0000000000585553

AUTHOR

Rosa Fernández

showing 6 related works from this author

The era of reference genomes in conservation genomics

2022

Progress in genome sequencing now enables the large-scale generation of reference genomes. Various international initiatives aim to generate reference genomes representing global biodiversity. These genomes provide unique insights into genomic diversity and architecture, thereby enabling comprehensive analyses of population and functional genomics, and are expected to revolutionize conservation genomics.

QH301 Biology580 Plants (Botany)Genetics -- ResearchEvolutionsbiologibiodiversity conservation; conservation genetics; ERGA; European Reference Genome AtlasConservation genetics; Biodiversity conservation; European Reference Genome Atlas; ERGAAnimal genome mappingudc:630*1GenomeGEERGA[SDV.BID.EVO]Life Sciences [q-bio]/Biodiversity/Populations and Evolution [q-bio.PE][SDE.BE.BIOD]Environmental Sciences/Biodiversity and Ecology/domain_sde.be.biodERGA ; Biodiversity [MeSH] ; Genomics [MeSH] ; Ecology Evolution Behavior and Systematics ; conservation genetics ; Genome [MeSH] ; biodiversity conservation ; European Reference Genome Atlas3rd-DASGenomicsBiodiversityreferenčni genomi[SDV.BIBS]Life Sciences [q-bio]/Quantitative Methods [q-bio.QM][SDE.BE.BEC]Environmental Sciences/Biodiversity and Ecology/domain_sde.be.becChemistry10121 Department of Systematic and Evolutionary BotanygenomikaGE Environmental Sciences:Informàtica::Aplicacions de la informàtica::Bioinformàtica [Àrees temàtiques de la UPC]biodiverzitetaSettore BIO/18 - GENETICAeducationQH426 GeneticsQH301European Reference Genome AtlasVDP::Matematikk og Naturvitenskap: 400::Basale biofag: 470[SDE.BE.EVO]Environmental Sciences/Biodiversity and Ecology/domain_sde.be.evoGeneticsconservation genetics ; biodiversity conservation ; European Reference Genome Atlas ; ERGAgenomi10211 Zurich-Basel Plant Science CenterGenomesGenetikBiologyQH426Ecology Evolution Behavior and SystematicsEvolutionary BiologyBiodiversity conservation; Conservation genetics; European Reference Genome AtlasAmbientaleEcologíaGenética1105 Ecology Evolution Behavior and Systematicsconservation geneticsWildlife conservation570 Life sciences; biologyHuman medicinebiodiversity conservationAnimal genetics[SDE.BE]Environmental Sciences/Biodiversity and EcologyGenètica
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The genome sequence of the grape phylloxera provides insights into the evolution, adaptation, and invasion routes of an iconic pest

2020

Background: Although native to North America, the invasion of the aphid-like grape phylloxera Daktulosphaira vitifoliae across the globe altered the course of grape cultivation. For the past 150 years, viticulture relied on grafting-resistant North American Vitis species as rootstocks, thereby limiting genetic stocks tolerant to other stressors such as pathogens and climate change. Limited understanding of the insect genetics resulted in successive outbreaks across the globe when rootstocks failed. Here we report the 294-Mb genome of D. vitifoliae as a basic tool to understand host plant manipulation, nutritional endosymbiosis, and enhance global viticulture. Results: Using a combination of…

0106 biological sciencesFil·loxeraPhysiology[SDV]Life Sciences [q-bio]Introduced speciesPlant Science01 natural sciencesGenomeGene duplicationsStructural BiologyVitislcsh:QH301-705.5ComputingMilieux_MISCELLANEOUS2. Zero hunger0303 health scienceseducation.field_of_studyHost plant interactionsGenomeEndosymbiosisbiologyfood and beveragesBiological SciencesBiological EvolutionGeneral Agricultural and Biological SciencesRootstockInfectionDaktulosphaira vitifoliaeBiotechnologyResearch ArticlePopulation010603 evolutionary biologyGeneral Biochemistry Genetics and Molecular BiologyHemiptera03 medical and health sciencesGeneticsInsect pestsAnimalsPlagues d'insectesAdaptationBiological invasionsGenomeseducationPhylloxeraEcology Evolution Behavior and Systematics030304 developmental biologyObligateHuman GenomeViticulturaCell Biology15. Life on landbiology.organism_classificationBiologicalEffectorsClimate Actionlcsh:Biology (General)13. Climate actionEvolutionary biologyArthropod genomesPhylloxeraAdaptationIntroduced SpeciesInsectAnimal DistributionDevelopmental Biology
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Diversity, evolution, and function of myriapod hemocyanins.

2018

Background Hemocyanin transports O2 in the hemolymph of many arthropod species. Such respiratory proteins have long been considered unnecessary in Myriapoda. As a result, the presence of hemocyanin in Myriapoda has long been overlooked. We analyzed transcriptome and genome sequences from all major myriapod taxa – Chilopoda, Diplopoda, Symphyla, and Pauropoda – with the aim of identifying hemocyanin-like proteins. Results We investigated the genomes and transcriptomes of 56 myriapod species and identified 46 novel full-length hemocyanin subunit sequences in 20 species of Chilopoda, Diplopoda, and Symphyla, but not Pauropoda. We found in Cleidogona sp. (Diplopoda, Chordeumatida) a hemocyanin-…

0301 basic medicineArthropodaEvolutionmedicine.medical_treatmentMyriapodaZoologychemical and pharmacologic phenomenacomplex mixturesHemocyaninPauropodaEvolution Molecular03 medical and health sciencesHemolymphmedicineQH359-425AnimalsAmino Acid SequenceRNA MessengerArthropodsEcology Evolution Behavior and SystematicsPhylogenyBinding SitesbiologyBase SequenceMonophenol MonooxygenaseMyriapodaGenetic VariationHemocyaninhemic and immune systemsbiology.organism_classificationRespiratory proteinOxygenProtein Subunits030104 developmental biologyHemocyaninsPhenoloxidaseSubunit diversityArthropodSymphylaCentipedeCopperResearch ArticleBMC evolutionary biology
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Global data on earthworm abundance, biomass, diversity and corresponding environmental properties

2021

Earthworms are an important soil taxon as ecosystem engineers, providing a variety of crucial ecosystem functions and services. Little is known about their diversity and distribution at large spatial scales, despite the availability of considerable amounts of local-scale data. Earthworm diversity data, obtained from the primary literature or provided directly by authors, were collated with information on site locations, including coordinates, habitat cover, and soil properties. Datasets were required, at a minimum, to include abundance or biomass of earthworms at a site. Where possible, site-level species lists were included, as well as the abundance and biomass of individual species and ec…

Data DescriptorDistribuição GeográficaPlan_S-Compliant-OASoilBiomassbiodiversityDiversityEcologyBiodiversidadeQBiodiversityeliöyhteisötmaaperäeliöstöPE&RCComputer Science ApplicationsMultidisciplinary SciencesBiogeographyinternational1181 Ecology evolutionary biologyEcosystem engineersScience & Technology - Other TopicsStatistics Probability and UncertaintyInformation SystemsStatistics and ProbabilitylierotScienceInvertebradosLibrary and Information Sciences[SDV.SA.SDS]Life Sciences [q-bio]/Agricultural sciences/Soil studyEcology and EnvironmentEducationeliömaantiede[SDV.EE.ECO]Life Sciences [q-bio]/Ecology environment/EcosystemsMinhocaServiço ambientalBIODIVERSITY CHANGELife ScienceEcosystem servicesEarthwormsDatasetsAnimalsSpatial distributionCommunity ecologyOligochaetaLaboratorium voor NematologieEcosystem1172 Environmental sciencesbiogeographyScience & TechnologyLAND-USEBiology and Life SciencesPLATFORMBodemfysica en LandbeheerEcologíaEcossistemabiodiversiteettiSoil Physics and Land ManagementSoloBiologia do Solomaaperäeläimistö570 Life sciences; biologyeartworm ; abundance ; biomass ; diversityLaboratory of Nematology[SDE.BE]Environmental Sciences/Biodiversity and EcologyCOMMUNITIEScommunity ecology
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Additional file 1 of The genome sequence of the grape phylloxera provides insights into the evolution, adaptation, and invasion routes of an iconic p…

2020

Additional file 1: Figures. S1-S22, Table S1-S20, Methods and Results. Figure S1. Mitochondrial genome view of grape phylloxera. Figure S2. Proportion of transposable elements (TE) in the genome. Figure S3. GO terms of phylloxera-specific genes. Figure S4. Enriched GO terms in the phylloxera genome with and without TEs. Figure S5. Gene gain/loss at different nodes or branches. Figure S6. Species phylogenetic tree based on insect genomes and the transcriptomes of Planoccoccus citri and Adelges tsugae. Figure S7. Diagram of the gap-filling and annotation process. Figure S8. Urea cycle in D. vitifoliae and A. pisum. Figure S9. IMD immune pathway in D. vitifoliae.Figure S10. Phylogenetic tree o…

2. Zero hunger
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Additional file 1 of The genome sequence of the grape phylloxera provides insights into the evolution, adaptation, and invasion routes of an iconic p…

2020

Additional file 1: Figures. S1-S22, Table S1-S20, Methods and Results. Figure S1. Mitochondrial genome view of grape phylloxera. Figure S2. Proportion of transposable elements (TE) in the genome. Figure S3. GO terms of phylloxera-specific genes. Figure S4. Enriched GO terms in the phylloxera genome with and without TEs. Figure S5. Gene gain/loss at different nodes or branches. Figure S6. Species phylogenetic tree based on insect genomes and the transcriptomes of Planoccoccus citri and Adelges tsugae. Figure S7. Diagram of the gap-filling and annotation process. Figure S8. Urea cycle in D. vitifoliae and A. pisum. Figure S9. IMD immune pathway in D. vitifoliae.Figure S10. Phylogenetic tree o…

2. Zero hunger
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