2024
UBXN3B is crucial for B lymphopoiesis
Geng T, Yang D, Lin T, Harrison A, Wang B, Cao Z, Torrance B, Fan Z, Wang K, Wang Y, Yang L, Haynes L, Cheng G, Vella A, Flavell R, Pereira J, Fikrig E, Wang P. UBXN3B is crucial for B lymphopoiesis. EBioMedicine 2024, 106: 105248. PMID: 39018756, PMCID: PMC11287013, DOI: 10.1016/j.ebiom.2024.105248.Peer-Reviewed Original ResearchUbiquitin regulatory XPre-BCR signalingB cell receptorB lymphopoiesisKnockout miceValosin-containing proteinCaspase-3 protein levelsCell cycle arrestBone marrow transferNormal B lymphopoiesisUbiquitin ligaseIncreased viral loadCell-intrinsic mannerPathogenesis of severe acute respiratory syndrome coronavirus 2RNA sequencingCycle arrestDNA virusesCell survivalMarrow transferMultiple virusesSingle-cellImmunofluorescence microscopyViral loadMature BRespiratory viruses
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 deficiencyCXCL10 Signaling Contributes to the Pathogenesis of Arthritogenic Alphaviruses
Lin T, Geng T, Harrison AG, Yang D, Vella AT, Fikrig E, Wang P. CXCL10 Signaling Contributes to the Pathogenesis of Arthritogenic Alphaviruses. Viruses 2020, 12: 1252. PMID: 33147869, PMCID: PMC7692144, DOI: 10.3390/v12111252.Peer-Reviewed Original ResearchConceptsChikungunya virusAlphaviral arthritisArthritogenic alphavirusesLargest immune cell populationMacrophages/T cellsImmune cell populationsInflammatory immune responseLow viral loadWild-type miceO'nyong-nyong virusWild-type animalsRheumatic manifestationsImmune infiltratesViral loadT cellsImmune responseAlphaviral diseaseArthritic diseasesTherapeutic targetCXCL10PathogenesisViral RNACell populationsArthritisFootpadMacrophage 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
2018
UBXN3B 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
Nlrp9b inflammasome restricts rotavirus infection in intestinal epithelial cells
Zhu S, Ding S, Wang P, Wei Z, Pan W, Palm NW, Yang Y, Yu H, Li HB, Wang G, Lei X, de Zoete MR, Zhao J, Zheng Y, Chen H, Zhao Y, Jurado KA, Feng N, Shan L, Kluger Y, Lu J, Abraham C, Fikrig E, Greenberg HB, Flavell RA. Nlrp9b inflammasome restricts rotavirus infection in intestinal epithelial cells. Nature 2017, 546: 667-670. PMID: 28636595, PMCID: PMC5787375, DOI: 10.1038/nature22967.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsApoptosis Regulatory ProteinsCARD Signaling Adaptor ProteinsCaspase 1DEAD-box RNA HelicasesEpithelial CellsFemaleImmunity, InnateInflammasomesInterleukin-18Intestinal MucosaIntestinesIntracellular Signaling Peptides and ProteinsMaleMiceMice, Inbred C57BLPhosphate-Binding ProteinsPyroptosisReceptors, G-Protein-CoupledRNA, Double-StrandedRotavirusRotavirus InfectionsAn 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 proliferationUnamplified RNA Sensor for On‐Site Screening of Zika Virus Disease in a Limited Resource Setting
Cheng C, Wu J, Fikrig E, Wang P, Chen J, Eda S, Terry P. Unamplified RNA Sensor for On‐Site Screening of Zika Virus Disease in a Limited Resource Setting. ChemElectroChem 2017, 4: 485-489. DOI: 10.1002/celc.201600831.Peer-Reviewed Original ResearchCopies/μL.Capacitive sensing technologySignal amplificationFalse-positive signalsSite screeningZika virus RNASequence-specific probesSensorsSensing technologyBiosensorLower limitRNA sensorsDetectionField applicationLimited resource settingsVirus RNAConfirmatory laboratory testsΜL.Sensitive meansTechnologyApplications
2013
Mosquito Saliva Serine Protease Enhances Dissemination of Dengue Virus into the Mammalian Host
Conway MJ, Watson AM, Colpitts TM, Dragovic SM, Li Z, Wang P, Feitosa F, Shepherd DT, Ryman KD, Klimstra WB, Anderson JF, Fikrig E. Mosquito Saliva Serine Protease Enhances Dissemination of Dengue Virus into the Mammalian Host. Journal Of Virology 2013, 88: 164-175. PMID: 24131723, PMCID: PMC3911723, DOI: 10.1128/jvi.02235-13.Peer-Reviewed Original ResearchConceptsDengue virusDENV infectivityAedes aegypti salivaMurine lymph nodesSalivary gland extractsAegypti salivaPrevention of diseaseLymph nodesMosquito salivaDENV loadVivo modelSerine protease activityNovel targetViral attachmentViral infectivityVirus infectivitySerine protease inhibitorHeparan sulfate proteoglycanExtracellular matrix proteinsRNA knockdownProtease inhibitorsInfectivitySulfate proteoglycanCell migrationMammalian hostsUBXN1 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
Innate 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 proteinsVaccineAlterations in the Aedes aegypti Transcriptome during Infection with West Nile, Dengue and Yellow Fever Viruses
Colpitts TM, Cox J, Vanlandingham DL, Feitosa FM, Cheng G, Kurscheid S, Wang P, Krishnan MN, Higgs S, Fikrig E. Alterations in the Aedes aegypti Transcriptome during Infection with West Nile, Dengue and Yellow Fever Viruses. PLOS Pathogens 2011, 7: e1002189. PMID: 21909258, PMCID: PMC3164632, DOI: 10.1371/journal.ppat.1002189.Peer-Reviewed Original ResearchConceptsGene expressionDiverse cellular processesPupal cuticle proteinsExpression of genesMosquito gene expressionYellow fever virusFlaviviral infectionsMosquito genesCuticle proteinsCellular processesBioinformatics analysisMosquito cellsExpression profilesMicroarray analysisDDR genesMetabolic processesHuman diseasesGenesTranscriptomic signaturesWest NileFever virusPeptidase activityWNV envelope proteinTranscriptomeAedes aegypti mosquitoesAn 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 ResearchprM-antibody renders immature West Nile virus infectious in vivo
Colpitts TM, Rodenhuis-Zybert I, Moesker B, Wang P, Fikrig E, Smit JM. prM-antibody renders immature West Nile virus infectious in vivo. Journal Of General Virology 2011, 92: 2281-2285. PMID: 21697345, PMCID: PMC3347797, DOI: 10.1099/vir.0.031427-0.Peer-Reviewed Original ResearchConceptsWest Nile virusInfectious West Nile virusNile virusDeath of micePrM antibodiesNeurotropic pathogensWNV particlesSevere human diseasesFamily FlaviviridaeVivo proofImmature flavivirus particlesInfectious potentialAntibodiesDiseaseViral surfaceVirus particlesPrM proteinFlavivirus particlesVirusHuman diseasesInfectionMiceFlavivirusesBrainSerum
2010
Tick Histamine Release Factor Is Critical for Ixodes scapularis Engorgement and Transmission of the Lyme Disease Agent
Dai J, Narasimhan S, Zhang L, Liu L, Wang P, Fikrig E. Tick Histamine Release Factor Is Critical for Ixodes scapularis Engorgement and Transmission of the Lyme Disease Agent. PLOS Pathogens 2010, 6: e1001205. PMID: 21124826, PMCID: PMC2991271, DOI: 10.1371/journal.ppat.1001205.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsBiomarkers, TumorBlotting, WesternBorrelia burgdorferiFeeding BehaviorFemaleHistamineHumansImmunizationIxodesLyme DiseaseMiceMice, Inbred C3HReverse Transcriptase Polymerase Chain ReactionRNA, MessengerRNA, Small InterferingSalivaTick InfestationsTumor Protein, Translationally-Controlled 1ConceptsTick-borne pathogensB. burgdorferi transmissionTick engorgementB. burgdorferi burdenHistamine-releasing factorRapid feeding phaseBurgdorferi-infected ticksAnimal healthTick feedingTick salivaDiverse infectious agentsDisease agentsTicksIxodes scapularisLyme disease agentRNA interferenceFeeding phaseVaccine potentialQuantitative reverse transcription PCRReverse transcription-PCRHistamine releaseEffective vaccineVascular permeabilityBlood flowInfectious agentsCaspase-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
2009
Antibodies against a Tick Protein, Salp15, Protect Mice from the Lyme Disease Agent
Dai J, Wang P, Adusumilli S, Booth CJ, Narasimhan S, Anguita J, Fikrig E. Antibodies against a Tick Protein, Salp15, Protect Mice from the Lyme Disease Agent. Cell Host & Microbe 2009, 6: 482-492. PMID: 19917502, PMCID: PMC2843562, DOI: 10.1016/j.chom.2009.10.006.Peer-Reviewed Original ResearchConceptsArthropod-borne pathogensTick-borne BorreliaTick salivary proteinsTick proteinsB. burgdorferiLyme diseaseDisease agentsTick-borne illnessB. burgdorferi infectionLyme disease agentHuman vaccinesSalp15Infection of miceB. burgdorferi antigensMicrobial toxinsMammalian hostsBorrelia burgdorferiPathogensMechanism of actionBurgdorferi infectionProtect miceMedical importanceBurgdorferiProtective capacityMiceThe Urokinase Receptor (uPAR) Facilitates Clearance of Borrelia burgdorferi
Hovius JW, Bijlsma MF, van der Windt GJ, Wiersinga WJ, Boukens BJ, Coumou J, Oei A, de Beer R, de Vos AF, van 't Veer C, van Dam AP, Wang P, Fikrig E, Levi MM, Roelofs JJ, van der Poll T. The Urokinase Receptor (uPAR) Facilitates Clearance of Borrelia burgdorferi. PLOS Pathogens 2009, 5: e1000447. PMID: 19461880, PMCID: PMC2678258, DOI: 10.1371/journal.ppat.1000447.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsArthritis, InfectiousBorrelia burgdorferiCell MovementHeartHistocytochemistryHumansLeukocytesLyme DiseaseMiceMice, Inbred C57BLMice, KnockoutMyocarditisPhagocytosisReceptors, Urokinase Plasminogen ActivatorSkinStatistics, NonparametricUp-RegulationUrinary BladderUrokinase-Type Plasminogen ActivatorConceptsB. burgdorferi numbersWT controlsPhagocytotic capacityC3H/HeN backgroundIL-1beta mRNA expressionBorrelia burgdorferiB. burgdorferi infectionRole of uPARSevere carditisBurgdorferi infectionImmune responseLeukocyte functionSpirochete Borrelia burgdorferiFibrinolytic systemPAI-1Facilitate clearanceMRNA expressionHuman leukocytesLyme borreliosisMiceB. burgdorferiCausative agentProteinase receptorUPARAdequate eradication