Science, 259, 484-489

Deng H, Zhang J, Li Y, Zheng S, Liu L, Huang L, Xu W H,Palli S R, Feng Q. 2012. Homeodomain POU and Abd-Aproteins regulate the transcription of pupal genes duringmetamorphosis of the silkworm, Bombyx mori. Proceedingsof the National Academy of Sciences of the United Statesof America, 109, 12598-12603

Doumpas N, Jékely G, Teleman A A. 2013. Wnt6 is requiredfor maxillary palp formation in Drosophila. BMC Biology,11, 104.

Götz S, García-Gómez J M, Terol J, Williams T D, NagarajS H, Nueda M J, Robles M, Talón M, Dopazo J, ConesaA. 2008. High-throughput functional annotation and datamining with the Blast2GO suite. Nucleic Acids Research,36, 3420-3435

Grabherr M G, Haas B J, Yassour M, Levin J Z, Thompson DA, Amit I, Adiconis X, Fan L, Raychowdhury R, Zeng Q,Chen Z, Mauceli E, Hacohen N, Gnirke A, Rhind N, di PalmaF, Birren B W, Nusbaum C, Lindblad-Toh K, FriedmanN, Regev A. 2011. Full-length transcriptome assemblyfrom RNA-Seq data without a reference genome. NatureBiotechnology, 29, 644-652

Grimm S, Pflugfelder G O. 1996. Control of the gene optomotorblindin Drosophila wing development by decapentaplegicand wingless. Science, 271, 1601-1604.

Gu S H, Wu K M, Guo Y Y, Pickett J A, Field L M, Zhou J J,Zhang Y J. 2013. Identification of genes expressed in thesex pheromone gland of the black cutworm Agrotis ipsilonwith putative roles in sex pheromone biosynthesis andtransport. BMC Genomics, 14, 636.

Halder G, Polaczyk P, Kraus M E, Hudson A, Kim J, LaughonA, Carroll S. 1998. The Vestigial and Scalloped proteins acttogether to directly regulate wing-specific gene expressionin Drosophila. Genes & Development, 12, 3900-3909

Iseli C, Jongeneel C V, Bucher P. 1999. ESTScan: A programfor detecting, evaluating, and reconstructing potential codingregions in EST sequences. Proceedings of InternationalConference on Intelligent Systems for Molecular Biology,7, 138-148

Johnson R L, Grenier J K, Scott M P. 1995. Patchedoverexpression alters wing disc size and pattern:Transcriptional and post-transcriptional effects on hedgehogtargets. Development, 121, 4161-4170

Kim E, Niethammer M, Rothschild A, Jan Y N, Sheng M. 1995.Clustering of Shaker-type K+ channels by interaction with afamily of membrane-associated guanylate kinases. Nature,378, 85-88

Kukalová-Peck J. 1983. Origin of the insect wing and wingarticulation from the arthropodan leg. Canadian Journal ofZoology, 61, 1618-1669

Livak K G, Schmittgen T D. 2001. Analysis of relative geneexpression data using real-time quantitative PCR and the2−ΔΔCT method. Methods, 25, 402-408

Lunde K, Biehs B, Nauber U, Bier E. 1998. The knirps andknirps-related genes organize development of the secondwing vein in Drosophila. Development, 125, 4145-4154

Morooka S, Tojo S. 1992. Maintenance and selection of strainsexhibiting specific wing form and body colour under highdensity conditions in the brown planthopper, nilaparvatalugens (Homoptera: Delphacidae). Japanese Society ofApplied Entomology and Zoology, 27, 445-454.Motzny C K, Holmgren R. 1995. The Drosophila cubitusinterruptus protein and its role in the wingless and hedgehogsignal transduction pathways. Mechanisms of Development,52, 137-150

Neumann C J, Cohen S M. 1996. A hierarchy of cross-regulationinvolving Notch, wingless, vestigial and cut organizes thedorsal/ventral axis of the Drosophila wing. Development,122, 3477-3485

Ng M, Diaz-Benjumea F J, Cohen S M. 1995. Nubbin encodes aPOU-domain protein required for proximal-distal patterningin the Drosophila wing. Development, 121, 589-599

Panganiban G., Rubenstein J L R. 2002. Developmentalfunctions of the Distal-less/Dlx homeobox genes.Development, 129, 4371-4386

Pavlopoulos A, Akam M. 2011. Hox gene Ultrabithoraxregulates distinct sets of target genes at successive stagesof Drosophila haltere morphogenesis. Proceedings of theNational Academy of Sciences of the United States ofAmerica, 108, 2855-2860

Posakony L G, Raftery L A, Gelbart W M. 1990. Wing formationin Drosophila melanogaster requires decapentaplegic genefunction along the anterior-posterior compartment boundary.Mechanisms of Development, 33, 69-82

Rogers B T, Peterson M D, Kaufman T C. 1997. Evolution ofthe insect body plan as revealed by the Sex combs reducedexpression pattern. Development, 124, 149-157

Skeath J B, Carroll S B. 1991. Regulation of achaete-scutegene expression and sensory organ pattern formation inthe Drosophila wing. Genes & Development, 5, 984-995

Snodgrass R E. 1935. Principles of Insect Morphology. McGraw-Hill, New York.

Soanes K H, MacKay J O, Core N, Heslip T, Kerridge S, BellJ B. 2001. Identification of a regulatory allele of teashirt(tsh) in Drosophila melanogaster that affects wing hingedevelopment. An adult-specific tsh enhancer in Drosophila.Mechanisms of Development, 105, 145-151

Sturtevant M A, Biehs B, Marin E, Bier E. 1997. The spaltgene links the A/P compartment boundary to a linear adultstructure in the Drosophila wing. Development, 124, 21-32

Syobu S, Mikuriya H, Yamaguchi J, Matsuzaki M, MatsumuraM. 2002. Fluctuations and factors affecting the wing-formratio of the brown planthopper, Nilaparvata lugens Stål inrice fields. Japanese Journal of Applied Entomology andZoology, 46, 135-143

Tabata T, Eaton S, Kornberg T B. 1992. The Drosophilahedgehog gene is expressed specifically in posteriorcompartment cells and is a target of engrailed regulation.Genes & Development, 6, 2635-2645

Tabata T, Kornbert T B. 1994. Hedgehog is a signaling proteinwith a key role in patterning Drosophila imaginal discs.Cell, 76, 89-102

Tomoyasu Y, Wheeler S R, Denell R E. 2005. Ultrabithoraxis required for membranous wing identity in the beetleTribolium castaneum. Nature, 433, 643-647

Torres A F, Huang C, Chong C M, Leung S W, Prieto-da-SilvaA R, Havt A, Quinet Y P, Martins A M, Lee S M, Rádis-Baptista G. 2014. Transcriptome analysis in venom glandof the predatory giant ant Dinoponera quadriceps: insightsinto the polypeptide toxin arsenal of hymenopterans. PLOSONE, 9, e87556.Tribolium Genome Sequencing Consortium. 2008. The genomeof the model beetle and pest Tribolium castaneum. Nature,452, 949-955

Tsuneizumi K, Nakayama T, Kamoshida Y, Kornberg T B,Christian J L, Tabata T. 1997. Daughters against dppmodulates dpp organizing activity in Drosophila wingdevelopment. Nature, 389, 627-631

Villa-Cuesta E, González-Pérez E, Modolell J. 2007. Appositionof iroquois expressing and non-expressing cells leads to cellsorting and fold formation in the Drosophila imaginal wingdisc. BMC Developmental Biology, 7, 106.Weatherbee S D, Halder G, Kim J, Hudson A, Carroll S. 1998.Ultrabithorax regulates genes at several levels of thewing-patterning hierarchy to shape the development of theDrosophila haltere. Genes & Development, 12, 1474-1482

Wigglesworth V B. 1973. Evolution of insect wings and flight.Nature, 246, 127-129

Williams J, Bell J, Carroll S. 1991. Control of Drosophila wingand haltere development by the nuclear vestigial geneproduct. Genes & Development, 5, 2481-2495

Wu G R, Yu X P, Tao L Y. 1997. Long-term forecast on theoutbreak of brown planthopper (Nilaparvata lugens Stål)and white-backed planthopper (Sogatella furcifera Horvath).Agricultural Sciences in China, 30, 25-29

Wu J, Cohen S M. 1999. Proximodistal axis formation inthe Drosophila leg: Subdivision into proximal and distaldomains by Homothorax and Distal-less. Development,126, 109-117

Ye J, Fang L, Zheng H K, Zhang Y, Chen J, Zhang Z J, WangJ, Li S T, Li R Q, Bolund L, Wang J. 2006. WEGO: A webtool for plotting GO annotations. Nucleic Acids Research,34, W293-W297.Zhou S S, Sun Z, Ma W, Chen W, Wang M Q. 2014. Denovo analysis of the Nilaparvata lugens (Stål) antennatranscriptome and expression patterns of olfactory genes.Comparative Biochemistry and Physiology (Part D:Genomics & Proteomics), 9, 31–39.

[1]	CHEN Tai-yu, HOU Ji-xiang, LIN Yong-jun. Transcriptome datasets supply basic gene information for RNAi pest management and gene functional studies in Nephotettix cincticeps (Uhler)[J]. Journal of Integrative Agriculture, 2016, 15(4): 840-847.
[2]	ZHANG Jiao, XING Yan-ru, HOU Bo-feng, YUAN Zhu-ting, LI Yao, JIE Wen-cai, SUN Yang, LI Fei. Amplification and function analysis of N6-adenine-specific DNA methyltransferase gene in Nilaparvata lugens[J]. Journal of Integrative Agriculture, 2016, 15(3): 591-599.
[3]	ZOU Xi-ling, ZENG Liu, LU Guang-yuan, CHENG Yong, XU Jin-song, ZHANG Xue-kun. Comparison of transcriptomes undergoing waterlogging at the seedling stage between tolerant and sensitive varieties of Brassica napus L.[J]. Journal of Integrative Agriculture, 2015, 14(9): 1723-1734.
[4]	XU Wei-hua, LI Zi-cong, OUYANG Zhi-ping, YU Bo, SHI Jun-song, LIU De-wu, WU Zhen-fang. RNA-Seq transcriptome analysis of porcine cloned and in vitro fertilized blastocysts[J]. Journal of Integrative Agriculture, 2015, 14(5): 926-938.
[5]	SHI Bao-kun, HUANG Jian-li, HU Chao-xing , HOU Mao-lin. Interactive Effects of Elevated CO2 and Temperature on Rice Planthopper, Nilaparvata lugens[J]. Journal of Integrative Agriculture, 2014, 13(7): 1520-1529.
[6]	SHI Zhao-peng, DU Shang-gen, YANG Guo-qing, LU Zhen-zhen , WU Jin-cai. Effects of Pesticide Applications on the Biochemical Properties of Transgenic cry 2A Rice and the Life History Parameters of Nilaparvata lugens Stål (Homptera: Delphacidae)[J]. Journal of Integrative Agriculture, 2013, 12(9): 1606-1613.
[7]	Owain Rhys Edwards , Alexie Papanicolaou. A Roadmap for Whitefly Genomics Research: Lessons from Previous Insect Genome Projects[J]. Journal of Integrative Agriculture, 2012, 11(2): 269-280.
[8]	Susan Seal, Mitulkumar V Patel, Carl Collins, John Colvin , David Bailey. Next Generation Transcriptome Sequencing and Quantitative Real-Time PCR Technologies for Characterisation of the Bemisia tabaci Asia 1 mtCOI Phylogenetic Clade[J]. Journal of Integrative Agriculture, 2012, 11(2): 281-292.

Wing patterning genes of Nilaparvata lugens identification by transcriptome analysis, and their differential expression profile in wing pads between brachypterous and macropterous morphs

Wing patterning genes of Nilaparvata lugens identification by transcriptome analysis, and their differential expression profile in wing pads between brachypterous and macropterous morphs

PDF

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 8

编辑推荐

Metrics