2024
Intranasal neomycin evokes broad-spectrum antiviral immunity in the upper respiratory tract
Mao T, Kim J, Peña-Hernández M, Valle G, Moriyama M, Luyten S, Ott I, Gomez-Calvo M, Gehlhausen J, Baker E, Israelow B, Slade M, Sharma L, Liu W, Ryu C, Korde A, Lee C, Monteiro V, Lucas C, Dong H, Yang Y, Initiative Y, Gopinath S, Wilen C, Palm N, Dela Cruz C, Iwasaki A, Vogels C, Hahn A, Chen N, Breban M, Koch T, Chaguza C, Tikhonova I, Castaldi C, Mane S, De Kumar B, Ferguson D, Kerantzas N, Peaper D, Landry M, Schulz W, Grubaugh N. Intranasal neomycin evokes broad-spectrum antiviral immunity in the upper respiratory tract. Proceedings Of The National Academy Of Sciences Of The United States Of America 2024, 121: e2319566121. PMID: 38648490, PMCID: PMC11067057, DOI: 10.1073/pnas.2319566121.Peer-Reviewed Original ResearchConceptsInterferon-stimulated genesRespiratory infectionsStrains of influenza A virusTreatment of respiratory viral infectionsRespiratory virus infectionsInfluenza A virusMouse model of COVID-19Respiratory viral infectionsNeomycin treatmentExpression of interferon-stimulated genesUpper respiratory infectionInterferon-stimulated gene expressionLower respiratory infectionsBroad spectrum of diseasesAdministration of neomycinRespiratory viral diseasesDisease to patientsUpper respiratory tractIntranasal deliveryCongenic miceIntranasal applicationNasal mucosaSevere acute respiratory syndrome coronavirus 2Acute respiratory syndrome coronavirus 2A virus
2021
A humanized mouse model of chronic COVID-19
Sefik E, Israelow B, Mirza H, Zhao J, Qu R, Kaffe E, Song E, Halene S, Meffre E, Kluger Y, Nussenzweig M, Wilen CB, Iwasaki A, Flavell RA. A humanized mouse model of chronic COVID-19. Nature Biotechnology 2021, 40: 906-920. PMID: 34921308, PMCID: PMC9203605, DOI: 10.1038/s41587-021-01155-4.Peer-Reviewed Original ResearchConceptsChronic COVID-19Humanized mouse modelImmune responseMouse modelAcute respiratory syndrome coronavirus 2 infectionSevere acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infectionSyndrome coronavirus 2 infectionCOVID-19Adaptive human immune responsesInterferon-stimulated gene signaturePersistent viral RNACoronavirus 2 infectionPatient-derived antibodiesT-cell lymphopeniaHuman immune responseHyperactive immune responseCoronavirus disease 2019Inflammatory macrophage responseImmunological injuryLung pathologyCell lymphopeniaDisease 2019Severe diseaseRodent modelsInflammatory macrophagesA stem-loop RNA RIG-I agonist protects against acute and chronic SARS-CoV-2 infection in mice
Mao T, Israelow B, Lucas C, Vogels CBF, Gomez-Calvo ML, Fedorova O, Breban MI, Menasche BL, Dong H, Linehan M, Alpert T, Anderson F, Earnest R, Fauver J, Kalinich C, Munyenyembe K, Ott I, Petrone M, Rothman J, Watkins A, Wilen C, Landry M, Grubaugh N, Pyle A, Iwasaki A. A stem-loop RNA RIG-I agonist protects against acute and chronic SARS-CoV-2 infection in mice. Journal Of Experimental Medicine 2021, 219: e20211818. PMID: 34757384, PMCID: PMC8590200, DOI: 10.1084/jem.20211818.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntiviral AgentsCOVID-19COVID-19 Drug TreatmentDisease Models, AnimalImmunity, InnateInterferon Type IMiceMice, Inbred BALB CRNASARS-CoV-2ConceptsSARS-CoV-2 infectionChronic SARS-CoV-2 infectionVariants of concernLethal SARS-CoV-2 infectionPost-infection therapyLower respiratory tractPost-exposure treatmentType I interferonSARS-CoV-2Effective medical countermeasuresAdaptive immune systemBroad-spectrum antiviralsContext of infectionSingle doseRespiratory tractViral controlImmunodeficient miceSevere diseaseMouse modelI interferonViral infectionImmune systemInnate immunityDisease preventionConsiderable efficacyAdaptive immune determinants of viral clearance and protection in mouse models of SARS-CoV-2
Israelow B, Mao T, Klein J, Song E, Menasche B, Omer SB, Iwasaki A. Adaptive immune determinants of viral clearance and protection in mouse models of SARS-CoV-2. Science Immunology 2021, 6: eabl4509. PMID: 34623900, PMCID: PMC9047536, DOI: 10.1126/sciimmunol.abl4509.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsChlorocebus aethiopsCOVID-19COVID-19 VaccinesDisease Models, AnimalFemaleImmunity, CellularImmunity, HumoralMaleMiceMice, KnockoutSARS-CoV-2Vero CellsConceptsSARS-CoV-2Viral clearanceImmune determinantsMouse modelSevere acute respiratory syndrome coronavirus 2Acute respiratory syndrome coronavirus 2Respiratory syndrome coronavirus 2Cellular adaptive immunitySyndrome coronavirus 2Vivo protective capacityVariants of concernMRNA vaccinationHomologous infectionCellular immunityConvalescent miceCoronavirus 2Antibody responsePrimary infectionEffective vaccineAdaptive immunityConfer protectionInfectionNatural infectionProtective capacityClearanceDiverse functional autoantibodies in patients with COVID-19
Wang EY, Mao T, Klein J, Dai Y, Huck JD, Jaycox JR, Liu F, Zhou T, Israelow B, Wong P, Coppi A, Lucas C, Silva J, Oh JE, Song E, Perotti ES, Zheng NS, Fischer S, Campbell M, Fournier JB, Wyllie AL, Vogels CBF, Ott IM, Kalinich CC, Petrone ME, Watkins AE, Dela Cruz C, Farhadian S, Schulz W, Ma S, Grubaugh N, Ko A, Iwasaki A, Ring A. Diverse functional autoantibodies in patients with COVID-19. Nature 2021, 595: 283-288. PMID: 34010947, DOI: 10.1038/s41586-021-03631-y.Peer-Reviewed Original ResearchConceptsPeripheral immune cell compositionSARS-CoV-2 infectionCOVID-19Effects of autoantibodiesTissue-associated antigensSpecific clinical characteristicsInnate immune activationImmune cell compositionCOVID-19 exhibitCOVID-19 manifestsAnalysis of autoantibodiesSARS-CoV-2Functional autoantibodiesMouse surrogateClinical characteristicsVirological controlClinical outcomesImmune activationMild diseaseAsymptomatic infectionAutoantibody reactivityDisease progressionHealthcare workersHigh prevalenceAutoantibodiesNeuroinvasion of SARS-CoV-2 in human and mouse brain
Song E, Zhang C, Israelow B, Lu-Culligan A, Prado AV, Skriabine S, Lu P, Weizman OE, Liu F, Dai Y, Szigeti-Buck K, Yasumoto Y, Wang G, Castaldi C, Heltke J, Ng E, Wheeler J, Alfajaro MM, Levavasseur E, Fontes B, Ravindra NG, Van Dijk D, Mane S, Gunel M, Ring A, Kazmi SAJ, Zhang K, Wilen CB, Horvath TL, Plu I, Haik S, Thomas JL, Louvi A, Farhadian SF, Huttner A, Seilhean D, Renier N, Bilguvar K, Iwasaki A. Neuroinvasion of SARS-CoV-2 in human and mouse brain. Journal Of Experimental Medicine 2021, 218: e20202135. PMID: 33433624, PMCID: PMC7808299, DOI: 10.1084/jem.20202135.Peer-Reviewed Original ResearchMeSH KeywordsAngiotensin-Converting Enzyme 2AnimalsAntibodies, BlockingCerebral CortexCOVID-19Disease Models, AnimalFemaleHumansMaleMiceMiddle AgedNeuronsOrganoidsSARS-CoV-2ConceptsSARS-CoV-2Central nervous systemSARS-CoV-2 neuroinvasionImmune cell infiltratesCOVID-19 patientsType I interferon responseMultiple organ systemsCOVID-19I interferon responseHuman brain organoidsNeuroinvasive capacityCNS infectionsCell infiltrateNeuronal infectionPathological featuresCortical neuronsRespiratory diseaseDirect infectionCerebrospinal fluidNervous systemMouse brainInterferon responseOrgan systemsHuman ACE2Infection
2020
Mouse model of SARS-CoV-2 reveals inflammatory role of type I interferon signaling
Israelow B, Song E, Mao T, Lu P, Meir A, Liu F, Alfajaro MM, Wei J, Dong H, Homer RJ, Ring A, Wilen CB, Iwasaki A. Mouse model of SARS-CoV-2 reveals inflammatory role of type I interferon signaling. Journal Of Experimental Medicine 2020, 217: e20201241. PMID: 32750141, PMCID: PMC7401025, DOI: 10.1084/jem.20201241.Peer-Reviewed Original ResearchMeSH KeywordsAngiotensin-Converting Enzyme 2AnimalsBetacoronavirusCell Line, TumorCoronavirus InfectionsCOVID-19DependovirusDisease Models, AnimalFemaleHumansInflammationInterferon Type ILungMaleMiceMice, Inbred C57BLMice, TransgenicPandemicsParvoviridae InfectionsPeptidyl-Dipeptidase APneumonia, ViralSARS-CoV-2Signal TransductionVirus ReplicationConceptsSARS-CoV-2Type I interferonMouse modelI interferonRobust SARS-CoV-2 infectionSevere acute respiratory syndrome coronavirus 2Acute respiratory syndrome coronavirus 2SARS-CoV-2 infectionRespiratory syndrome coronavirus 2SARS-CoV-2 replicationCOVID-19 patientsSyndrome coronavirus 2Patient-derived virusesSignificant fatality ratePathological findingsInflammatory rolePathological responseEnzyme 2Receptor angiotensinFatality rateVaccine developmentGenetic backgroundViral replicationCoronavirus diseaseMicem6A Modification Prevents Formation of Endogenous Double-Stranded RNAs and Deleterious Innate Immune Responses during Hematopoietic Development
Gao Y, Vasic R, Song Y, Teng R, Liu C, Gbyli R, Biancon G, Nelakanti R, Lobben K, Kudo E, Liu W, Ardasheva A, Fu X, Wang X, Joshi P, Lee V, Dura B, Viero G, Iwasaki A, Fan R, Xiao A, Flavell RA, Li HB, Tebaldi T, Halene S. m6A Modification Prevents Formation of Endogenous Double-Stranded RNAs and Deleterious Innate Immune Responses during Hematopoietic Development. Immunity 2020, 52: 1007-1021.e8. PMID: 32497523, PMCID: PMC7408742, DOI: 10.1016/j.immuni.2020.05.003.Peer-Reviewed Original ResearchConceptsDouble-stranded RNADeleterious innate immune responseMammalian hematopoietic developmentEndogenous double-stranded RNAHematopoietic developmentInnate immune responseAbundant RNA modificationMurine fetal liverPattern recognition receptor pathwaysImmune responseProtein codingDsRNA formationRNA modificationsWriter METTL3Hematopoietic defectsPerinatal lethalityNative stateConditional deletionAberrant innate immune responsesLoss of METTL3Hematopoietic failureReceptor pathwayAberrant immune responsePrevents formationFetal liver
2019
Effector TH17 Cells Give Rise to Long-Lived TRM Cells that Are Essential for an Immediate Response against Bacterial Infection
Vesely M, Pallis P, Bielecki P, Low JS, Zhao J, Harman CCD, Kroehling L, Jackson R, Bailis W, Licona-Limón P, Xu H, Iijima N, Pillai PS, Kaplan DH, Weaver CT, Kluger Y, Kowalczyk MS, Iwasaki A, Pereira JP, Esplugues E, Gagliani N, Flavell RA. Effector TH17 Cells Give Rise to Long-Lived TRM Cells that Are Essential for an Immediate Response against Bacterial Infection. Cell 2019, 178: 1176-1188.e15. PMID: 31442406, PMCID: PMC7057720, DOI: 10.1016/j.cell.2019.07.032.Peer-Reviewed Original ResearchConceptsCD4 TTissue-resident memory T cellsBacterial infectionsResident memory T cellsFunction of airwayLife-long protectionEffector memory TMemory T cellsTh17 cellsTRM cellsΓδ TEffector cellsMemory TBacterial clearanceT cellsIL-7Adaptive immunityMouse modelMemory responsesVaccine designHost defenseLymphatic endothelial cellsDepletion studiesEndothelial cellsCellular originLow ambient humidity impairs barrier function and innate resistance against influenza infection
Kudo E, Song E, Yockey LJ, Rakib T, Wong PW, Homer RJ, Iwasaki A. Low ambient humidity impairs barrier function and innate resistance against influenza infection. Proceedings Of The National Academy Of Sciences Of The United States Of America 2019, 116: 10905-10910. PMID: 31085641, PMCID: PMC6561219, DOI: 10.1073/pnas.1902840116.Peer-Reviewed Original ResearchConceptsInfluenza infectionImpair barrier functionImpairs host defenseSeasonal influenza virusesInfluenza virus infectionLungs of miceImpairs mucociliary clearanceTissue repairInduction of IFNInnate antiviral defenseViral burdenMucociliary clearanceDisease outcomeRespiratory challengeVirus infectionSevere diseaseViral infectionCongenic miceHost responseViral transmissionHost defenseSingle-cell RNA sequencingInnate resistanceDisease pathologyInfluenza virusAedes aegypti AgBR1 antibodies modulate early Zika virus infection of mice
Uraki R, Hastings AK, Marin-Lopez A, Sumida T, Takahashi T, Grover JR, Iwasaki A, Hafler DA, Montgomery RR, Fikrig E. Aedes aegypti AgBR1 antibodies modulate early Zika virus infection of mice. Nature Microbiology 2019, 4: 948-955. PMID: 30858571, PMCID: PMC6533137, DOI: 10.1038/s41564-019-0385-x.Peer-Reviewed Original ResearchConceptsZika virus infectionVirus infectionZika virusAegypti salivary proteinsGuillain-Barre syndromeEarly inflammatory responseSkin of micePrevention of mosquitoInflammatory responseAedes aegypti mosquitoesTherapeutic measuresSalivary factorsSalivary proteinsMosquito-borneInfectionMiceSubstantial mortalityRecent epidemicProtein 1Aegypti mosquitoesAntigenic proteinsVirusAntibodiesMosquitoesAntiserum
2018
Topical application of aminoglycoside antibiotics enhances host resistance to viral infections in a microbiota-independent manner
Gopinath S, Kim MV, Rakib T, Wong PW, van Zandt M, Barry NA, Kaisho T, Goodman AL, Iwasaki A. Topical application of aminoglycoside antibiotics enhances host resistance to viral infections in a microbiota-independent manner. Nature Microbiology 2018, 3: 611-621. PMID: 29632368, PMCID: PMC5918160, DOI: 10.1038/s41564-018-0138-2.Peer-Reviewed Original ResearchMeSH KeywordsAdministration, TopicalAminoglycosidesAnimalsAnti-Bacterial AgentsDisease Models, AnimalGene Expression ProfilingGene Expression RegulationGerm-Free LifeHumansInfluenza A virusMiceMicrobiotaOligonucleotide Array Sequence AnalysisSimplexvirusToll-Like Receptor 3Transcription FactorsVirus DiseasesVirus ReplicationZika VirusConceptsToll-like receptor 3Aminoglycoside treatmentInterferon-stimulated genesViral infectionReceptor 3ISG inductionAminoglycoside antibioticsMicrobiota-independent mannerGerm-free miceAdapter-inducing interferonInterferon regulatory factor 3Herpes simplex virusTopical mucosal applicationRegulatory factor 3Dendritic cellsAntibiotic useAntiviral effectAminoglycoside applicationHost resistanceSimplex virusAntiviral resistanceVaginal mucosaMarked upregulationMucosal applicationTopical applicationType I interferons instigate fetal demise after Zika virus infection
Yockey LJ, Jurado KA, Arora N, Millet A, Rakib T, Milano KM, Hastings AK, Fikrig E, Kong Y, Horvath TL, Weatherbee S, Kliman HJ, Coyne CB, Iwasaki A. Type I interferons instigate fetal demise after Zika virus infection. Science Immunology 2018, 3 PMID: 29305462, PMCID: PMC6049088, DOI: 10.1126/sciimmunol.aao1680.Peer-Reviewed Original ResearchConceptsZika virus infectionZIKV infectionI IFNsI interferonType I interferonGrowth restrictionFetal demiseVirus infectionSevere fetal growth restrictionType I IFNsChorionic villous explantsAdverse fetal outcomesCongenital viral infectionFetal growth restrictionMaternal-fetal barrierType IFunctional type IPlacental damageFetal outcomesPregnancy complicationsEarly pregnancyFetal resorptionZIKV diseasePregnant damsSpontaneous abortion
2017
Antiviral CD8 T cells induce Zika-virus-associated paralysis in mice
Jurado KA, Yockey LJ, Wong PW, Lee S, Huttner AJ, Iwasaki A. Antiviral CD8 T cells induce Zika-virus-associated paralysis in mice. Nature Microbiology 2017, 3: 141-147. PMID: 29158604, PMCID: PMC5780207, DOI: 10.1038/s41564-017-0060-z.Peer-Reviewed Original ResearchConceptsCentral nervous systemZIKV infectionZika virusT cellsNeurological complicationsNervous systemBlood-brain barrier breakdownAntiviral CD8 T cellsHigh viral burdenIFNAR knockout miceCD8 T cellsEffector T cellsSusceptible mouse modelBlood-brain barrierNon-haematopoietic cellsSite of infectionIFNAR1 deficiencyViral burdenNeurological manifestationsGuillain-BarréBarrier breakdownMouse modelKnockout miceAstrocytes resultsAntiviral activityFetal Growth Restriction Caused by Sexual Transmission of Zika Virus in Mice
Uraki R, Jurado KA, Hwang J, Szigeti-Buck K, Horvath TL, Iwasaki A, Fikrig E. Fetal Growth Restriction Caused by Sexual Transmission of Zika Virus in Mice. The Journal Of Infectious Diseases 2017, 215: 1720-1724. PMID: 28472297, PMCID: PMC5853330, DOI: 10.1093/infdis/jix204.Peer-Reviewed Original ResearchConceptsZika virusSexual transmissionWeight of fetusesFetal growth restrictionNaive female miceType I interferon receptorEmbryonic day 18.5Female miceGrowth restrictionMale miceOcular deformityMosquito bitesControl groupDay 18.5Fetal abnormalitiesSexual contactInterferon receptorMiceFetusesInfected malesVirusDeformityAbnormalitiesReceptors
2016
Vaginal Exposure to Zika Virus during Pregnancy Leads to Fetal Brain Infection
Yockey LJ, Varela L, Rakib T, Khoury-Hanold W, Fink SL, Stutz B, Szigeti-Buck K, Van den Pol A, Lindenbach BD, Horvath TL, Iwasaki A. Vaginal Exposure to Zika Virus during Pregnancy Leads to Fetal Brain Infection. Cell 2016, 166: 1247-1256.e4. PMID: 27565347, PMCID: PMC5006689, DOI: 10.1016/j.cell.2016.08.004.Peer-Reviewed Original ResearchMeSH KeywordsAbortion, HabitualAnimalsBrainBrain DiseasesDisease Models, AnimalFemaleFetal Growth RetardationInterferon Regulatory Factor-3MiceMice, Inbred C57BLMice, Mutant StrainsPregnancyPregnancy Complications, InfectiousReceptor, Interferon alpha-betaVaginaVirus ReplicationZika VirusZika Virus InfectionConceptsZika virusFetal brain infectionFetal growth restrictionLocal viral replicationWild-type miceType I interferon receptorZIKV challengeTranscription factor IRF3Vaginal exposureGenital mucosaBrain infectionWT miceEarly pregnancyZIKV infectionGrowth restrictionPregnant damsVaginal infectionsZIKV replicationFetal brainMouse modelIFN pathwayVaginal tractUnborn fetusViral replicationDisease consequencesAXL receptor tyrosine kinase is required for T cell priming and antiviral immunity
Schmid ET, Pang IK, Silva E, Bosurgi L, Miner JJ, Diamond MS, Iwasaki A, Rothlin CV. AXL receptor tyrosine kinase is required for T cell priming and antiviral immunity. ELife 2016, 5: e12414. PMID: 27350258, PMCID: PMC4924996, DOI: 10.7554/elife.12414.Peer-Reviewed Original ResearchConceptsType I IFNsI IFNsI interferonDendritic cellsIL-1βAntiviral T cell immunityAntiviral adaptive immunityPotent immunosuppressive functionT cell immunityT cell primingInhibition of AXLType I IFN receptorAxl receptor tyrosine kinaseReceptor tyrosine kinase AXLControl of infectionType I interferonI IFN receptorTyrosine kinase AXLDC maturationCell immunityWest Nile virusCell primingImmunosuppressive functionImmunosuppressive effectsAdaptive immunityCD301b+ Macrophages Are Essential for Effective Skin Wound Healing
Shook B, Xiao E, Kumamoto Y, Iwasaki A, Horsley V. CD301b+ Macrophages Are Essential for Effective Skin Wound Healing. Journal Of Investigative Dermatology 2016, 136: 1885-1891. PMID: 27287183, PMCID: PMC5727894, DOI: 10.1016/j.jid.2016.05.107.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsDisease Models, AnimalFluorescent Antibody TechniqueLectins, C-TypeMacrophagesMaleMiceMice, Inbred C57BLSensitivity and SpecificitySkinWound HealingConceptsSkin wound healingBarrier functionEssential inflammatory cellsAnti-inflammatory macrophagesWound healingSkin barrier functionSubpopulation of macrophagesEarly regenerative stageMultiple myeloid lineagesInflammatory cellsSyngeneic miceWound healing defectsMyeloid cellsCutaneous repairReparative processesSelective depletionPhenotype switchMacrophagesMyeloid lineageMiceMultiple cell typesHealingCD301bHealing defectsSkin repairViral Spread to Enteric Neurons Links Genital HSV-1 Infection to Toxic Megacolon and Lethality
Khoury-Hanold W, Yordy B, Kong P, Kong Y, Ge W, Szigeti-Buck K, Ralevski A, Horvath TL, Iwasaki A. Viral Spread to Enteric Neurons Links Genital HSV-1 Infection to Toxic Megacolon and Lethality. Cell Host & Microbe 2016, 19: 788-799. PMID: 27281569, PMCID: PMC4902295, DOI: 10.1016/j.chom.2016.05.008.Peer-Reviewed Original ResearchConceptsGenital HSV-1 infectionEnteric nervous systemHSV-1 infectionSensory nervous systemNervous systemGenital herpesToxic megacolonHSV-1Genital mucosal epithelial cellsPeripheral sensory nervous systemDorsal root gangliaPathological inflammatory responsesMucosal epithelial cellsHerpes simplex virus 1Simplex virus 1Urinary retentionEnteric neuronsLaxative treatmentAutonomic gangliaRoot gangliaInflammatory responseViral gene transcriptionMouse modelInfectionEpithelial cellsAccess of protective antiviral antibody to neuronal tissues requires CD4 T-cell help
Iijima N, Iwasaki A. Access of protective antiviral antibody to neuronal tissues requires CD4 T-cell help. Nature 2016, 533: 552-556. PMID: 27225131, PMCID: PMC4883597, DOI: 10.1038/nature17979.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntibodies, ViralBiological TransportBlood-Brain BarrierB-LymphocytesCapillary PermeabilityCD4-Positive T-LymphocytesDisease Models, AnimalFemaleGanglia, SpinalHerpes GenitalisHerpesvirus 2, HumanHistocompatibility Antigens Class IImmunologic MemoryIntegrin alpha4Interferon-gammaMiceNerve TissueNervous SystemNeuronsNoseReceptors, FcSpinal CordVesiculovirus