2024
Contribution of climate change to the spatial expansion of West Nile virus in Europe
Erazo D, Grant L, Ghisbain G, Marini G, Colón-González F, Wint W, Rizzoli A, Van Bortel W, Vogels C, Grubaugh N, Mengel M, Frieler K, Thiery W, Dellicour S. Contribution of climate change to the spatial expansion of West Nile virus in Europe. Nature Communications 2024, 15: 1196. PMID: 38331945, PMCID: PMC10853512, DOI: 10.1038/s41467-024-45290-3.Peer-Reviewed Original ResearchConceptsWest Nile virusEcological niche modelsExpansion of West Nile virusClimate changeWNV circulationNiche modelsNile virusMosquito-borne pathogensEffects of climate changeHuman population changeSpatial expansionContributions of climate changeWest Nile virus circulationEnvironmental changesPublic health threatHuman populationLand-useHuman influencePotential driversRisk of exposureLong-term trendsPopulation densityPopulation changeHealth threatClimate
2019
Endless Forms: Within-Host Variation in the Structure of the West Nile Virus RNA Genome during Serial Passage in Bird Hosts
Scroggs SLP, Grubaugh ND, Sena JA, Sundararajan A, Schilkey FD, Smith DR, Ebel GD, Hanley KA. Endless Forms: Within-Host Variation in the Structure of the West Nile Virus RNA Genome during Serial Passage in Bird Hosts. MSphere 2019, 4: 10.1128/msphere.00291-19. PMID: 31243074, PMCID: PMC6595145, DOI: 10.1128/msphere.00291-19.Peer-Reviewed Original ResearchConceptsUntranslated regionSecondary structureBird speciesRNA genomeGenome cyclizationRNA virusesHost variationPrimary genomic sequenceWest Nile virusPrimary genome sequenceDS regionStructural diversityIntrahost genetic diversityVirus phenotypeComplex secondary structureVirus RNA genomeRNA secondary structureSerial passageSmall RNAsGenetic diversityNile virusGenome sequenceMutant lineagesGenomic sequencesNext-generation sequencing
2017
Mosquitoes Transmit Unique West Nile Virus Populations during Each Feeding Episode
Grubaugh ND, Fauver JR, Rückert C, Weger-Lucarelli J, Garcia-Luna S, Murrieta RA, Gendernalik A, Smith DR, Brackney DE, Ebel GD. Mosquitoes Transmit Unique West Nile Virus Populations during Each Feeding Episode. Cell Reports 2017, 19: 709-718. PMID: 28445723, PMCID: PMC5465957, DOI: 10.1016/j.celrep.2017.03.076.Peer-Reviewed Original ResearchConceptsGenetic diversityNovel virus variantsWNV genetic diversityMost genetic diversityComplex evolutionary forcesVirus populationsEvolutionary forcesWest Nile virusGenetic driftInfection phenotypesWNV variantsIndividual mosquitoesIntrahost variantsVirus variantsTransmission cyclePopulation levelMosquitoesDiversityContinuous threatNile virusVariantsArthropodsChikungunya virusVirusLarge epidemics
2016
Genetic Drift during Systemic Arbovirus Infection of Mosquito Vectors Leads to Decreased Relative Fitness during Host Switching
Grubaugh ND, Weger-Lucarelli J, Murrieta RA, Fauver JR, Garcia-Luna SM, Prasad AN, Black WC, Ebel GD. Genetic Drift during Systemic Arbovirus Infection of Mosquito Vectors Leads to Decreased Relative Fitness during Host Switching. Cell Host & Microbe 2016, 19: 481-492. PMID: 27049584, PMCID: PMC4833525, DOI: 10.1016/j.chom.2016.03.002.Peer-Reviewed Original ResearchConceptsRelative fitnessMosquito speciesLower relative fitnessWest Nile virusComplex virus populationsSignificant fitness costMosquito-borne RNA virusesHost switchingGenetic driftGenetic diversityAdaptive potentialPopulation expansionFitness costsAvian cellsDeleterious mutationsMutational diversityRNA virusesBridge vectorsViral populationsVirus populationsMosquito vectorsFitnessSpeciesDiversityNile virus