2024
Cholesterol promotes IFNG mRNA expression in CD4+ effector/memory cells by SGK1 activation
Hanin A, Comi M, Sumida T, Hafler D. Cholesterol promotes IFNG mRNA expression in CD4+ effector/memory cells by SGK1 activation. Life Science Alliance 2024, 7: e202402890. PMID: 39366761, PMCID: PMC11452476, DOI: 10.26508/lsa.202402890.Peer-Reviewed Original ResearchConceptsCentral nervous systemT cellsEffector/memory cellsCentral nervous system milieuT cell environmentCD4 T cellsIFNG mRNA expressionCXCR3<sup>+</sup> cellsT cell homeostasisInhibition of SGK1Targeting lipid pathwaysMaintenance of immune surveillanceSerum/glucocorticoid-regulated kinaseImmune surveillanceHealthy donorsCytotoxic capacityEffector responsesInflammatory conditionsSGK1 activityMRNA expressionNervous systemSGK1Metabolic conditionsLipid pathwaysTissue adaptation
2023
Differential effects of anti-CD20 therapy on CD4 and CD8 T cells and implication of CD20-expressing CD8 T cells in MS disease activity
Shinoda K, Li R, Rezk A, Mexhitaj I, Patterson K, Kakara M, Zuroff L, Bennett J, von Büdingen H, Carruthers R, Edwards K, Fallis R, Giacomini P, Greenberg B, Hafler D, Ionete C, Kaunzner U, Lock C, Longbrake E, Pardo G, Piehl F, Weber M, Ziemssen T, Jacobs D, Gelfand J, Cross A, Cameron B, Musch B, Winger R, Jia X, Harp C, Herman A, Bar-Or A. Differential effects of anti-CD20 therapy on CD4 and CD8 T cells and implication of CD20-expressing CD8 T cells in MS disease activity. Proceedings Of The National Academy Of Sciences Of The United States Of America 2023, 120: e2207291120. PMID: 36634138, PMCID: PMC9934304, DOI: 10.1073/pnas.2207291120.Peer-Reviewed Original ResearchConceptsEarly disease activityDisease activityCD8 T cellsT cellsCD20 therapyPeripheral blood mononuclear cellsCellular immune profilesNew disease activityMS disease activityT cell poolMultiple sclerosis patientsAnti-inflammatory profileBlood mononuclear cellsTreatment-associated changesMultiparametric flow cytometryCentral nervous systemFurther dosingRepeat infusionsImmune profileMS patientsSclerosis patientsValidation cohortMononuclear cellsRelapse developmentImmune cascade
2022
Basic principles of neuroimmunology
Yoshida TM, Wang A, Hafler DA. Basic principles of neuroimmunology. Seminars In Immunopathology 2022, 44: 685-695. PMID: 35732977, DOI: 10.1007/s00281-022-00951-7.Peer-Reviewed Original ResearchConceptsNeuro-immune interactionsCentral nervous systemImmune privilegeCerebrospinal fluidCNS-resident immune cellsImmune-derived cytokinesResident T cellsImmune cell infiltrationImmune-privileged organMeningeal lymphatic systemIntroduction of antigenImmune compartmentNeuroinflammatory diseasesNeurological functionCNS homeostasisCell infiltrationHarmful inflammationImmune cellsPeripheral organsT cellsImmune responseLeukocyte traffickingNervous systemImmune systemLymphatic system
2020
Transcriptomic and clonal characterization of T cells in the human central nervous system
Pappalardo JL, Zhang L, Pecsok MK, Perlman K, Zografou C, Raddassi K, Abulaban A, Krishnaswamy S, Antel J, van Dijk D, Hafler DA. Transcriptomic and clonal characterization of T cells in the human central nervous system. Science Immunology 2020, 5 PMID: 32948672, PMCID: PMC8567322, DOI: 10.1126/sciimmunol.abb8786.Peer-Reviewed Original ResearchConceptsCentral nervous systemCSF of patientsT cellsCerebrospinal fluidMultiple sclerosisImmune surveillanceNervous systemCSF T cellsHuman central nervous systemHealthy human donorsT cell activationImmune dysfunctionNeuroinflammatory diseasesCytotoxic capacityHealthy donorsHealthy individualsCell activationHuman donorsTissue adaptationPatientsClonal characterizationExpression of genesCellsSurveillanceFurther characterizationChapter 51 Multiple Sclerosis
Wesley S, Hafler D. Chapter 51 Multiple Sclerosis. 2020, 961-986. DOI: 10.1016/b978-0-12-812102-3.00051-8.Peer-Reviewed Original ResearchMultiple sclerosisModern treatment paradigmsAutoreactive T cellsPeripheral immune systemCentral nervous systemTreatable diseaseInflammatory processTreatment paradigmT cellsNervous systemDisease pathogenesisImmune systemUnknown originUntreatable diseaseSclerosisPathogenesisDiseaseGenetic haplotypesStrong evidenceComprehensive reviewMyelin
2019
CXCR3+ T cells in multiple sclerosis correlate with reduced diversity of the gut microbiome
Choileáin SN, Kleinewietfeld M, Raddassi K, Hafler DA, Ruff WE, Longbrake EE. CXCR3+ T cells in multiple sclerosis correlate with reduced diversity of the gut microbiome. Journal Of Translational Autoimmunity 2019, 3: 100032. PMID: 32743517, PMCID: PMC7388357, DOI: 10.1016/j.jtauto.2019.100032.Peer-Reviewed Original ResearchInflammatory T cell subsetsCentral nervous systemT cell subsetsMultiple sclerosisT cellsGut microbiomeCell subsetsCNS-reactive T cellsRelapsing-remitting MS patientsGrey matter inflammationGut-immune axisExpression of CXCR3CD8 T cellsAltered gut microbiomeAutoreactive T cellsMultiple sclerosis correlateGut microbiome compositionInflammatory subsetMS pathogenesisMS patientsTh1 phenotypeAxonal degenerationAutoimmune diseasesCascade of eventsDisease onsetMultiple sclerosis genomic map implicates peripheral immune cells and microglia in susceptibility
Patsopoulos N, Baranzini S, Santaniello A, Shoostari P, Cotsapas C, Wong G, Beecham A, James T, Replogle J, Vlachos I, McCabe C, Pers T, Brandes A, White C, Keenan B, Cimpean M, Winn P, Panteliadis I, Robbins A, Andlauer T, Zarzycki O, Dubois B, Goris A, Søndergaard H, Sellebjerg F, Sorensen P, Ullum H, Thørner L, Saarela J, Cournu-Rebeix I, Damotte V, Fontaine B, Guillot-Noel L, Lathrop M, Vukusic S, Berthele A, Pongratz V, Buck D, Gasperi C, Graetz C, Grummel V, Hemmer B, Hoshi M, Knier B, Korn T, Lill C, Luessi F, Mühlau M, Zipp F, Dardiotis E, Agliardi C, Amoroso A, Barizzone N, Benedetti M, Bernardinelli L, Cavalla P, Clarelli F, Comi G, Cusi D, Esposito F, Ferrè L, Galimberti D, Guaschino C, Leone M, Martinelli V, Moiola L, Salvetti M, Sorosina M, Vecchio D, Zauli A, Santoro S, Mancini N, Zuccalà M, Mescheriakova J, van Duijn C, Bos S, Celius E, Spurkland A, Comabella M, Montalban X, Alfredsson L, Bomfim I, Gomez-Cabrero D, Hillert J, Jagodic M, Lindén M, Piehl F, Jelčić I, Martin R, Sospedra M, Baker A, Ban M, Hawkins C, Hysi P, Kalra S, Karpe F, Khadake J, Lachance G, Molyneux P, Neville M, Thorpe J, Bradshaw E, Caillier S, Calabresi P, Cree B, Cross A, Davis M, de Bakker P, Delgado S, Dembele M, Edwards K, Fitzgerald K, Frohlich I, Gourraud P, Haines J, Hakonarson H, Kimbrough D, Isobe N, Konidari I, Lathi E, Lee M, Li T, An D, Zimmer A, Madireddy L, Manrique C, Mitrovic M, Olah M, Patrick E, Pericak-Vance M, Piccio L, Schaefer C, Weiner H, Lage K, Compston A, Hafler D, Harbo H, Hauser S, Stewart G, D’Alfonso S, Hadjigeorgiou G, Taylor B, Barcellos L, Booth D, Hintzen R, Kockum I, Martinelli-Boneschi F, McCauley J, Oksenberg J, Oturai A, Sawcer S, Ivinson A, Olsson T, De Jager P. Multiple sclerosis genomic map implicates peripheral immune cells and microglia in susceptibility. Science 2019, 365 PMID: 31604244, PMCID: PMC7241648, DOI: 10.1126/science.aav7188.Peer-Reviewed Original ResearchMeSH KeywordsCase-Control StudiesCell Cycle ProteinsChromosome MappingChromosomes, Human, XGene FrequencyGenetic LociGenome-Wide Association StudyGenomicsGTPase-Activating ProteinsHumansInheritance PatternsMajor Histocompatibility ComplexMicrogliaMultiple SclerosisPolymorphism, Single NucleotideQuantitative Trait LociRNA-SeqTranscriptomeConceptsMajor histocompatibility complexMultiple sclerosisImmune cellsBrain-resident immune cellsPeripheral immune cellsPeripheral immune responseCentral nervous systemExtended major histocompatibility complexAutoimmune processControl subjectsHuman microgliaImmune responseNervous systemImmune systemHistocompatibility complexPutative susceptibility genesMicrogliaX variantGenetic architectureSusceptibility genesGenomic mapGenetic dataExpression profilesM geneSusceptibility variantsCHAPTER 2 Genetics of Multiple Sclerosis
Abulaban A, Hafler D, Longbrake E. CHAPTER 2 Genetics of Multiple Sclerosis. 2019, 33-54. DOI: 10.1039/9781788016070-00033.ChaptersMultiple sclerosisCentral nervous systemImmune cell infiltratesComplex autoimmune diseaseEnvironmental risk factorsExtensive CNS demyelinationMS therapyAxonal damageCell infiltrateCNS demyelinationAutoimmune diseasesRisk factorsGenetic predispositionNervous systemDisease severityDiseaseSclerosisComplex genetic diseasesChapter 2 GeneticsGenetic diseasesDemyelinationInfiltratesAutoimmunityPathogenesisTherapy
2018
Fingolimod modulates T cell phenotype and regulatory T cell plasticity in vivo
Dominguez-Villar M, Raddassi K, Danielsen AC, Guarnaccia J, Hafler DA. Fingolimod modulates T cell phenotype and regulatory T cell plasticity in vivo. Journal Of Autoimmunity 2018, 96: 40-49. PMID: 30122421, PMCID: PMC7882197, DOI: 10.1016/j.jaut.2018.08.002.Peer-Reviewed Original ResearchConceptsT cellsMultiple sclerosisT cell effector phenotypeRelapsing-remitting multiple sclerosisRegulatory T cell populationTh1-like phenotypeRegulatory T cellsPro-inflammatory cytokinesT-cell phenotypeT cell populationsExpression of Th1Immune cell functionRegulatory T cell plasticityT cell plasticityCentral nervous systemExpression of markersCell migratory capacityImportant immunomodulatory functionsExcessive Th1Fingolimod treatmentExhaustion markersTh17 cytokinesEffector phenotypeLymph nodesSerum levelsRegulatory T Cells: From Discovery to Autoimmunity
Kitz A, Singer E, Hafler D. Regulatory T Cells: From Discovery to Autoimmunity. Cold Spring Harbor Perspectives In Medicine 2018, 8: a029041. PMID: 29311129, PMCID: PMC6280708, DOI: 10.1101/cshperspect.a029041.Peer-Reviewed Original ResearchConceptsAutoreactive T cellsT cellsMultiple sclerosisEffector-like T cellsInterferon γ secretionEffector T cellsRegulatory T cellsTreg cell functionT-bet expressionCentral nervous systemT cell activationFunctional TregsΓ secretionProinflammatory cytokinesVitamin DAutoimmune diseasesGenetic predispositionNervous systemLoss of functionReduced suppressionConsistent findingCell functionDisease developmentActivationCellsChapter 46 Multiple sclerosis
Cotsapas C, Mitrovic M, Hafler D. Chapter 46 Multiple sclerosis. Handbook Of Clinical Neurology 2018, 148: 723-730. PMID: 29478610, DOI: 10.1016/b978-0-444-64076-5.00046-6.Peer-Reviewed Original ResearchConceptsMultiple sclerosisCentral nervous system white matterNervous system white matterAutoimmune neurologic disordersDisease-modifying therapiesImmune function modulationSpecific immune subsetsCentral nervous systemGenetic variantsImmune subsetsNeurologic symptomsAutoimmune attackLeading causeNeurologic disordersNervous systemWhite matterCommon genetic variantsOverall riskSclerosisYoung adultsEnvironmental exposuresRiskSymptomsDiseasePatients
2017
Co‐inhibitory blockade while preserving tolerance: checkpoint inhibitors for glioblastoma
Lucca LE, Hafler DA. Co‐inhibitory blockade while preserving tolerance: checkpoint inhibitors for glioblastoma. Immunological Reviews 2017, 276: 9-25. PMID: 28258696, PMCID: PMC5338636, DOI: 10.1111/imr.12529.Peer-Reviewed Original ResearchConceptsCheckpoint immunotherapyTumor rejectionCommon adult brain tumorsImmune-related side effectsCheckpoint receptor blockadeCo-inhibitory receptorsIntroduction of immunotherapyT cell exhaustionImmune regulatory pathwaysCo-inhibitory pathwaysAdult brain tumorsPrevention of autoimmunityCentral nervous systemAnti-tumor activityDifferent tumor typesCheckpoint inhibitorsReceptor blockadeAdvanced cancerTherapeutic successBrain tumorsSide effectsImmunotherapyNervous systemTherapeutic efficacyTumor types
2016
The Link Between CD6 and Autoimmunity: Genetic and Cellular Associations.
Kofler DM, Farkas A, von Bergwelt-Baildon M, Hafler DA. The Link Between CD6 and Autoimmunity: Genetic and Cellular Associations. Current Drug Targets 2016, 17: 651-65. PMID: 26844569, DOI: 10.2174/1389450117666160201105934.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntigens, CDAntigens, Differentiation, T-LymphocyteArthritis, RheumatoidAutoimmunityCD4-Positive T-LymphocytesCell Adhesion Molecules, NeuronalClinical Trials as TopicDisease Models, AnimalFetal ProteinsGenetic Predisposition to DiseaseHumansMultiple SclerosisPolymorphism, Single NucleotideConceptsMultiple sclerosisRheumatoid arthritisCentral nervous systemNervous systemSingle nucleotide polymorphismsDevelopment of MSTreatment of RARole of CD6T cell traffickingT cell functionGenetic risk factorsEndothelial cell barrierCD6 geneClinical responseGenetic associationClinical featuresAutoimmune diseasesSynovial cellsRisk factorsTumor necrosisSynovial fibroblastsPossible common mechanismT cellsT lymphocytesLeukocyte trafficking
2015
Investigating the Antigen Specificity of Multiple Sclerosis Central Nervous System-Derived Immunoglobulins
Willis SN, Stathopoulos P, Chastre A, Compton SD, Hafler DA, O’Connor K. Investigating the Antigen Specificity of Multiple Sclerosis Central Nervous System-Derived Immunoglobulins. Frontiers In Immunology 2015, 6: 600. PMID: 26648933, PMCID: PMC4663633, DOI: 10.3389/fimmu.2015.00600.Peer-Reviewed Original ResearchCentral nervous systemB cell responsesMultiple sclerosisB cellsCNS tissueCerebrospinal fluidAntigen specificityNervous systemCell responsesAntigen-driven B cell responsesImmune cell infiltrationMS central nervous systemTertiary lymphoid structuresResident B cellsAntigen-driven responseB cell clonesMS brainsLymphoid structuresCell infiltrationRecombinant human immunoglobulinNeurofilament lightCNS-derived cell linesCandidate antigensAntigen arraysDisease pathology
2014
B cells populating the multiple sclerosis brain mature in the draining cervical lymph nodes
Stern JN, Yaari G, Vander Heiden JA, Church G, Donahue WF, Hintzen RQ, Huttner AJ, Laman JD, Nagra RM, Nylander A, Pitt D, Ramanan S, Siddiqui BA, Vigneault F, Kleinstein SH, Hafler DA, O'Connor KC. B cells populating the multiple sclerosis brain mature in the draining cervical lymph nodes. Science Translational Medicine 2014, 6: 248ra107. PMID: 25100741, PMCID: PMC4388137, DOI: 10.1126/scitranslmed.3008879.Peer-Reviewed Original ResearchConceptsCervical lymph nodesCentral nervous systemB cellsCerebrospinal fluidLymph nodesMultiple sclerosisLymphoid tissueCNS of patientsCNS B cellsAntigen-experienced B cellsMultiple sclerosis brainSecondary lymphoid tissuesB cell compartmentB cell trafficB cell maturationImmunomodulatory therapyImmune infiltratesPeripheral bloodInflammatory diseasesLymphocyte transmigrationPeripheral tissuesNervous systemMembers of clonesCell maturationCell traffic
2013
Regulatory T Cells in MS
Gawlik B, Hafler D. Regulatory T Cells in MS. 2013, 27-47. DOI: 10.1007/978-1-4614-7953-6_2.Peer-Reviewed Original ResearchRegulatory T cellsAutoreactive T cellsT cellsCentral nervous systemMultiple sclerosisTreg cellsHealthy individualsPathogenic autoreactive T cellsMultifocal demyelinating diseaseDemyelinating diseaseCNS lesionsMS patientsAutoimmune responseAutoimmune diseasesPeripheral bloodImmune homeostasisImmune responseNervous systemSusceptible individualsProgressive neurodegenerationDiseaseKey regulatorCellsIndividualsHigher numberSpecific peripheral B cell tolerance defects in patients with multiple sclerosis
Kinnunen T, Chamberlain N, Morbach H, Cantaert T, Lynch M, Preston-Hurlburt P, Herold KC, Hafler DA, O’Connor K, Meffre E. Specific peripheral B cell tolerance defects in patients with multiple sclerosis. Journal Of Clinical Investigation 2013, 123: 2737-2741. PMID: 23676463, PMCID: PMC3668812, DOI: 10.1172/jci68775.Peer-Reviewed Original ResearchConceptsB cell tolerance checkpointsB cell tolerance defectsMultiple sclerosisRheumatoid arthritisTolerance checkpointsB cellsPeripheral B cell tolerance checkpointsTolerance defectsAutoreactive B cell clonesMature naive B cellsType 1 diabetesAutoreactive B cellsB cell toleranceCentral nervous systemNaive B cellsB cell clonesB cell selectionEarly B cell developmentIPEX patientsMost patientsTreg functionHomeostatic proliferationAutoimmune diseasesPatientsHealthy individuals
2012
Regulatory T cells in the central nervous system
Lowther DE, Hafler DA. Regulatory T cells in the central nervous system. Immunological Reviews 2012, 248: 156-169. PMID: 22725960, DOI: 10.1111/j.1600-065x.2012.01130.x.Peer-Reviewed Original ResearchConceptsRegulatory T cellsTreg functionAutoimmune diseasesT cellsForkhead box protein 3Central nervous system diseaseBox protein 3Nervous system diseasesCentral nervous systemPotential therapeutic targetHuman immune systemTreg biologyPeripheral toleranceMultiple sclerosisCNS diseaseImmune surveillanceImmune responseSystem diseasesTherapeutic targetNervous systemImmune systemProtein 3DiseaseTregsCells
2011
Related B cell clones populate the meninges and parenchyma of patients with multiple sclerosis
Lovato L, Willis SN, Rodig SJ, Caron T, Almendinger SE, Howell OW, Reynolds R, O’Connor K, Hafler DA. Related B cell clones populate the meninges and parenchyma of patients with multiple sclerosis. Brain 2011, 134: 534-541. PMID: 21216828, PMCID: PMC3030766, DOI: 10.1093/brain/awq350.Peer-Reviewed Original ResearchConceptsB cell clonesB cell aggregatesMultiple sclerosisCentral nervous systemParenchymal infiltratesCell clonesNervous systemMeningeal B cell aggregatesRelated B cell clonesProgressive multiple sclerosisB-cell infiltratesCerebral spinal fluidInflammatory plaquesCell infiltrateImmune compartmentParenchymal lesionsLymphoid tissueSclerosisSpinal fluidWhite matterPatientsGray matterBrain tissueInfiltratesMeninges
2010
A unique antibody gene signature is prevalent in the central nervous system of patients with multiple sclerosis
Ligocki AJ, Lovato L, Xiang D, Guidry P, Scheuermann RH, Willis SN, Almendinger S, Racke MK, Frohman EM, Hafler DA, O'Connor KC, Monson NL. A unique antibody gene signature is prevalent in the central nervous system of patients with multiple sclerosis. Journal Of Neuroimmunology 2010, 226: 192-193. PMID: 20655601, PMCID: PMC2937103, DOI: 10.1016/j.jneuroim.2010.06.016.Peer-Reviewed Original ResearchConceptsMultiple sclerosisB cellsGene signatureMS brain tissueCSF of patientsCNS tissue samplesEnriched B cellsCentral nervous systemB cell receptorMS brainsTissue injuryNervous systemBrain tissueCell receptorTissue samplesSclerosisPatientsCSFUnique accumulationCellsSomatic hypermutationInjuryBrainReceptors