0000000000202319

AUTHOR

Gloria Navarro-cerrillo

showing 5 related works from this author

A new gene superfamily of pathogen-response (repat) genes in Lepidoptera: Classification and expression analysis

2012

Repat (REsponse to PAThogens) genes were first identified in the midgut of Spodoptera exigua (Lepidoptera: Noctuidae) in response to Bacillus thuringiensis and baculovirus exposure. Since then, additional repat gene homologs have been identified in different studies. In this study the comprehensive larval transcriptome from S. exigua was analyzed for the presence of novel repat-homolog sequences. These analyses revealed the presence of at least 46 repat genes in S. exigua, establishing a new gene superfamily in this species. Phylogenetic analysis and studies of conserved motifs in these hypothetical proteins have allowed their classification in two main classes, αREPAT and βREPAT. Studies o…

PhysiologyBacillus thuringiensisGenes InsectSpodopteradigestive systemBiochemistryTranscriptomeHemolysin ProteinsBacterial ProteinsBacillus thuringiensisGene expressionExiguaAnimalsMolecular BiologyGeneGeneticsBacillus thuringiensis ToxinsbiologyGene Expression ProfilingStem CellsfungiMidgutbiology.organism_classificationMolecular biologyEndotoxinsIntestinesLepidopteraGene expression profilingLarvaMetagenomeComparative Biochemistry and Physiology Part B: Biochemistry and Molecular Biology
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Functional interactions between members of the REPAT family of insect pathogen-induced proteins

2012

Studies on the transcriptional response to pathogens in the insect larval gut have shown the regulation of several genes after the infection. Repat (REsponse to PAThogens) genes were first identified in Spodoptera exigua midgut as being up-regulated in response to the exposure to Bacillus thuringiensis toxins and baculovirus. Recently, new members of the REPAT family showed a constitutive up-regulation in a B. thuringiensis-resistant population. Based on a yeast two-hybrid screening, we have detected the interaction of REPAT1 with other members of the REPAT family, leading to the discovery of a new member: REPAT8. The functional role of this interaction was shown by following the changes of…

education.field_of_studybiologyPopulationMidgutSpodopteraSubcellular localizationbiology.organism_classificationmedicine.disease_causeMicrobiologyInsect ScienceBacillus thuringiensisGeneticsmedicineeducationMolecular BiologyGenePathogenEscherichia coliInsect Molecular Biology
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Constitutive Activation of the Midgut Response to Bacillus thuringiensis in Bt-Resistant Spodoptera exigua

2010

Bacillus thuringiensis is the most effective microbial control agent for controlling numerous species from different insect orders. The main threat for the long term use of B. thuringiensis in pest control is the ability of insects to develop resistance. Thus, the identification of insect genes involved in conferring resistance is of paramount importance. A colony of Spodoptera exigua (Lepidoptera: Noctuidae) was selected for 15 years in the laboratory for resistance to Xentari (TM), a B. thuringiensis-based insecticide, reaching a final resistance level of greater than 1,000-fold. Around 600 midgut ESTs were analyzed by DNA-macroarray in order to find differences in midgut gene expression …

0106 biological sciencesDrug Resistancelcsh:MedicineGene ExpressionInsectaminopeptidase n01 natural sciencesAminopeptidasesHemolysin ProteinsEndotoxinmanduca-sextaBacillus thuringiensisInsect ProteinBiotechnology/Applied Microbiologylcsh:Scienceheliothis-virescensmedia_common0303 health sciencesLarvaMultidisciplinarybiologymediated insect resistanceGenetics and Genomics/Gene ExpressionEcology/Population Ecologybacterial-infectionNoctuidaeInsect ProteinsResearch Articlemedia_common.quotation_subjectAminopeptidaseMolecular Sequence DataBacillus thuringiensisBacterial ProteinSpodopteraSpodopterastem-cell proliferationMicrobiology03 medical and health sciencesMicrobiology/Applied MicrobiologyBacterial ProteinsExiguaBotanyBacillus thuringiensiAnimalscrystal proteinsBIOS Plant Development SystemsAmino Acid Sequencekinase pathways030304 developmental biologyposterior midgutHeliothis virescensBacillus thuringiensis ToxinsAnimaltrichoplusia-nilcsh:RfungiMidgutHemolysin Proteinbiology.organism_classificationEndotoxinsGastrointestinal Tract010602 entomologyPlant Biology/Agricultural Biotechnologylcsh:QSequence Alignment
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Increase in midgut microbiota load induces an apparent immune priming and increases tolerance to Bacillus thuringiensis

2010

Summary The insect immune system is comprised of both humoral and cellular components that are mobilized in response to parasitic or pathogenic infections. Activation of the immune response implies a consid- erable expenditure of energy and that is why insects rely on inducible pathways that are activated after coming into contact with the pathogenic agent. Known as immune priming, insects can prolong the activation of the immune response and transmit their immune status to the next generation. Starting from a laboratory colony of the lepidopteran Spodoptera exigua and using the lytic zone assay as a measure of the immune status, we selected for a sub-colony with high levels of immune activ…

animal diseasesmedia_common.quotation_subjectfungiPriming (immunology)chemical and pharmacologic phenomenaMidgutInsectbiochemical phenomena metabolism and nutritionBiologySpodopterabiology.organism_classificationMicrobiologyMicrobiologyImmune systemLytic cycleBacillus thuringiensisBotanybacteriaEcology Evolution Behavior and SystematicsBacteriamedia_commonEnvironmental Microbiology
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ABCC transporters mediate insect resistance to multiple Bt toxins revealed by bulk segregant analysis

2014

[EN] Background: Relatively recent evidence indicates that ABCC2 transporters play a main role in the mode of action of Bacillus thuringiensis (Bt) Cry1A-type proteins. Mapping of major Cry1A resistance genes has linked resistance to the ABCC2 locus in Heliothis virescens, Plutella xylostella, Trichoplusia ni and Bombyx mori, and mutations in this gene have been found in three of these Bt-resistant strains. Results: We have used a colony of Spodoptera exigua (Xen-R) highly resistant to a Bt commercial bioinsecticide to identify regions in the S. exigua genome containing loci for major resistance genes by using bulk segregant analysis (BSA). Results reveal a region containing three genes fro…

MalePhysiologyGenes InsectPlant ScienceBt resistanceInsecticide ResistanceHemolysin ProteinsStructural BiologyBacillus thuringiensisChromosome SegregationPhylogenyGeneticsbiologyAgricultural and Biological Sciences(all)LarvaFemaleGeneral Agricultural and Biological SciencesBiotechnologyResearch ArticleMolecular Sequence DataBacillus thuringiensisSpodopteraSpodopteraABCC2 transporterPolymorphism Single NucleotideGeneral Biochemistry Genetics and Molecular BiologyBacterial ProteinsExiguaAnimalsAmino Acid SequenceGeneEcology Evolution Behavior and SystematicsCrosses GeneticBombyxBacillus thuringiensis ToxinsBiochemistry Genetics and Molecular Biology(all)Gene Expression ProfilingfungiWild typeCell BiologySequence Analysis DNAbiology.organism_classificationBombyxMolecular biologyEndotoxinsKineticsGENETICACry1AcMembrane proteinATP-Binding Cassette TransportersCry toxinsDevelopmental Biology
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