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 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 efficacyLive imaging of SARS-CoV-2 infection in mice reveals that neutralizing antibodies require Fc function for optimal efficacy
Ullah I, Prévost J, Ladinsky MS, Stone H, Lu M, Anand SP, Beaudoin-Bussières G, Symmes K, Benlarbi M, Ding S, Gasser R, Fink C, Chen Y, Tauzin A, Goyette G, Bourassa C, Medjahed H, Mack M, Chung K, Wilen CB, Dekaban GA, Dikeakos JD, Bruce EA, Kaufmann DE, Stamatatos L, McGuire AT, Richard J, Pazgier M, Bjorkman PJ, Mothes W, Finzi A, Kumar P, Uchil PD. Live imaging of SARS-CoV-2 infection in mice reveals that neutralizing antibodies require Fc function for optimal efficacy. Immunity 2021, 54: 2143-2158.e15. PMID: 34453881, PMCID: PMC8372518, DOI: 10.1016/j.immuni.2021.08.015.Peer-Reviewed Original ResearchConceptsCOVID-19 convalescent subjectsSARS-CoV-2 infectionBioluminescence imagingK18-hACE2 miceLive bioluminescence imagingNatural killer cellsFc effector functionsSARS-CoV-2Convalescent subjectsKiller cellsPotent NAbsImmune protectionInflammatory responseEffector functionsNasal cavityNaB treatmentOptimal efficacyFc functionDepletion studiesMiceNAbsCOVID-19Direct neutralizationInfectionAntibodiesNeuroinvasion 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
An ACE2 Microbody Containing a Single Immunoglobulin Fc Domain Is a Potent Inhibitor of SARS-CoV-2
Tada T, Fan C, Chen JS, Kaur R, Stapleford KA, Gristick H, Dcosta BM, Wilen CB, Nimigean CM, Landau NR. An ACE2 Microbody Containing a Single Immunoglobulin Fc Domain Is a Potent Inhibitor of SARS-CoV-2. Cell Reports 2020, 33: 108528. PMID: 33326798, PMCID: PMC7705358, DOI: 10.1016/j.celrep.2020.108528.Peer-Reviewed Original ResearchMeSH KeywordsAmino Acid SequenceAngiotensin-Converting Enzyme 2AnimalsAntiviral AgentsCOVID-19Disease Models, AnimalDisulfidesFemaleHEK293 CellsHumansImmunoglobulin Fc FragmentsMaleMice, TransgenicMicrobodiesProtein DomainsProtein MultimerizationSARS-CoV-2Spike Glycoprotein, CoronavirusVirionVirus InternalizationConceptsSARS-CoV-2Soluble ACE2Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) infectionAcute respiratory syndrome coronavirus 2 infectionLive SARS-CoV-2Syndrome coronavirus 2 infectionCoronavirus 2 infectionSARS-CoV-2 spikeCoronavirus disease 2019SARS-CoV-2 spike proteinDisease 2019Enzyme 2Mouse modelFuture coronavirusesFc fusion proteinΒ-coronavirusViral variantsImmunoglobulin heavy chainSpike proteinACE2 ectodomainImmunoglobulin Fc domainFc domainVirusACE2Potent inhibitorMouse 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 diseaseMice
2019
A Secreted Viral Nonstructural Protein Determines Intestinal Norovirus Pathogenesis
Lee S, Liu H, Wilen CB, Sychev ZE, Desai C, Hykes BL, Orchard RC, McCune BT, Kim KW, Nice TJ, Handley SA, Baldridge MT, Amarasinghe GK, Virgin HW. A Secreted Viral Nonstructural Protein Determines Intestinal Norovirus Pathogenesis. Cell Host & Microbe 2019, 25: 845-857.e5. PMID: 31130511, PMCID: PMC6622463, DOI: 10.1016/j.chom.2019.04.005.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsCaliciviridae InfectionsCytokinesDisease Models, AnimalGastroenteritisHumansImmune EvasionMiceNorovirusViral Nonstructural ProteinsVirulence FactorsConceptsNS1 secretionTuft cellsIFN-λ responseAnti-capsid antibodiesMNoV infectionAcute infectionIntestinal infectionsLack of inductionPersistent infectionNorovirus pathogenesisCaspase-3 cleavageIFN responseInfectionSecretionViral nonstructural proteinsIFNProtein 1/2Viral proteinsMurine norovirusNS1Lower percentageNonstructural proteinsCellsLow numberVaccination
2011
Engineering HIV-Resistant Human CD4+ T Cells with CXCR4-Specific Zinc-Finger Nucleases
Wilen CB, Wang J, Tilton JC, Miller JC, Kim KA, Rebar EJ, Sherrill-Mix SA, Patro SC, Secreto AJ, Jordan AP, Lee G, Kahn J, Aye PP, Bunnell BA, Lackner AA, Hoxie JA, Danet-Desnoyers GA, Bushman FD, Riley JL, Gregory PD, June CH, Holmes MC, Doms RW. Engineering HIV-Resistant Human CD4+ T Cells with CXCR4-Specific Zinc-Finger Nucleases. PLOS Pathogens 2011, 7: e1002020. PMID: 21533216, PMCID: PMC3077364, DOI: 10.1371/journal.ppat.1002020.Peer-Reviewed Original ResearchConceptsT cellsHIV-1Human CD4X4-tropic HIV-1X4 HIV-1CCR5-tropic virusHumanized mouse modelLoss of CXCR4CXCR4-tropic HIVHIV-1 entryHuman T cellsCCR5Δ32 polymorphismAdoptive transferAutologous transplantCell surface expressionCXCR4 coreceptorMouse modelCD4CCR5CXCR4Surface expressionHIVInfectionSuch cellsHost cells