2021
Developmental partitioning of SYK and ZAP70 prevents autoimmunity and cancer
Sadras T, Martin M, Kume K, Robinson ME, Saravanakumar S, Lenz G, Chen Z, Song JY, Siddiqi T, Oksa L, Knapp AM, Cutler J, Cosgun KN, Klemm L, Ecker V, Winchester J, Ghergus D, Soulas-Sprauel P, Kiefer F, Heisterkamp N, Pandey A, Ngo V, Wang L, Jumaa H, Buchner M, Ruland J, Chan WC, Meffre E, Martin T, Müschen M. Developmental partitioning of SYK and ZAP70 prevents autoimmunity and cancer. Molecular Cell 2021, 81: 2094-2111.e9. PMID: 33878293, PMCID: PMC8239336, DOI: 10.1016/j.molcel.2021.03.043.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntigens, CD19AutoimmunityB-LymphocytesCalciumCell DifferentiationCell Transformation, NeoplasticEnzyme ActivationHumansImmune ToleranceLymphoma, B-CellMiceModels, GeneticNeoplasm ProteinsNeoplasmsNFATC Transcription FactorsPhosphatidylinositol 3-KinasesProtein BindingReceptors, Antigen, B-CellSignal TransductionSyk KinaseZAP-70 Protein-Tyrosine Kinase
2020
IFITM3 functions as a PIP3 scaffold to amplify PI3K signalling in B cells
Lee J, Robinson ME, Ma N, Artadji D, Ahmed MA, Xiao G, Sadras T, Deb G, Winchester J, Cosgun KN, Geng H, Chan LN, Kume K, Miettinen TP, Zhang Y, Nix MA, Klemm L, Chen CW, Chen J, Khairnar V, Wiita AP, Thomas-Tikhonenko A, Farzan M, Jung JU, Weinstock DM, Manalis SR, Diamond MS, Vaidehi N, Müschen M. IFITM3 functions as a PIP3 scaffold to amplify PI3K signalling in B cells. Nature 2020, 588: 491-497. PMID: 33149299, PMCID: PMC8087162, DOI: 10.1038/s41586-020-2884-6.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntigens, CD19B-LymphocytesCell Transformation, NeoplasticFemaleGerminal CenterHumansIntegrinsMembrane MicrodomainsMembrane ProteinsMiceMice, Inbred C57BLMice, Inbred NODModels, MolecularPhosphatidylinositol 3-KinasesPhosphatidylinositol PhosphatesPhosphorylationReceptors, Antigen, B-CellRNA-Binding ProteinsSignal TransductionConceptsPI3KCell leukemiaAntiviral effector functionsAntigen-specific antibodiesInterferon-induced transmembrane proteinsIFITM3 functionDevelopment of leukemiaCell surfacePoor outcomeOncogenic PI3KClinical cohortEffector functionsGerminal centersMouse modelB cellsExpression of IFITM3Malignant transformationAccumulation of PIP3PI3K signalsCell receptorNormal numbersLeukemiaDefective expressionEndosomal proteinIFITM3
2019
Histone H3 trimethylation at lysine 36 guides m6A RNA modification co-transcriptionally
Huang H, Weng H, Zhou K, Wu T, Zhao BS, Sun M, Chen Z, Deng X, Xiao G, Auer F, Klemm L, Wu H, Zuo Z, Qin X, Dong Y, Zhou Y, Qin H, Tao S, Du J, Liu J, Lu Z, Yin H, Mesquita A, Yuan CL, Hu YC, Sun W, Su R, Dong L, Shen C, Li C, Qing Y, Jiang X, Wu X, Sun M, Guan JL, Qu L, Wei M, Müschen M, Huang G, He C, Yang J, Chen J. Histone H3 trimethylation at lysine 36 guides m6A RNA modification co-transcriptionally. Nature 2019, 567: 414-419. PMID: 30867593, PMCID: PMC6438714, DOI: 10.1038/s41586-019-1016-7.Peer-Reviewed Original ResearchConceptsM6A methyltransferase complexHistone H3 trimethylationH3 trimethylationHistone modificationsImportant post-transcriptional mechanismMouse embryonic stem cellsGene expression regulationRNA polymerase IIPrevalent internal modificationPost-transcriptional mechanismsEmbryonic stem cellsN6-methyladenosine (m<sup>6</sup>A) mRNA modificationM6A depositionTranscription elongationNascent RNAMethyltransferase complexPolymerase IIExpression regulationGene expression1RNA methylationMRNA modificationMETTL14 knockdownH3K36me3M6A modificationCell stemness
2018
B-Cell-Specific Diversion of Glucose Carbon Utilization Reveals a Unique Vulnerability in B Cell Malignancies
Xiao G, Chan LN, Klemm L, Braas D, Chen Z, Geng H, Zhang QC, Aghajanirefah A, Cosgun KN, Sadras T, Lee J, Mirzapoiazova T, Salgia R, Ernst T, Hochhaus A, Jumaa H, Jiang X, Weinstock DM, Graeber TG, Müschen M. B-Cell-Specific Diversion of Glucose Carbon Utilization Reveals a Unique Vulnerability in B Cell Malignancies. Cell 2018, 173: 470-484.e18. PMID: 29551267, PMCID: PMC6284818, DOI: 10.1016/j.cell.2018.02.048.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsB-LymphocytesCarbonCell Line, TumorCell SurvivalGlucoseGlucosephosphate DehydrogenaseGlycolysisHumansIkaros Transcription FactorMiceMice, Inbred C57BLMice, Inbred NODOxidative StressPAX5 Transcription FactorPentose Phosphate PathwayPrecursor Cell Lymphoblastic Leukemia-LymphomaProtein Phosphatase 2Proto-Oncogene Proteins c-bcl-2Transcription, GeneticConceptsPentose phosphate pathwayCarbon utilizationSerine/threonine protein phosphatase 2AB-cell transcription factor PAX5Transcription factor Pax5Favor of glycolysisSmall molecule inhibitionPhosphatase 2ATranscriptional repressionRedox homeostasisOncogenic transformationTumor suppressorMolecule inhibitionPP2AGenetic studiesPhosphate pathwayB cell activationEssential roleB-cell malignanciesCell malignanciesB cellsAntioxidant protectionOxidative stressB-cell tumorsCell activation
2015
Erk Negative Feedback Control Enables Pre-B Cell Transformation and Represents a Therapeutic Target in Acute Lymphoblastic Leukemia
Shojaee S, Caeser R, Buchner M, Park E, Swaminathan S, Hurtz C, Geng H, Chan LN, Klemm L, Hofmann WK, Qiu YH, Zhang N, Coombes KR, Paietta E, Molkentin J, Koeffler HP, Willman CL, Hunger SP, Melnick A, Kornblau SM, Müschen M. Erk Negative Feedback Control Enables Pre-B Cell Transformation and Represents a Therapeutic Target in Acute Lymphoblastic Leukemia. Cancer Cell 2015, 28: 114-128. PMID: 26073130, PMCID: PMC4565502, DOI: 10.1016/j.ccell.2015.05.008.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntineoplastic AgentsCell Transformation, NeoplasticDNA-Binding ProteinsDual Specificity Phosphatase 6Host Cell Factor C1HumansIntracellular Signaling Peptides and ProteinsMAP Kinase Signaling SystemMembrane ProteinsMiceMice, TransgenicMolecular Sequence DataPrecursor Cell Lymphoblastic Leukemia-LymphomaPrognosisProtein Serine-Threonine KinasesSmall Molecule LibrariesTranscription FactorsConceptsAcute lymphoblastic leukemiaLymphoblastic leukemiaPatient-derived preNegative feedback regulationPre-B cell cloneCell deathImmediate cell deathMouse modelSmall molecule inhibitorsTherapeutic targetAcute activationMalignant transformationCell clonesFeedback regulationOncogenic signalingMolecule inhibitorsStrong activationLeukemiaDeathERKPre-B-cell transformationCell transformationActivationOncogenic transformationVast majorityMechanisms of clonal evolution in childhood acute lymphoblastic leukemia
Swaminathan S, Klemm L, Park E, Papaemmanuil E, Ford A, Kweon SM, Trageser D, Hasselfeld B, Henke N, Mooster J, Geng H, Schwarz K, Kogan SC, Casellas R, Schatz DG, Lieber MR, Greaves MF, Müschen M. Mechanisms of clonal evolution in childhood acute lymphoblastic leukemia. Nature Immunology 2015, 16: 766-774. PMID: 25985233, PMCID: PMC4475638, DOI: 10.1038/ni.3160.Peer-Reviewed Original ResearchMeSH KeywordsAdolescentAnimalsAntibody DiversityB-LymphocytesChildChild, PreschoolClonal EvolutionCytidine DeaminaseDNA-Binding ProteinsFemaleFlow CytometryHomeodomain ProteinsHumansImmunoblottingInfantMaleMice, Inbred NODMice, KnockoutMice, SCIDMice, TransgenicMicroscopy, FluorescencePrecursor Cell Lymphoblastic Leukemia-LymphomaPrecursor Cells, B-LymphoidReverse Transcriptase Polymerase Chain ReactionTumor Cells, CulturedSignalling thresholds and negative B-cell selection in acute lymphoblastic leukaemia
Chen Z, Shojaee S, Buchner M, Geng H, Lee JW, Klemm L, Titz B, Graeber TG, Park E, Tan YX, Satterthwaite A, Paietta E, Hunger SP, Willman CL, Melnick A, Loh ML, Jung JU, Coligan JE, Bolland S, Mak TW, Limnander A, Jumaa H, Reth M, Weiss A, Lowell CA, Müschen M. Signalling thresholds and negative B-cell selection in acute lymphoblastic leukaemia. Nature 2015, 521: 357-361. PMID: 25799995, PMCID: PMC4441554, DOI: 10.1038/nature14231.Peer-Reviewed Original ResearchMeSH KeywordsAmino Acid MotifsAnimalsAntigens, CDB-LymphocytesCell DeathCell Line, TumorCell Transformation, NeoplasticDisease Models, AnimalDrug Resistance, NeoplasmEnzyme ActivationFemaleFusion Proteins, bcr-ablGene DeletionHumansInositol Polyphosphate 5-PhosphatasesIntracellular Signaling Peptides and ProteinsMiceMice, Inbred NODMice, SCIDPhosphatidylinositol-3,4,5-Trisphosphate 5-PhosphatasesPhosphoric Monoester HydrolasesPlatelet Endothelial Cell Adhesion Molecule-1Precursor Cell Lymphoblastic Leukemia-LymphomaPrecursor Cells, B-LymphoidProtein Tyrosine Phosphatase, Non-Receptor Type 6Protein-Tyrosine KinasesReceptors, Antigen, B-CellReceptors, ImmunologicSignal TransductionSyk KinaseTyrosineXenograft Model Antitumor AssaysIdentification of FOXM1 as a therapeutic target in B-cell lineage acute lymphoblastic leukaemia
Buchner M, Park E, Geng H, Klemm L, Flach J, Passegué E, Schjerven H, Melnick A, Paietta E, Kopanja D, Raychaudhuri P, Müschen M. Identification of FOXM1 as a therapeutic target in B-cell lineage acute lymphoblastic leukaemia. Nature Communications 2015, 6: 6471. PMID: 25753524, PMCID: PMC4366523, DOI: 10.1038/ncomms7471.Peer-Reviewed Original ResearchMeSH KeywordsAdultAnimalsAntineoplastic AgentsB-LymphocytesCell ProliferationCell SurvivalChildClinical Trials as TopicCyclin-Dependent Kinase Inhibitor p16Drug Resistance, NeoplasmForkhead Box Protein M1Forkhead Box Protein O3Forkhead Transcription FactorsGene Expression Regulation, LeukemicHumansMicePeptidesPrecursor Cell Lymphoblastic Leukemia-LymphomaSignal TransductionSurvival AnalysisThiostreptonXenograft Model Antitumor AssaysConceptsAcute lymphoblastic leukemiaLymphoblastic leukemiaTherapeutic targetB-cell lineage acute lymphoblastic leukemiaFOXM1 levelsAggressive clinical coursePre-B cell receptor checkpointNovel therapeutic targetB cell populationsNormal B cell populationsClinical coursePoor outcomeCure rateNormal B cell developmentFOXM1 inhibitionB cell developmentDrug resistanceFoxm1 deletionFOXM1Colony formationPatientsLeukemiaCell survivalPrognosisTranscriptional inactivation
2011
BCL6 enables Ph+ acute lymphoblastic leukaemia cells to survive BCR–ABL1 kinase inhibition
Duy C, Hurtz C, Shojaee S, Cerchietti L, Geng H, Swaminathan S, Klemm L, Kweon SM, Nahar R, Braig M, Park E, Kim YM, Hofmann WK, Herzog S, Jumaa H, Koeffler HP, Yu JJ, Heisterkamp N, Graeber TG, Wu H, Ye BH, Melnick A, Müschen M. BCL6 enables Ph+ acute lymphoblastic leukaemia cells to survive BCR–ABL1 kinase inhibition. Nature 2011, 473: 384-388. PMID: 21593872, PMCID: PMC3597744, DOI: 10.1038/nature09883.Peer-Reviewed Original ResearchMeSH KeywordsADP-Ribosylation Factor 1AnimalsCell SurvivalDNA-Binding ProteinsDrug Resistance, NeoplasmFusion Proteins, bcr-ablGene Expression Regulation, NeoplasticHumansMiceMice, Inbred NODMice, SCIDPrecursor Cell Lymphoblastic Leukemia-LymphomaProtein Kinase InhibitorsProto-Oncogene Proteins c-bcl-6Transcription, GeneticTumor Suppressor Protein p53ConceptsTyrosine kinase inhibitorsAcute lymphoblastic leukemia cellsBCR-ABL1 mutationsLymphoblastic leukemia cellsDrug resistanceLeukemia cellsLeukemia-initiating cellsXenograft modelBCR-ABL1Anticancer responseTargeted inhibitionDual inhibitionKinase inhibitorsOncogene withdrawalCancer therapyBCL6Kinase inhibitionLeukemiaInhibitionCellsTherapyMutationsUpregulation