Transcriptome-wide responses of adult melon thrips (Thrips palmi) associated with capsicum chlorosis virus infection

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Publicado en:	PLoS One vol. 13, no. 12 (Dec 2018), p. e0208538
Autor principal:	Shirani M K Widana Gamage
Otros Autores:	Rotenberg, Dorith, Schneweis, Derek J, Chi-Wei, Tsai, Ralf G Dietzgen ⨯
Publicado:	Public Library of Science
Materias:	National Taiwan University University of Queensland St Lucia Queensland Australia United States > US Taiwan Australia Infections Digestion Vitellogenin Chlorosis Cell walls Genes Biological effects Gangrene Tomatoes Tropical environments Viruses Genomics Insects Crop damage Molecular interactions Immune response Lipids Proteins Disease transmission Salivary gland Exposure Genetic engineering Adults Gene expression Plant pathology Wilt Structure-function relationships Salivary glands Ribonucleic acid > RNA Immune system Conservation Innate immunity Melanization Thrips palmi Tospoviridae Environmental
Acceso en línea:	Citation/Abstract Full Text Full Text - PDF
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001	2151746907
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022			\|a 1932-6203
024	7		\|a 10.1371/journal.pone.0208538 \|2 doi
035			\|a 2151746907
045	2		\|b d20181201 \|b d20181231
084			\|a 174835 \|2 nlm
100	1		\|a Shirani M K Widana Gamage
245	1		\|a Transcriptome-wide responses of adult melon thrips (Thrips palmi) associated with capsicum chlorosis virus infection
260			\|b Public Library of Science \|c Dec 2018
513			\|a Journal Article
520	3		\|a Thrips palmi is a widely distributed major agricultural pest in the tropics and subtropics, causing significant losses in cucurbit and solanaceous crops through feeding damage and transmission of tospoviruses. Thrips palmi is a vector of capsicum chlorosis virus (CaCV) in Australia. The present understanding of transmission biology and potential effects of CaCV on T. palmi is limited. To gain insights into molecular responses to CaCV infection, we performed RNA-Seq to identify thrips transcripts that are differentially-abundant during virus infection of adults. De-novo assembly of the transcriptome generated from whole bodies of T. palmi adults generated 166,445 contigs, of which ~24% contained a predicted open reading frame. We identified 1,389 differentially-expressed (DE) transcripts, with comparable numbers up- (708) and down-regulated (681) in virus-exposed thrips compared to non-exposed thrips. Approximately 59% of these DE transcripts had significant matches to NCBI non-redundant proteins (Blastx) and Blast2GO identified provisional functional categories among the up-regulated transcripts in virus-exposed thrips including innate immune response-related genes, salivary gland and/or gut-associated genes and vitellogenin genes. The majority of the immune-related proteins are known to serve functions in lysosome activity and melanisation in insects. Most of the up-regulated oral and extra-oral digestion-associated genes appear to be involved in digestion of proteins, lipids and plant cell wall components which may indirectly enhance the likelihood or frequency of virus transmission or may be involved in the regulation of host defence responses. Most of the down-regulated transcripts fell into the gene ontology functional category of ‘structural constituent of cuticle’. Comparison to DE genes responsive to tomato spotted wilt virus in Frankliniella occidentalis indicates conservation of some thrips molecular responses to infection by different tospoviruses. This study assembled the first transcriptome in the genus Thrips and provides important data to broaden our understanding of networks of molecular interactions between thrips and tospoviruses.
610		4	\|a National Taiwan University University of Queensland
651		4	\|a St Lucia
651		4	\|a Queensland Australia
651		4	\|a United States--US
651		4	\|a Taiwan
651		4	\|a Australia
653			\|a Infections
653			\|a Digestion
653			\|a Vitellogenin
653			\|a Chlorosis
653			\|a Cell walls
653			\|a Genes
653			\|a Biological effects
653			\|a Gangrene
653			\|a Tomatoes
653			\|a Tropical environments
653			\|a Viruses
653			\|a Genomics
653			\|a Insects
653			\|a Crop damage
653			\|a Molecular interactions
653			\|a Immune response
653			\|a Lipids
653			\|a Proteins
653			\|a Disease transmission
653			\|a Salivary gland
653			\|a Exposure
653			\|a Genetic engineering
653			\|a Adults
653			\|a Gene expression
653			\|a Plant pathology
653			\|a Wilt
653			\|a Structure-function relationships
653			\|a Salivary glands
653			\|a Ribonucleic acid--RNA
653			\|a Immune system
653			\|a Conservation
653			\|a Innate immunity
653			\|a Melanization
653			\|a Thrips palmi
653			\|a Tospoviridae
653			\|a Environmental
700	1		\|a Rotenberg, Dorith
700	1		\|a Schneweis, Derek J
700	1		\|a Chi-Wei, Tsai
700	1		\|a Ralf G Dietzgen ⨯
773	0		\|t PLoS One \|g vol. 13, no. 12 (Dec 2018), p. e0208538
786	0		\|d ProQuest \|t Health & Medical Collection
856	4	1	\|3 Citation/Abstract \|u https://www.proquest.com/docview/2151746907/abstract/embedded/160PP4OP4BJVV2EV?source=fedsrch
856	4	0	\|3 Full Text \|u https://www.proquest.com/docview/2151746907/fulltext/embedded/160PP4OP4BJVV2EV?source=fedsrch
856	4	0	\|3 Full Text - PDF \|u https://www.proquest.com/docview/2151746907/fulltextPDF/embedded/160PP4OP4BJVV2EV?source=fedsrch