2023
Development of an amplicon-based sequencing approach in response to the global emergence of mpox
Chen N, Chaguza C, Gagne L, Doucette M, Smole S, Buzby E, Hall J, Ash S, Harrington R, Cofsky S, Clancy S, Kapsak C, Sevinsky J, Libuit K, Park D, Hemarajata P, Garrigues J, Green N, Sierra-Patev S, Carpenter-Azevedo K, Huard R, Pearson C, Incekara K, Nishimura C, Huang J, Gagnon E, Reever E, Razeq J, Muyombwe A, Borges V, Ferreira R, Sobral D, Duarte S, Santos D, Vieira L, Gomes J, Aquino C, Savino I, Felton K, Bajwa M, Hayward N, Miller H, Naumann A, Allman R, Greer N, Fall A, Mostafa H, McHugh M, Maloney D, Dewar R, Kenicer J, Parker A, Mathers K, Wild J, Cotton S, Templeton K, Churchwell G, Lee P, Pedrosa M, McGruder B, Schmedes S, Plumb M, Wang X, Barcellos R, Godinho F, Salvato R, Ceniseros A, Breban M, Grubaugh N, Gallagher G, Vogels C. Development of an amplicon-based sequencing approach in response to the global emergence of mpox. PLOS Biology 2023, 21: e3002151. PMID: 37310918, PMCID: PMC10263305, DOI: 10.1371/journal.pbio.3002151.Peer-Reviewed Original ResearchConceptsPublic health laboratoriesHealth laboratoriesSevere acute respiratory syndrome coronavirus 2Acute respiratory syndrome coronavirus 2Monkeypox virusRespiratory syndrome coronavirus 2Ongoing coronavirus disease 2019 (COVID-19) pandemicAnatomical body sitesAtypical clinical presentationCoronavirus disease 2019 (COVID-19) pandemicSyndrome coronavirus 2Course of infectionDisease 2019 pandemicRapid outbreak responseWhole-genome sequencingHuman monkeypox virusCT valuesClinical presentationViral loadCoronavirus 2Viral DNA concentrationsPathogen whole-genome sequencingZika virusClinical specimensBody sitesGenomic and phenotypic analyses suggest moderate fitness differences among Zika virus lineages
Oliveira G, Vogels C, Zolfaghari A, Saraf S, Klitting R, Weger-Lucarelli J, P Leon K, Ontiveros C, Agarwal R, Tsetsarkin K, Harris E, Ebel G, Wohl S, Grubaugh N, Andersen K. Genomic and phenotypic analyses suggest moderate fitness differences among Zika virus lineages. PLOS Neglected Tropical Diseases 2023, 17: e0011055. PMID: 36753510, PMCID: PMC9907835, DOI: 10.1371/journal.pntd.0011055.Peer-Reviewed Original ResearchMeSH KeywordsAedesAnimalsEvolution, MolecularGenomicsHumansMosquito VectorsZika VirusZika Virus InfectionConceptsHuman primary cellsFitness differencesVirus lineagesRapid molecular evolutionPrimary cellsShort generation timeAmino acid sitesFitness changesHigh mutation ratePhenotypic evolutionMolecular evolutionPositive selectionMutation rateLineagesPhenotypic analysisPhenotypic changesRNA virusesGeneration timeRecombinant virusesAedes aegypti mosquitoesReplicative fitnessFitnessAegypti mosquitoesMosquitoesZika virus
2020
Forced Zika Virus Infection of Culex pipiens Leads to Limited Virus Accumulation in Mosquito Saliva
Abbo SR, Vogels CBF, Visser TM, Geertsema C, van Oers MM, Koenraadt CJM, Pijlman GP. Forced Zika Virus Infection of Culex pipiens Leads to Limited Virus Accumulation in Mosquito Saliva. Viruses 2020, 12: 659. PMID: 32575394, PMCID: PMC7354520, DOI: 10.3390/v12060659.Peer-Reviewed Original ResearchConceptsZika virusGuillain-Barré syndromeZika virus infectionInfectious blood mealUrban transmission cyclesMosquito-borne pathogenMosquito salivaZIKV transmissionOral exposureVirus infectionCongenital microcephalySevere diseaseIntrathoracic injectionLarge outbreakVirus disseminationUsutu virusMidgut barrierBarrier functionMosquito midgutVirus transmissionSalivaBlood mealYellow fever mosquitoVector competenceVirusThe invasive Asian bush mosquito Aedes japonicus found in the Netherlands can experimentally transmit Zika virus and Usutu virus
Abbo SR, Visser TM, Wang H, Göertz GP, Fros JJ, Abma-Henkens MHC, Geertsema C, Vogels CBF, Koopmans MPG, Reusken CBEM, Hall-Mendelin S, Hall RA, van Oers MM, Koenraadt CJM, Pijlman GP. The invasive Asian bush mosquito Aedes japonicus found in the Netherlands can experimentally transmit Zika virus and Usutu virus. PLOS Neglected Tropical Diseases 2020, 14: e0008217. PMID: 32282830, PMCID: PMC7153878, DOI: 10.1371/journal.pntd.0008217.Peer-Reviewed Original ResearchMeSH KeywordsAedesAnimalsFemaleFlavivirusFlavivirus InfectionsHumansMicrocephalyMosquito VectorsNetherlandsSalivaTemperatureZika VirusZika Virus InfectionConceptsZika virusUsutu virusFed mosquitoesMidgut barrierMosquito midgut barrierGuillain-Barré syndromeInfectious blood mealSevere neurological impairmentSevere congenital microcephalyField-collected AeWest Nile virusClinical manifestationsMild diseaseUSUV infectionNeurological impairmentCongenital microcephalyRNA responseVirus disseminationArboviral diseasesNile virusVirus transmissionDroplet feedingVirusFemale mosquitoesBlood meal
2019
Subgenomic flavivirus RNA binds the mosquito DEAD/H-box helicase ME31B and determines Zika virus transmission by Aedes aegypti
Göertz GP, van Bree JWM, Hiralal A, Fernhout BM, Steffens C, Boeren S, Visser TM, Vogels CBF, Abbo SR, Fros JJ, Koenraadt CJM, van Oers MM, Pijlman GP. Subgenomic flavivirus RNA binds the mosquito DEAD/H-box helicase ME31B and determines Zika virus transmission by Aedes aegypti. Proceedings Of The National Academy Of Sciences Of The United States Of America 2019, 116: 19136-19144. PMID: 31488709, PMCID: PMC6754610, DOI: 10.1073/pnas.1905617116.Peer-Reviewed Original ResearchConceptsSubgenomic flavivirus RNAInfectious blood mealZika virusMosquito infectionWild-type Zika virusesFlavivirus RNAMosquito midgut barrierArthropod-borne flavivirusZika virus transmissionBlood mealGlobal human health threatMosquito cell culturesZIKV infectionMosquito salivaIntrathoracic injectionViral Small Interfering RNAsInfected mosquitoesViral titersAntiviral activityFlavivirus replicationFlavivirus transmissionMidgut barrierHealth threatInfectionInfected cellsTravel Surveillance and Genomics Uncover a Hidden Zika Outbreak during the Waning Epidemic
Grubaugh ND, Saraf S, Gangavarapu K, Watts A, Tan AL, Oidtman RJ, Ladner JT, Oliveira G, Matteson NL, Kraemer MUG, Vogels CBF, Hentoff A, Bhatia D, Stanek D, Scott B, Landis V, Stryker I, Cone MR, Kopp EW, Cannons AC, Heberlein-Larson L, White S, Gillis LD, Ricciardi MJ, Kwal J, Lichtenberger PK, Magnani DM, Watkins DI, Palacios G, Hamer DH, Network G, Gardner LM, Perkins TA, Baele G, Khan K, Morrison A, Isern S, Michael SF, Andersen KG. Travel Surveillance and Genomics Uncover a Hidden Zika Outbreak during the Waning Epidemic. Cell 2019, 178: 1057-1071.e11. PMID: 31442400, PMCID: PMC6716374, DOI: 10.1016/j.cell.2019.07.018.Peer-Reviewed Original ResearchMeSH KeywordsAedesAnimalsCubaEpidemicsGenomicsHumansIncidenceMosquito ControlPhylogenyRNA, ViralSequence Analysis, RNATravelWest IndiesZika VirusZika Virus InfectionArbovirus coinfection and co-transmission: A neglected public health concern?
Vogels CBF, Rückert C, Cavany SM, Perkins TA, Ebel GD, Grubaugh ND. Arbovirus coinfection and co-transmission: A neglected public health concern? PLOS Biology 2019, 17: e3000130. PMID: 30668574, PMCID: PMC6358106, DOI: 10.1371/journal.pbio.3000130.Peer-Reviewed Original ResearchConceptsImpact of coinfectionPublic health concernPublic healthEpidemiological synergyVirus coinfectionAedes aegypti mosquitoesClinical diseaseSuch coinfectionsZika virusCoinfectionOutbreaks of virusesHealth concernAegypti mosquitoesMultiple virusesTransmission dynamicsVirusHealthHumansMosquitoesDiseaseDengue
2017
Mosquito co-infection with Zika and chikungunya virus allows simultaneous transmission without affecting vector competence of Aedes aegypti
Göertz GP, Vogels CBF, Geertsema C, Koenraadt CJM, Pijlman GP. Mosquito co-infection with Zika and chikungunya virus allows simultaneous transmission without affecting vector competence of Aedes aegypti. PLOS Neglected Tropical Diseases 2017, 11: e0005654. PMID: 28570693, PMCID: PMC5469501, DOI: 10.1371/journal.pntd.0005654.Peer-Reviewed Original ResearchConceptsChikungunya virusZika virusAegypti mosquitoesIntrathoracic injectionPresence of ZIKVVector competenceInfectious blood mealSerious health burdenDual-color immunofluorescenceBlood mealMultiple mosquito bitesArthropod-borne virusZIKV productionSalivary gland barrierCase reportAedes aegypti mosquitoesHealth burdenOral exposureMosquito bitesViral titersPositive mosquitoesMosquito cellsBiteProfound barrierVirus
2016
Noncoding Subgenomic Flavivirus RNA Is Processed by the Mosquito RNA Interference Machinery and Determines West Nile Virus Transmission by Culex pipiens Mosquitoes
Göertz GP, Fros JJ, Miesen P, Vogels CB, van der Bent ML, Geertsema C, Koenraadt CJ, van Rij RP, van Oers MM, Pijlman GP. Noncoding Subgenomic Flavivirus RNA Is Processed by the Mosquito RNA Interference Machinery and Determines West Nile Virus Transmission by Culex pipiens Mosquitoes. Journal Of Virology 2016, 90: 10145-10159. PMID: 27581979, PMCID: PMC5105652, DOI: 10.1128/jvi.00930-16.Peer-Reviewed Original ResearchConceptsSubgenomic flavivirus RNARNA interference machineryCulex pipiens mosquitoesWest Nile virusInterference machinerySfRNA productionPipiens mosquitoesBiological functionsUntranslated regionNile virusPivotal biological functionsIntrathoracic injectionWild-type WNVRNA deep sequencingKey biological functionsBlood mealFlavivirus RNAMosquito cell linesFlavivirus West Nile virusViral genomic RNAMosquito midgut barrierMutant West Nile virusTick-borne flavivirusesWNV-infected mosquitoesMammalian cells