Yingjun Cui, PhD
Associate Research Scientist (Infectious Diseases)Cards
About
Research
Publications
2024
Cytoskeleton‐associated gelsolin responds to the midgut distention process in saline meal‐fed Aedes aegypti and affects arbovirus dissemination from the midgut
Cui Y, Megawati D, Lin J, Rehard D, Grant D, Liu P, Jurkevich A, Reid W, Mooney B, Franz A. Cytoskeleton‐associated gelsolin responds to the midgut distention process in saline meal‐fed Aedes aegypti and affects arbovirus dissemination from the midgut. The FASEB Journal 2024, 38: e23764. PMID: 39042395, PMCID: PMC11268798, DOI: 10.1096/fj.202302684rr.Peer-Reviewed Original ResearchConceptsApoptotic signalingHost factorsInduction of apoptosisIncreased induction of apoptosisBlood meal ingestionDifferentially expressed proteinsActin filamentsCytoskeleton modulationTime course analysisSecondary tissuesBasal laminaStable knockoutTissue distentionAedes aegyptiMosquito linesFunctional studiesVertebrate hostsSynthesized virionsMosquito midgutMidgut escape barrierCourse analysisGelsolinSurrounding basal laminaMidgutMidgut tissueZika virus exists in enterocytes and enteroendocrine cells of the Aedes aegypti midgut
Chen T, Raduwan H, Marín-López A, Cui Y, Fikrig E. Zika virus exists in enterocytes and enteroendocrine cells of the Aedes aegypti midgut. IScience 2024, 27: 110353. PMID: 39055935, PMCID: PMC11269924, DOI: 10.1016/j.isci.2024.110353.Peer-Reviewed Original ResearchAedes aegypti midgutEnteroendocrine cellsSingle-cell RNA sequencingIntestinal stem cellsVirus infectionPathogen interactionsExpressed genesRNA sequencingCopy numberTranscriptomic changesFunctional studiesInfected cellsZika virus infectionEnteroendocrineBlood digestionRNA copy numberCellular levelCell processesGenesMidgutPotential targetCell clustersCellsEnterocytesViral infectionAn atlas of human vector-borne microbe interactions reveals pathogenicity mechanisms
Hart T, Sonnert N, Tang X, Chaurasia R, Allen P, Hunt J, Read C, Johnson E, Arora G, Dai Y, Cui Y, Chuang Y, Yu Q, Rahman M, Mendes M, Rolandelli A, Singh P, Tripathi A, Ben Mamoun C, Caimano M, Radolf J, Lin Y, Fingerle V, Margos G, Pal U, Johnson R, Pedra J, Azad A, Salje J, Dimopoulos G, Vinetz J, Carlyon J, Palm N, Fikrig E, Ring A. An atlas of human vector-borne microbe interactions reveals pathogenicity mechanisms. Cell 2024, 187: 4113-4127.e13. PMID: 38876107, DOI: 10.1016/j.cell.2024.05.023.Peer-Reviewed Original ResearchCell invasionHost-microbe interactionsArthropod-borne pathogensHost sensingMicrobe interactionsTranscriptional regulationLyme disease spirocheteMicrobial interactionsExtracellular proteinsMicrobial pathogenesisEpidermal growth factorTissue colonizationEnvironmental cuesBacterial selectivityIntracellular pathogensPutative interactionsNext-generation therapeuticsPathogensFunctional investigationsInteractomeVector-borne diseasesImmune evasionPathogenic mechanismsStrainUnmet medical needA cell atlas of the adult female Aedes aegypti midgut revealed by single-cell RNA sequencing
Wang S, Huang Y, Wang F, Han Q, Ren N, Wang X, Cui Y, Yuan Z, Xia H. A cell atlas of the adult female Aedes aegypti midgut revealed by single-cell RNA sequencing. Scientific Data 2024, 11: 587. PMID: 38839790, PMCID: PMC11153528, DOI: 10.1038/s41597-024-03432-8.Peer-Reviewed Original ResearchConceptsSingle-cell RNA sequencingFat body cellsRNA sequencingSingle-cell levelHemocyte cellsEnteroendocrine cellsVisceral musclesSingle-nucleus resolutionTranscriptome of AeMosquito midgutAedes aegypti midgutMidgut transcriptomeBlood meal digestionCell atlasCardia cellsArbovirus infectionMeal digestionNutrient absorptionMidgut cellsMidgutBody cellsCell clustersPrimary vectorSequenceCellsmosGILT controls innate immunity and germ cell development in Anopheles gambiae
Arora G, Tang X, Cui Y, Yang J, Chuang Y, Joshi J, Sajid A, Dong Y, Cresswell P, Dimopoulos G, Fikrig E. mosGILT controls innate immunity and germ cell development in Anopheles gambiae. BMC Genomics 2024, 25: 42. PMID: 38191283, PMCID: PMC10775533, DOI: 10.1186/s12864-023-09887-0.Peer-Reviewed Original ResearchConceptsGerm cell developmentAnopheles gambiaeCell developmentOvarian developmentReductase-like proteinWild-type mosquitoesPlasmodium life cycleBiological controlGrowth genesEssential regulatorRNA sequencingA. gambiaeGenesGambiaeAltered expressionImpaired ovarian developmentMosquito vectorsLife cycleMosquitoesImmune activationPlasmodium infectionTranscriptomeOogenesisRegulatorProteinmRNA vaccination of rabbits alters the fecundity, but not the attachment, of adult Ixodes scapularis
Matias J, Cui Y, Lynn G, DePonte K, Mesquita E, Muramatsu H, Alameh M, Dwivedi G, Tam Y, Pardi N, Weissman D, Fikrig E. mRNA vaccination of rabbits alters the fecundity, but not the attachment, of adult Ixodes scapularis. Scientific Reports 2024, 14: 496. PMID: 38177212, PMCID: PMC10766947, DOI: 10.1038/s41598-023-50389-6.Peer-Reviewed Original Research
2023
Metabolomic changes associated with acquired resistance to Ixodes scapularis
Cui Y, Matias J, Tang X, Cibichakravarthy B, DePonte K, Wu M, Fikrig E. Metabolomic changes associated with acquired resistance to Ixodes scapularis. Ticks And Tick-borne Diseases 2023, 15: 102279. PMID: 37972499, DOI: 10.1016/j.ttbdis.2023.102279.Peer-Reviewed Original ResearchGuinea pigsHydroxyphenyllactic acidMetabolome of serumGroups of miceTyrosine metabolic pathwayTick biteImmune responseControl animalsIxodes scapularisTick salivaI. scapularisMiceInduction of componentsMetabolomic changesMortalityNitisinoneMolecular mechanismsAnimalsMetabolism pathwaysTyrosine degradationPigsTyrosine metabolism pathwayMetabolic pathwaysScapularisMetabolomeAdiponectin in the mammalian host influences ticks’ acquisition of the Lyme disease pathogen Borrelia
Tang X, Cao Y, Booth C, Arora G, Cui Y, Matias J, Fikrig E. Adiponectin in the mammalian host influences ticks’ acquisition of the Lyme disease pathogen Borrelia. PLOS Biology 2023, 21: e3002331. PMID: 37862360, PMCID: PMC10619873, DOI: 10.1371/journal.pbio.3002331.Peer-Reviewed Original ResearchConceptsAdipocyte-derived hormoneBite siteAdiponectin-deficient miceInfiltration of neutrophilsTick bite sitePro-inflammatory responseWild-type animalsIxodes scapularis ticksIL-1βVascular leakageHistamine releaseTick biteAdiponectinInfectious diseasesLyme disease agentBlood feeding arthropodsBorrelia burgdorferiScapularis ticksAnimal infectious diseasesBlood feedingB. burgdorferi survivalHuman bloodHormonePathogen acquisitionMammalian hostsBulk and single-nucleus RNA sequencing highlight immune pathways induced in individuals during an Ixodes scapularis tick bite
Tang X, Lynn G, Cui Y, Cerny J, Arora G, Tomayko M, Craft J, Fikrig E. Bulk and single-nucleus RNA sequencing highlight immune pathways induced in individuals during an Ixodes scapularis tick bite. Infection And Immunity 2023, 91: e00282-23. PMID: 37846980, PMCID: PMC10652856, DOI: 10.1128/iai.00282-23.Peer-Reviewed Original ResearchConceptsRNA sequencingSingle-nucleus RNA sequencingBulk RNA sequencingInterleukin-17 signalingPlatelet activation pathwaysLaboratory guinea pigsSnRNA-seqHippo signalingIndividual genesPeripheral bloodTick biteAdaptive immunityAnti-tick vaccinesGuidance pathwayImmune pathwaysNew biomarkersHost responseGuinea pigsHematophagous arthropodsHost defenseCell adhesionTick attachmentNovel insightsTick feedingPhysiological consequencesSpecific mRNA lipid nanoparticles and acquired resistance to ticks
Matias J, Cui Y, Tang X, Sajid A, Arora G, Wu M, DePonte K, Muramatsu H, Tam Y, Narasimhan S, Pardi N, Weissman D, Fikrig E. Specific mRNA lipid nanoparticles and acquired resistance to ticks. Vaccine 2023, 41: 4996-5002. PMID: 37407406, PMCID: PMC10530371, DOI: 10.1016/j.vaccine.2023.06.081.Peer-Reviewed Original Research