2022
Quantitative Analysis of B-Cell Subpopulations in Bone Marrow by Flow Cytometry
Geng T, Wang P. Quantitative Analysis of B-Cell Subpopulations in Bone Marrow by Flow Cytometry. Methods In Molecular Biology 2022, 2585: 71-77. PMID: 36331766, DOI: 10.1007/978-1-0716-2760-0_8.Peer-Reviewed Original ResearchLipases secreted by a gut bacterium inhibit arbovirus transmission in mosquitoes
Yu X, Tong L, Zhang L, Yang Y, Xiao X, Zhu Y, Wang P, Cheng G. Lipases secreted by a gut bacterium inhibit arbovirus transmission in mosquitoes. PLOS Pathogens 2022, 18: e1010552. PMID: 35679229, PMCID: PMC9182268, DOI: 10.1371/journal.ppat.1010552.Peer-Reviewed Original ResearchConceptsJapanese encephalitis virusYellow fever virusZika virusDengue virusSindbis virusGlobal public healthBroad-spectrum virucidal activityEffective prophylacticLipase activityViral envelope structureViral infectionSevere human diseasesEncephalitis virusAedes aegypti midgutVirucidal activityEtiological agentTremendous burdenFever virusVirusMost arbovirusesPublic healthVector-borne diseasesAegypti midgutDiseaseVirucidal abilityA glucose-like metabolite deficient in diabetes inhibits cellular entry of SARS-CoV-2
Tong L, Xiao X, Li M, Fang S, Ma E, Yu X, Zhu Y, Wu C, Tian D, Yang F, Sun J, Qu J, Zheng N, Liao S, Tai W, Feng S, Zhang L, Li Y, Wang L, Han X, Sun S, Yang L, Zhong H, Zhao J, Liu W, Liu X, Wang P, Li L, Zhao G, Zhang R, Cheng G. A glucose-like metabolite deficient in diabetes inhibits cellular entry of SARS-CoV-2. Nature Metabolism 2022, 4: 547-558. PMID: 35534727, DOI: 10.1038/s42255-022-00567-z.Peer-Reviewed Original ResearchConceptsSARS-CoV-2Diabetes mellitusDiabetic micePre-existing medical comorbiditiesSARS-CoV-2 infectionSARS-CoV-2 replicationRespiratory tissue damageSevere COVID-19COVID-19 pathogenesisHigh viral loadWild-type miceSARS-CoV-2 loadSARS-CoV-2 spike proteinCOVID-19Effective antiviral activityMedical comorbiditiesDiabetic populationDiabetic patientsNondiabetic miceViral loadAG supplementationSustained supplementationAg levelsHealthy individualsViral infection
2021
UBX Domain Protein 6 Positively Regulates JAK-STAT1/2 Signaling.
Ketkar H, Harrison A, Graziano V, Geng T, Yang L, Vella A, Wang P. UBX Domain Protein 6 Positively Regulates JAK-STAT1/2 Signaling. The Journal Of Immunology 2021, 206: 2682-2691. PMID: 34021047, PMCID: PMC8164993, DOI: 10.4049/jimmunol.1901337.Peer-Reviewed Original ResearchConceptsTyrosine kinase 2Domain-containing proteinsExpression of hundredsComplex cellular regulationRNA viral replicationJAK/STATCellular regulationType I/III IFNsKinase 2JAK/Type I/III IFNProtein 6IFN expressionGenesViral infectionSignalingExpressionViral replicationExpression of IFNCellsType IProteinSTATOverexpressionDeletion
2020
A mosquito salivary protein promotes flavivirus transmission by activation of autophagy
Sun P, Nie K, Zhu Y, Liu Y, Wu P, Liu Z, Du S, Fan H, Chen CH, Zhang R, Wang P, Cheng G. A mosquito salivary protein promotes flavivirus transmission by activation of autophagy. Nature Communications 2020, 11: 260. PMID: 31937766, PMCID: PMC6959235, DOI: 10.1038/s41467-019-14115-z.Peer-Reviewed Original ResearchConceptsBeclin-1Viral transmissionFlavivirus transmissionMosquito salivary proteinsHost immune cellsZika virus transmissionActivation of autophagyLow viremiaProphylactic targetsMosquito salivaImmune cellsZIKV transmissionAllergen 1Infected mosquitoesViral infectionMonocyte lineageVirus transmissionMiceMosquitoesSalivary proteinsNumerous studiesViremiaInfectionFlavivirusesProtein
2018
Interferon-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 activity
2015
Mosquito Defense Strategies against Viral Infection
Cheng G, Liu Y, Wang P, Xiao X. Mosquito Defense Strategies against Viral Infection. Trends In Parasitology 2015, 32: 177-186. PMID: 26626596, PMCID: PMC4767563, DOI: 10.1016/j.pt.2015.09.009.Peer-Reviewed Original ResearchConceptsViral infectionMosquito antiviral immunityEfficient antiviral strategiesPathological sequelaePersistent infectionAntiviral immunityArbovirus infectionViral replicationAntiviral strategiesInfectionMosquito tissuesViral diseasesGlobal healthViral propagationMosquitoesTissueNatural vectorSequelaeSpecific tissuesDiseaseImmunityA Neuron-Specific Antiviral Mechanism Prevents Lethal Flaviviral Infection of Mosquitoes
Xiao X, Zhang R, Pang X, Liang G, Wang P, Cheng G. A Neuron-Specific Antiviral Mechanism Prevents Lethal Flaviviral Infection of Mosquitoes. PLOS Pathogens 2015, 11: e1004848. PMID: 25915054, PMCID: PMC4411065, DOI: 10.1371/journal.ppat.1004848.Peer-Reviewed Original ResearchMeSH KeywordsAedesAnimalsAntiviral AgentsApoptosisBrainCell LineCell MembraneDengue VirusDrosophila melanogasterDrosophila ProteinsEncephalitis Virus, JapaneseFemaleHost-Pathogen InteractionsHumansInsect ProteinsNerve Tissue ProteinsNeuronsPhylogenyProtein Interaction Domains and MotifsRecombinant ProteinsViral Envelope ProteinsVirus InternalizationConceptsMosquito nervous systemCentral nervous systemJapanese encephalitis virusNervous systemFlaviviral infectionsDengue virusSindbis virusAntiviral mechanismMembrane targetingDramatic pathologyPlasma membraneAnti-flavivirus activityMosquito cellsSurface envelope proteinMosquito lifespanNatural vectorCulex pipiensHuman viral diseasesNeural cellsFlavivirus infectionEnvelope proteinFunctional blockadeNeural apoptosisMosquito behaviorViral infection
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-STAT
2008
ICAM-1 Participates in the Entry of West Nile Virus into the Central Nervous System
Dai J, Wang P, Bai F, Town T, Fikrig E. ICAM-1 Participates in the Entry of West Nile Virus into the Central Nervous System. Journal Of Virology 2008, 82: 4164-4168. PMID: 18256150, PMCID: PMC2292986, DOI: 10.1128/jvi.02621-07.Peer-Reviewed Original ResearchConceptsWest Nile virusICAM-1Control animalsWest Nile virus neuroinvasionBlood-brain barrier leakagePathogenesis of encephalitisNile virusBlood-brain barrierLow viral loadWest Nile encephalitisCentral nervous systemICAM-1 participatesVirus neuroinvasionNeuronal damageLeukocyte infiltrationViral encephalitisViral loadBarrier leakageViral infectionNervous systemEncephalitisMiceICAMVirusAnimals