2021
A critical role for MSR1 in vesicular stomatitis virus infection of the central nervous system
Yang D, Lin T, Li C, Harrison A, Geng T, Wang P. A critical role for MSR1 in vesicular stomatitis virus infection of the central nervous system. IScience 2021, 24: 102678. PMID: 34169243, PMCID: PMC8208900, DOI: 10.1016/j.isci.2021.102678.Peer-Reviewed Original ResearchMacrophage scavenger receptor 1Vesicular stomatitis virus infectionCentral nervous systemStomatitis virus infectionSpinal cordVirus infectionNervous systemLethal VSV infectionMsr1 deficient miceM2 macrophage polarizationWild-type miceInnate immune responseReceptor-dependent mannerScavenger receptor 1Cellular entryViral loadReduced morbidityImmune responseMacrophage polarizationVSV infectionMSR1 expressionViral pathogenesisReceptor 1Bacterial infectionsHost defense
2020
A Critical Role for STING Signaling in Limiting Pathogenesis of Chikungunya Virus
Geng T, Lin T, Yang D, Harrison AG, Vella AT, Fikrig E, Wang P. A Critical Role for STING Signaling in Limiting Pathogenesis of Chikungunya Virus. The Journal Of Infectious Diseases 2020, 223: 2186-2196. PMID: 33161431, PMCID: PMC8205639, DOI: 10.1093/infdis/jiaa694.Peer-Reviewed Original ResearchConceptsVirus infectionSTING signalingGt miceType I IFN responseChikungunya virus infectionImmune cell infiltrationWild-type miceActivator of neutrophilsInnate immune responseExpression of interferonI IFN responseExpression of chemoattractantsRNA virus infectionDNA virus infectionInterferon genes (STING) pathwayCHIKV arthritisViremic stageArthritis progressionViral burdenArthritis pathogenesisChemokine responsesCell infiltrationJoint damageImmune responseSTING deficiencyMacrophage scavenger receptor 1 controls Chikungunya virus infection through autophagy in mice
Yang L, Geng T, Yang G, Ma J, Wang L, Ketkar H, Yang D, Lin T, Hwang J, Zhu S, Wang Y, Dai J, You F, Cheng G, Vella AT, Flavell RA, Fikrig E, Wang P. Macrophage scavenger receptor 1 controls Chikungunya virus infection through autophagy in mice. Communications Biology 2020, 3: 556. PMID: 33033362, PMCID: PMC7545163, DOI: 10.1038/s42003-020-01285-6.Peer-Reviewed Original ResearchConceptsMacrophage scavenger receptor 1Scavenger receptor 1Chikungunya virusReceptor 1Antiviral roleType I IFN responseChikungunya virus infectionLow-density lipoproteinImportant antiviral roleI IFN responseMarkers of autophagyCHIKV infectionViral loadArthritogenic alphavirusesVirus infectionCHIKV replicationATG5-ATG12Antiviral actionKnockout miceMSR1 expressionIFN responseInfectionMiceNsp1 proteinAutophagic function
2019
Host serum iron modulates dengue virus acquisition by mosquitoes
Zhu Y, Tong L, Nie K, Wiwatanaratanabutr I, Sun P, Li Q, Yu X, Wu P, Wu T, Yu C, Liu Q, Bian Z, Wang P, Cheng G. Host serum iron modulates dengue virus acquisition by mosquitoes. Nature Microbiology 2019, 4: 2405-2415. PMID: 31527795, DOI: 10.1038/s41564-019-0555-x.Peer-Reviewed Original ResearchConceptsSerum ironDengue virusVirus acquisitionDengue virus infectionIron-deficient miceDengue virus prevalenceIron metabolism pathwaysViral loadIron supplementationA. aegypti mosquitoesHigh prevalenceVirus infectionArbovirus infectionHuman donorsIron deficiencyInfectionBlood componentsGut epitheliumReactive oxygen speciesSusceptibility of mosquitoesVirus prevalenceAegypti mosquitoesBlood mealHuman bloodVirusEndogenous Retrovirus-Derived Long Noncoding RNA Enhances Innate Immune Responses via Derepressing RELA Expression
Zhou B, Qi F, Wu F, Nie H, Song Y, Shao L, Han J, Wu Z, Saiyin H, Wei G, Wang P, Ni T, Qian F. Endogenous Retrovirus-Derived Long Noncoding RNA Enhances Innate Immune Responses via Derepressing RELA Expression. MBio 2019, 10: 10.1128/mbio.00937-19. PMID: 31363026, PMCID: PMC6667616, DOI: 10.1128/mbio.00937-19.Peer-Reviewed Original ResearchConceptsAntiviral immune responseImmune responseInnate immune responseNF-κB subunitsExpression of RelADeficient miceI interferonAntiviral responseVirus-induced cytokine productionHost genome instabilityEndogenous retrovirusesNF-κB signalingType I interferonRNA virus infectionViral RNA mimicViral loadCytokine productionViral challengeVirus infectionLong noncoding RNADeleterious roleRelA expressionViral replicationViral sensorsReduced expressionLack of efficacy of ivermectin for prevention of a lethal Zika virus infection in a murine system
Ketkar H, Yang L, Wormser GP, Wang P. Lack of efficacy of ivermectin for prevention of a lethal Zika virus infection in a murine system. Diagnostic Microbiology And Infectious Disease 2019, 95: 38-40. PMID: 31097261, PMCID: PMC6697611, DOI: 10.1016/j.diagmicrobio.2019.03.012.Peer-Reviewed Original ResearchConceptsZika virus infectionAnti-Zika virus activityVirus infectionAnimal modelsZika virusLethal Zika Virus InfectionIFNAR1 knockout miceZika virus strainLack of efficacyEffectiveness of ivermectinLethal infectionKnockout miceVirus activityAntiviral activityMurine systemVirus strainsDrug ivermectinInfectionIvermectinStudy limitationsPreventionVirusSenegal strainMice
2018
A Gut Commensal Bacterium Promotes Mosquito Permissiveness to Arboviruses
Wu P, Sun P, Nie K, Zhu Y, Shi M, Xiao C, Liu H, Liu Q, Zhao T, Chen X, Zhou H, Wang P, Cheng G. A Gut Commensal Bacterium Promotes Mosquito Permissiveness to Arboviruses. Cell Host & Microbe 2018, 25: 101-112.e5. PMID: 30595552, DOI: 10.1016/j.chom.2018.11.004.Peer-Reviewed Original ResearchConceptsArboviral infectionsCommensal bacteriumGut bacteriaDengue virus infectionGut commensal bacteriumCultivable gut bacteriaAedes aegypti mosquitoesVirus infectionViral disseminationAntibiotic depletionIntestinal tractOral introductionGut microbiomeGut epitheliumInfectionMembrane-bound mucinsHuman virusesAegypti mosquitoesHematophagous vectorsVector competenceArbovirusesField mosquitoesSerratia marcescensMosquitoesVirusInterferon-stimulated TRIM69 interrupts dengue virus replication by ubiquitinating viral nonstructural protein 3
Wang K, Zou C, Wang X, Huang C, Feng T, Pan W, Wu Q, Wang P, Dai J. Interferon-stimulated TRIM69 interrupts dengue virus replication by ubiquitinating viral nonstructural protein 3. PLOS Pathogens 2018, 14: e1007287. PMID: 30142214, PMCID: PMC6126873, DOI: 10.1371/journal.ppat.1007287.Peer-Reviewed Original ResearchMeSH KeywordsA549 CellsAnimalsAnophelesCells, CulturedDengue VirusGene Expression RegulationHEK293 CellsHeLa CellsHuman Umbilical Vein Endothelial CellsHumansInterferon Type IMiceProtein Processing, Post-TranslationalRNA HelicasesSerine EndopeptidasesTripartite Motif ProteinsUbiquitinationUbiquitin-Protein LigasesUp-RegulationViral Nonstructural ProteinsVirus ReplicationConceptsInterferon-stimulated genesI interferonNonstructural protein 3DENV replicationMost interferon-stimulated genesProtein 3Dengue virus infectionDengue virus replicationType I interferonViral nonstructural protein 3DENV infectionImmunocompetent miceVirus infectionViral infectionAntiviral activityVirus replicationVivo studiesInfectionTripartite motif (TRIM) proteinsTRIM family membersViral nonstructural proteinsFamily membersNonstructural proteinsTRIM69E3 ubiquitin ligase activityUBXN3B positively regulates STING-mediated antiviral immune responses
Yang L, Wang L, Ketkar H, Ma J, Yang G, Cui S, Geng T, Mordue DG, Fujimoto T, Cheng G, You F, Lin R, Fikrig E, Wang P. UBXN3B positively regulates STING-mediated antiviral immune responses. Nature Communications 2018, 9: 2329. PMID: 29899553, PMCID: PMC5998066, DOI: 10.1038/s41467-018-04759-8.Peer-Reviewed Original ResearchConceptsUbiquitin regulatory X domain-containing proteinAntiviral immune responseImmune responseDeficient immune responseDomain-containing proteinsInterferon genes (STING) signalingVesicular stomatitis virus infectionDiverse biological processesStomatitis virus infectionPhosphorylation of TBK1Physiological evidenceHerpes simplex virus 1Cre-loxP approachSimplex virus 1Virus infectionAdult miceGene signalingHSV-1Biological processesPhysiological functionsVirus 1MicePrimary cellsConsequent recruitmentResponse
2017
Sophoraflavenone G Restricts Dengue and Zika Virus Infection via RNA Polymerase Interference
Sze A, Olagnier D, Hadj SB, Han X, Tian XH, Xu HT, Yang L, Shi Q, Wang P, Wainberg MA, Wu JH, Lin R. Sophoraflavenone G Restricts Dengue and Zika Virus Infection via RNA Polymerase Interference. Viruses 2017, 9: 287. PMID: 28972551, PMCID: PMC5691638, DOI: 10.3390/v9100287.Peer-Reviewed Original ResearchConceptsZika virus infectionHepatitis C virusHepatitis C replicationPost-infection treatmentGlobal health concernAntiviral treatmentC virusVirus infectionVesicular stomatitis virusZika virusAntiviral compoundsHealth concernChinese medicinePolymerase inhibitionDengueStomatitis virusVirusTreatmentRNA polymerase inhibitionInfectionDiseaseFlavivirusesAn essential role of PI3K in the control of West Nile virus infection
Wang L, Yang L, Fikrig E, Wang P. An essential role of PI3K in the control of West Nile virus infection. Scientific Reports 2017, 7: 3724. PMID: 28623344, PMCID: PMC5473900, DOI: 10.1038/s41598-017-03912-5.Peer-Reviewed Original ResearchConceptsWest Nile virus infectionPI3K inhibitorsPI3KVirus infectionImmune responseK inhibitorsType I IFN responseAntiviral immune responseI IFN responseCatalytic subunit p110δTNF-α protein productionPrimary mouse macrophagesFlaviviral infectionsAntiviral immunityIFN responseViral titersClass I PI3KAntiviral roleMRNA expressionPI3K activityIFNProtein expressionInfectionMouse macrophagesCell proliferation
2016
Glycosphingolipid GM3 is Indispensable for Dengue Virus Genome Replication
Wang K, Wang J, Sun T, Bian G, Pan W, Feng T, Wang P, Li Y, Dai J. Glycosphingolipid GM3 is Indispensable for Dengue Virus Genome Replication. International Journal Of Biological Sciences 2016, 12: 872-883. PMID: 27313500, PMCID: PMC4910605, DOI: 10.7150/ijbs.15641.Peer-Reviewed Original ResearchConceptsDENV infectionDengue virusB16 cellsDENV attachmentSynthetase inhibitorGM95 cellsPrevalent arthropodVirus infectionMouse melanoma B16 cellsMortality rateViral-host interactionsMelanoma B16 cellsMouse brainViral replicationInfectionVirus genome replicationViral diseasesGenome replicationViral genome replicationEndoplasmic reticulumGM3CellsViral replication complexInhibitorsGlycosphingolipidsExploration of West Nile Virus Infection in Mouse Models
Wang P. Exploration of West Nile Virus Infection in Mouse Models. Methods In Molecular Biology 2016, 1435: 71-81. PMID: 27188551, DOI: 10.1007/978-1-4939-3670-0_7.Peer-Reviewed Original ResearchConceptsWest Nile virusMouse modelWest Nile virus infectionExperimental mouse modelAntiviral immune responseCentral nervous systemWNV pathogenesisLeukocyte numbersVirus infectionImmune responseBlood leukocytesWNV infectionNervous systemNeurological diseasesMouse brainViral titersResidential cellsLeukocytesNile virusVirus spreadInfectionImmunopathologyPathogenesisCNSDisease
2013
UBXN1 Interferes with Rig-I-like Receptor-Mediated Antiviral Immune Response by Targeting MAVS
Wang P, Yang L, Cheng G, Yang G, Xu Z, You F, Sun Q, Lin R, Fikrig E, Sutton RE. UBXN1 Interferes with Rig-I-like Receptor-Mediated Antiviral Immune Response by Targeting MAVS. Cell Reports 2013, 3: 1057-1070. PMID: 23545497, PMCID: PMC3707122, DOI: 10.1016/j.celrep.2013.02.027.Peer-Reviewed Original ResearchConceptsAntiviral immune responseInnate immune responseImmune responseLike receptorsSystemic antiviral immune responsesVirus-induced innate immune responsesDengue virus infectionType I interferon responseI interferon responseRNA virusesVirus infectionViral infectionStrong inhibitory effectViral replicationVirus replicationInterferon responseRNA virus replicationInhibitory effectWest NileMAVSVesicular stomatitisInfectionAdaptor moleculeFamily membersReceptors
2011
ISG15 facilitates cellular antiviral response to dengue and west nile virus infection in vitro
Dai J, Pan W, Wang P. ISG15 facilitates cellular antiviral response to dengue and west nile virus infection in vitro. Virology Journal 2011, 8: 468. PMID: 21992229, PMCID: PMC3215395, DOI: 10.1186/1743-422x-8-468.Peer-Reviewed Original ResearchConceptsWest Nile virusNon-infected cellsWNV infectionViral infectionWest Nile virus infectionWest Nile meningoencephalitisInterferon beta 1Type I interferonCellular antiviral responseVirus infectionI interferonAntiviral responseFlaviviridae familyRAW264.7 cellsDENVInfectionConclusionsThese findingsBeta 1Protein ISGylationGene 15SOCS3 siRNANile virusCausative agentExact roleISG15Innate immune control of West Nile virus infection
Arjona A, Wang P, Montgomery RR, Fikrig E. Innate immune control of West Nile virus infection. Cellular Microbiology 2011, 13: 1648-1658. PMID: 21790942, PMCID: PMC3196381, DOI: 10.1111/j.1462-5822.2011.01649.x.Peer-Reviewed Original ResearchConceptsWest Nile virusWNV infectionAntiviral innate immune mechanismsLong-term neurologic sequelaeWest Nile virus infectionRe-emerging zoonotic pathogenInnate immune controlInnate immune mechanismsLife-threatening meningoencephalitisInnate immune systemNeurologic sequelaeImmune controlInflammatory mediatorsImmune mechanismsMammalian hostsVirus infectionCurrent evidenceViral infectionAntiviral effectorsImmune systemFlaviviridae familyAntiviral mechanismInfectionNile virusJAK-STATDengue Virus Capsid Protein Binds Core Histones and Inhibits Nucleosome Formation in Human Liver Cells
Colpitts TM, Barthel S, Wang P, Fikrig E. Dengue Virus Capsid Protein Binds Core Histones and Inhibits Nucleosome Formation in Human Liver Cells. PLOS ONE 2011, 6: e24365. PMID: 21909430, PMCID: PMC3164731, DOI: 10.1371/journal.pone.0024365.Peer-Reviewed Original ResearchConceptsDENV infectionDENV CHuman liver cellsDengue virusLiver cellsDengue virus infectionTime-dependent mannerSpecific antiviralsVirus infectionInfectionAlters levelsSerious human diseasesInteresting new roleViral RNANuclear presenceMature virus particlesVirus particlesHuman diseasesFlaviviral replicationCellsCellular responsesCapsid proteinStructural proteinsVaccineAn In Vivo Transfection Approach Elucidates a Role for Aedes aegypti Thioester-Containing Proteins in Flaviviral Infection
Cheng G, Liu L, Wang P, Zhang Y, Zhao YO, Colpitts TM, Feitosa F, Anderson JF, Fikrig E. An In Vivo Transfection Approach Elucidates a Role for Aedes aegypti Thioester-Containing Proteins in Flaviviral Infection. PLOS ONE 2011, 6: e22786. PMID: 21818390, PMCID: PMC3144946, DOI: 10.1371/journal.pone.0022786.Peer-Reviewed Original Research
2010
Caspase-12 controls West Nile virus infection via the viral RNA receptor RIG-I
Wang P, Arjona A, Zhang Y, Sultana H, Dai J, Yang L, LeBlanc PM, Doiron K, Saleh M, Fikrig E. Caspase-12 controls West Nile virus infection via the viral RNA receptor RIG-I. Nature Immunology 2010, 11: 912-919. PMID: 20818395, PMCID: PMC3712356, DOI: 10.1038/ni.1933.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsCaspase 12Cells, CulturedDEAD Box Protein 58DEAD-box RNA HelicasesDNA-Binding ProteinsFibroblastsImmunity, InnateInterferon Type IMiceMice, Inbred C57BLMice, KnockoutNeuronsReceptors, VirusSignal TransductionTranscription FactorsUbiquitinationUbiquitin-Protein LigasesWest Nile FeverWest Nile virusA C-Type Lectin Collaborates with a CD45 Phosphatase Homolog to Facilitate West Nile Virus Infection of Mosquitoes
Cheng G, Cox J, Wang P, Krishnan MN, Dai J, Qian F, Anderson JF, Fikrig E. A C-Type Lectin Collaborates with a CD45 Phosphatase Homolog to Facilitate West Nile Virus Infection of Mosquitoes. Cell 2010, 142: 714-725. PMID: 20797779, PMCID: PMC2954371, DOI: 10.1016/j.cell.2010.07.038.Peer-Reviewed Original ResearchConceptsWest Nile virusWNV infectionWest Nile virus infectionArthropod-borne flavivirusBlood-feeding processVirus infectionHuman CD45Viral disseminationC-type lectinInfectionViral entryViral attachmentMosquito homologCalcium-dependent mannerNile virusMolecular understandingVivo experimentsSame pathwayNatural vector