2024
A Noncanonical CD56dimCD16dim/- NK Cell Subset Indicative of Prior Cytotoxic Activity Is Elevated in Patients with Autoantibody-Mediated Neurologic Diseases.
Yandamuri S, Filipek B, Lele N, Cohen I, Bennett J, Nowak R, Sotirchos E, Longbrake E, Mace E, O'Connor K. A Noncanonical CD56dimCD16dim/- NK Cell Subset Indicative of Prior Cytotoxic Activity Is Elevated in Patients with Autoantibody-Mediated Neurologic Diseases. The Journal Of Immunology 2024, 212: 785-800. PMID: 38251887, PMCID: PMC10932911, DOI: 10.4049/jimmunol.2300015.Peer-Reviewed Original ResearchConceptsNeuromyelitis optica spectrum disorderAb-dependent cellular cytotoxicityNK cellsMyasthenia gravisMG patientsInduced Ab-dependent cellular cytotoxicityNK cell-mediated effector functionsPeripheral blood immune cell populationsCell-mediated effector functionsNeuromyelitis optica spectrum disorder patientsBlood immune cell populationsAb-dependent cellular cytotoxicity activityNK marker CD56NK cell markersHLA-DR expressionNK cell subsetsExpression of perforinImmune cell populationsAutoimmune myasthenia gravisElevated disease burdenHLA-DRCell subsetsCellular cytotoxicityChemokine receptorsMultiparameter immunophenotyping
2023
From drab to Fab; PLP1's fit is redressed for MS.
Bayer A, O'Connor K. From drab to Fab; PLP1's fit is redressed for MS. Science Immunology 2023, 8: eadl0618. PMID: 37801515, DOI: 10.1126/sciimmunol.adl0618.Commentaries, Editorials and LettersRemission of severe myasthenia gravis after autologous stem cell transplantation
Schlatter M, Yandamuri S, O'Connor K, Nowak R, Pham M, Obaid A, Redman C, Provost M, McSweeney P, Pearlman M, Tees M, Bowen J, Nash R, Georges G. Remission of severe myasthenia gravis after autologous stem cell transplantation. Annals Of Clinical And Translational Neurology 2023, 10: 2105-2113. PMID: 37726935, PMCID: PMC10646993, DOI: 10.1002/acn3.51898.Peer-Reviewed Original ResearchConceptsHematopoietic cell transplantationRefractory myasthenia gravisAutologous hematopoietic cell transplantationMyasthenia gravisCell transplantationAcetylcholine receptorsAutologous stem cell transplantationPhase 2 clinical trialAmerica (MGFA) clinical classificationMultiple immunomodulatory agentsRabbit antithymocyte globulinSevere myasthenia gravisAutoimmune neurological disordersHigh-dose chemotherapyMyasthenia Gravis FoundationNeuromuscular junction disordersStem cell transplantationTherapeutic plasma exchangeImmune cell subtypesDays of treatmentEffect of treatmentAntithymocyte globulinDisease activityComplete responseUnderwent treatmentToddler's T cells are taught in muco-school.
Khani-Habibabadi F, O'Connor K. Toddler's T cells are taught in muco-school. Science Immunology 2023, 8: eadj9555. PMID: 37540737, DOI: 10.1126/sciimmunol.adj9555.Peer-Reviewed Original ResearchIndividual myasthenia gravis autoantibody clones can efficiently mediate multiple mechanisms of pathology
Pham M, Masi G, Patzina R, Obaid A, Oxendine S, Oh S, Payne A, Nowak R, O’Connor K. Individual myasthenia gravis autoantibody clones can efficiently mediate multiple mechanisms of pathology. Acta Neuropathologica 2023, 146: 319-336. PMID: 37344701, PMCID: PMC11380498, DOI: 10.1007/s00401-023-02603-y.Peer-Reviewed Original ResearchConceptsMyasthenia gravisAntigenic modulationPathogenic mechanismsAutoimmune myasthenia gravisCurrent therapeutic approachesΑ-bungarotoxin bindingNicotinic acetylcholine receptorsReceptor blockadeSerum autoantibodiesAutoreactive clonesMonoclonal levelTherapeutic approachesMonoclonal autoantibodiesAcetylcholine receptorsComplement activationAutoantibodiesAChR subunitsJurkat cell lineDistinct molecular mechanismsPathogenic profilePathogenic capacityPathologyCell-based assaysMAbsPatientsMOGAD patient autoantibodies induce complement, phagocytosis, and cellular cytotoxicity
Yandamuri S, Filipek B, Obaid A, Lele N, Thurman J, Makhani N, Nowak R, Guo Y, Lucchinetti C, Flanagan E, Longbrake E, O’Connor K. MOGAD patient autoantibodies induce complement, phagocytosis, and cellular cytotoxicity. JCI Insight 2023, 8: e165373. PMID: 37097758, PMCID: PMC10393237, DOI: 10.1172/jci.insight.165373.Peer-Reviewed Original ResearchConceptsMyelin oligodendrocyte glycoprotein antibody-associated diseaseAntibody-dependent cellular phagocytosisAntibody-dependent cellular cytotoxicityComplement-dependent cytotoxicityMOG autoantibodiesPatient seraCellular cytotoxicityEffector functionsComplement activityAntibody-associated diseaseMultiple mechanismsNK cellsPatient autoantibodiesCytotoxic capacityLesion histologyCellular phagocytosisFuture relapseIgG subclassesCerebrospinal fluidAutoantibodiesCNS conditionsMOGSerumRelapseCytotoxicityThe Plasma Cell Infiltrate Populating the Muscle Tissue of Patients with Inclusion Body Myositis Features Distinct B Cell Receptor Repertoire Properties
Jiang R, Roy B, Wu Q, Mohanty S, Nowak R, Shaw A, Kleinstein S, O’Connor K. The Plasma Cell Infiltrate Populating the Muscle Tissue of Patients with Inclusion Body Myositis Features Distinct B Cell Receptor Repertoire Properties. ImmunoHorizons 2023, 7: 310-322. PMID: 37171806, PMCID: PMC10579972, DOI: 10.4049/immunohorizons.2200078.Peer-Reviewed Original ResearchConceptsInclusion body myositisMemory B cellsCell infiltrateBody myositisB cellsIBM muscle biopsiesB-cell infiltratesPlasma cell infiltrateClass-switched IgGMuscle tissueAdaptive immune receptor repertoire sequencingHumoral responseHealthy controlsIgA isotypePlasma cellsCell repertoireMuscle biopsyInfiltratesDegenerative disordersDisease pathologyRepertoire sequencingSkeletal muscleDermatomyositisPolymyositisMyositisClinicoserological insights into patients with immune checkpoint inhibitor‐induced myasthenia gravis
Masi G, Pham M, Karatz T, Oh S, Payne A, Nowak R, Howard J, Guptill J, Juel V, O'Connor K. Clinicoserological insights into patients with immune checkpoint inhibitor‐induced myasthenia gravis. Annals Of Clinical And Translational Neurology 2023, 10: 825-831. PMID: 36924454, PMCID: PMC10187728, DOI: 10.1002/acn3.51761.Peer-Reviewed Original ResearchPrecision targeting of autoantigen-specific B cells in muscle-specific tyrosine kinase myasthenia gravis with chimeric autoantibody receptor T cells
Oh S, Mao X, Manfredo-Vieira S, Lee J, Patel D, Choi E, Alvarado A, Cottman-Thomas E, Maseda D, Tsao P, Ellebrecht C, Khella S, Richman D, O’Connor K, Herzberg U, Binder G, Milone M, Basu S, Payne A. Precision targeting of autoantigen-specific B cells in muscle-specific tyrosine kinase myasthenia gravis with chimeric autoantibody receptor T cells. Nature Biotechnology 2023, 41: 1229-1238. PMID: 36658341, PMCID: PMC10354218, DOI: 10.1038/s41587-022-01637-z.Peer-Reviewed Original ResearchConceptsMuscle‐specific tyrosine kinase myasthenia gravisReceptor T cellsB cellsT cellsMyasthenia gravisChimeric autoantibody receptor T cellsCD19 chimeric antigen receptor T cellsAutoantigen-specific B cellsChimeric antigen receptor T cellsAntigen receptor T cellsAnti-MuSK antibodiesB-cell depletionTotal IgG levelsClinical study designInvestigational new drug applicationChronic immunosuppressionIgG levelsMuscle weaknessAutoimmune diseasesCell depletionCurrent therapiesSimilar efficacyCytolytic activityMouse modelNew drug applications
2022
Reemergence of pathogenic, autoantibody-producing B cell clones in myasthenia gravis following B cell depletion therapy
Fichtner ML, Hoehn KB, Ford EE, Mane-Damas M, Oh S, Waters P, Payne AS, Smith ML, Watson CT, Losen M, Martinez-Martinez P, Nowak RJ, Kleinstein SH, O’Connor K. Reemergence of pathogenic, autoantibody-producing B cell clones in myasthenia gravis following B cell depletion therapy. Acta Neuropathologica Communications 2022, 10: 154. PMID: 36307868, PMCID: PMC9617453, DOI: 10.1186/s40478-022-01454-0.Peer-Reviewed Original ResearchConceptsB cell depletion therapyB cell clonesMuSK-MG patientsMyasthenia gravisB cellsMG patientsDepletion therapyCell clonesAutoantibody-producing B cellsMuscle-specific tyrosine kinaseComplete stable remissionB cell receptor repertoireCell receptor repertoireValuable candidate biomarkersB cell receptorMG relapseClinical relapseStable remissionDisease relapseAutoimmune disordersRelapsePatientsAcetylcholine receptorsCandidate biomarkersReceptor repertoireNovel pathophysiological insights in autoimmune myasthenia gravis
Masi G, O’Connor K. Novel pathophysiological insights in autoimmune myasthenia gravis. Current Opinion In Neurology 2022, 35: 586-596. PMID: 35942663, PMCID: PMC9458626, DOI: 10.1097/wco.0000000000001088.Peer-Reviewed Reviews, Practice Guidelines, Standards, and Consensus StatementsConceptsAutoimmune myasthenia gravisMyasthenia gravisMG patientsClinical responseMuscle-specific tyrosine kinaseSpecific therapeutic strategiesNovel pathophysiological insightsMG pathologyMG subtypesAutoantibody repertoireTreatment optionsCancer immunotherapyPredictive biomarkersSuch therapyImmunological heterogeneityPathophysiological insightsMG phenotypeTherapeutic strategiesClinical observationsTherapeutic outcomesAcetylcholine receptorsDisease subtypesTherapeutic perspectivesSubtypesDevelopment of assaysInflammatory Responses After Ischemic Stroke
DeLong JH, Ohashi SN, O’Connor K, Sansing LH. Inflammatory Responses After Ischemic Stroke. Seminars In Immunopathology 2022, 44: 625-648. PMID: 35767089, DOI: 10.1007/s00281-022-00943-7.Peer-Reviewed Reviews, Practice Guidelines, Standards, and Consensus StatementsMyasthenia gravis complement activity is independent of autoantibody titer and disease severity
Fichtner ML, Hoarty MD, Vadysirisack DD, Munro-Sheldon B, Nowak RJ, O’Connor K. Myasthenia gravis complement activity is independent of autoantibody titer and disease severity. PLOS ONE 2022, 17: e0264489. PMID: 35290370, PMCID: PMC8923450, DOI: 10.1371/journal.pone.0264489.Peer-Reviewed Original ResearchConceptsAutoantibody titersComplement activityDisease activityMyasthenia gravisComplement pathwayAcetylcholine receptor autoantibodiesAutoimmune myasthenia gravisSecondary complement deficiencyClassical complement pathwayAChR autoantibodiesReceptor autoantibodiesClinical statusAutoimmune diseasesHealthy controlsComplement deficiencyPatients associatesStudy subjectsCandidate biomarkersDisease statusDisease severitySignificant associationDisease pathologyTitersAutoantibodiesPatients
2020
CD4+ follicular regulatory T cells optimize the influenza virus–specific B cell response
Lu Y, Jiang R, Freyn AW, Wang J, Strohmeier S, Lederer K, Locci M, Zhao H, Angeletti D, O’Connor K, Kleinstein SH, Nachbagauer R, Craft J. CD4+ follicular regulatory T cells optimize the influenza virus–specific B cell response. Journal Of Experimental Medicine 2020, 218: e20200547. PMID: 33326020, PMCID: PMC7748821, DOI: 10.1084/jem.20200547.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntibody FormationAntigensB-LymphocytesCD4 AntigensDisease Models, AnimalEpitopesForkhead Transcription FactorsGerminal CenterHumansImmunityImmunologic MemoryInfluenza, HumanInfluenzavirus BIntegrasesMice, Inbred C57BLOrthomyxoviridae InfectionsReceptors, Antigen, B-CellSpecies SpecificityT-Lymphocytes, RegulatoryVaccinationConceptsB cell responsesGerminal center B cell responsesFollicular regulatory T cellsRegulatory T cellsTfr cellsCell responsesT cellsViral challengeHumoral memoryVirus-specific B cell responsesAntigen-specific B cell responsesFollicular helper T cellsHA stalk regionHelper T cellsInfluenza virus infectionGerminal center developmentAntibody responsePlasma cellsVirus infectionImmunization modelAntibody productionBCR repertoireInfluenza virusRepeated exposureInfluenza virus glycoproteinsAffinity maturation is required for pathogenic monovalent IgG4 autoantibody development in myasthenia gravis
Fichtner ML, Vieni C, Redler RL, Kolich L, Jiang R, Takata K, Stathopoulos P, Suarez PA, Nowak RJ, Burden SJ, Ekiert DC, O’Connor K. Affinity maturation is required for pathogenic monovalent IgG4 autoantibody development in myasthenia gravis. Journal Of Experimental Medicine 2020, 217: e20200513. PMID: 32820331, PMCID: PMC7953735, DOI: 10.1084/jem.20200513.Peer-Reviewed Original ResearchConceptsMyasthenia gravisUnmutated common ancestorPathogenic capacityMuscle-specific tyrosine kinaseAffinity maturationMuSK myasthenia gravisAutoimmune myasthenia gravisMonovalent antigen-binding fragmentsUnique autoantibodiesIgG4 autoantibodiesAutoantibody developmentAutoantibodiesFab-arm exchangeMonoclonal autoantibodiesAntigen-binding fragmentsGravisSomatic mutationsSubnanomolar affinityMAbsMonovalent FabTyrosine kinaseMaturationImmunopathologyAutoimmunityThe B cell immunobiology that underlies CNS autoantibody-mediated diseases
Sun B, Ramberger M, O’Connor K, Bashford-Rogers RJM, Irani SR. The B cell immunobiology that underlies CNS autoantibody-mediated diseases. Nature Reviews Neurology 2020, 16: 481-492. PMID: 32724223, PMCID: PMC9364389, DOI: 10.1038/s41582-020-0381-z.Peer-Reviewed Original ResearchConceptsAutoantigen-specific B cellsB cellsPathogenic autoantibodiesB cell tolerance checkpointsAutoantibody-mediated diseasesB cell immunobiologyLong-term morbidityHigher serum levelsCirculation of patientsSource of autoantibodiesSite of pathologyB-cell lineageClinical relapseAvailable medicationsSerum levelsIntrathecal synthesisCNS diseaseTolerance checkpointsPlasma cellsTherapeutic effectCerebrospinal fluidGerminal centersAutoantibodiesDiseasePatientsAutoimmune Pathology in Myasthenia Gravis Disease Subtypes Is Governed by Divergent Mechanisms of Immunopathology
Fichtner ML, Jiang R, Bourke A, Nowak RJ, O’Connor K. Autoimmune Pathology in Myasthenia Gravis Disease Subtypes Is Governed by Divergent Mechanisms of Immunopathology. Frontiers In Immunology 2020, 11: 776. PMID: 32547535, PMCID: PMC7274207, DOI: 10.3389/fimmu.2020.00776.Peer-Reviewed Original ResearchConceptsLipoprotein receptor-related protein 4Chronic inflammatory demyelinating polyneuropathyMuSK myasthenia gravisMyasthenia gravisDisease subtypesPathogenic autoantibodiesNeuromyelitis opticaPemphigus vulgarisFab-arm exchangeNeuromuscular junctionAChR myasthenia gravisDistinct immune mechanismsInflammatory demyelinating polyneuropathyAutoimmune myasthenia gravisContribution of complementMuscle-specific kinaseNicotinic acetylcholine receptorsSubtype of diseaseDemyelinating polyneuropathyMG subtypesMG patientsAutoantibody productionClinical benefitAutoimmune diseasesAutoimmune pathology
2019
Characterization of pathogenic monoclonal autoantibodies derived from muscle-specific kinase myasthenia gravis patients
Takata K, Stathopoulos P, Cao M, Mané-Damas M, Fichtner ML, Benotti ES, Jacobson L, Waters P, Irani SR, Martinez-Martinez P, Beeson D, Losen M, Vincent A, Nowak RJ, O’Connor K. Characterization of pathogenic monoclonal autoantibodies derived from muscle-specific kinase myasthenia gravis patients. JCI Insight 2019, 4: e127167. PMID: 31217355, PMCID: PMC6629167, DOI: 10.1172/jci.insight.127167.Peer-Reviewed Original ResearchConceptsMyasthenia gravisMonoclonal autoantibodiesNeuromuscular junctionMuscle-specific tyrosine kinaseMuSK-MG patientsChronic autoimmune disorderMyasthenia gravis patientsSubset of patientsMouse neuromuscular junctionHuman monoclonal autoantibodiesMuSK autoantibodiesAutoimmune mechanismsGravis patientsMG patientsMost patientsPathogenic autoantibodiesAutoimmune disordersMuscle weaknessNeuromuscular transmissionMuSK phosphorylationAutoantibodiesB cellsAcetylcholine receptorsSynaptic differentiationPatientsEarly B cell tolerance defects in neuromyelitis optica favour anti-AQP4 autoantibody production
Cotzomi E, Stathopoulos P, Lee CS, Ritchie AM, Soltys JN, Delmotte FR, Oe T, Sng J, Jiang R, K A, Vander Heiden JA, Kleinstein SH, Levy M, Bennett JL, Meffre E, O’Connor K. Early B cell tolerance defects in neuromyelitis optica favour anti-AQP4 autoantibody production. Brain 2019, 142: 1598-1615. PMID: 31056665, PMCID: PMC6536857, DOI: 10.1093/brain/awz106.Peer-Reviewed Original ResearchConceptsNeuromyelitis optica spectrum disorderB cell tolerance checkpointsNMOSD patientsNaïve B cellsAQP4 autoantibodiesTolerance checkpointsHealthy donorsB cellsEarly B cell tolerance checkpointsPeripheral B cell tolerance checkpointsMature naïve B cellsB cell tolerance defectsSeropositive NMOSD patientsOptica spectrum disorderRare autoimmune disorderNaïve B-cell compartmentB cell compartmentB cell populationsAquaporin-4 water channelsPathogenic autoantibodiesAutoantibody productionOptic nerveAutoimmune disordersSevere inflammationSpinal cordAutoantibodies against Neurologic Antigens in Nonneurologic Autoimmunity
Stathopoulos P, Chastre A, Waters P, Irani S, Fichtner ML, Benotti ES, Guthridge JM, Seifert J, Nowak RJ, Buckner JH, Holers VM, James JA, Hafler DA, O’Connor K. Autoantibodies against Neurologic Antigens in Nonneurologic Autoimmunity. The Journal Of Immunology 2019, 202: ji1801295. PMID: 30824481, PMCID: PMC6452031, DOI: 10.4049/jimmunol.1801295.Peer-Reviewed Original ResearchConceptsSystemic lupus erythematosusRheumatoid arthritisControl cohortNeuromyelitis optica spectrum disorderSurface AgOptica spectrum disorderMyelin oligodendrocyte glycoproteinHealthy donor seraType 1 diabetesB cell toleranceNeurologic autoimmunitySLE patientsLupus erythematosusSuch autoantibodiesT1D patientsAutoimmune diseasesHigh titer AbsOligodendrocyte glycoproteinSystemic autoimmunityDonor seraLarge cohortRare caseAutoantibodiesAquaporin-4Cell tolerance