2020
IL-18BP is a secreted immune checkpoint and barrier to IL-18 immunotherapy
Zhou T, Damsky W, Weizman OE, McGeary MK, Hartmann KP, Rosen CE, Fischer S, Jackson R, Flavell RA, Wang J, Sanmamed MF, Bosenberg MW, Ring AM. IL-18BP is a secreted immune checkpoint and barrier to IL-18 immunotherapy. Nature 2020, 583: 609-614. PMID: 32581358, PMCID: PMC7381364, DOI: 10.1038/s41586-020-2422-6.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsCD8-Positive T-LymphocytesDisease Models, AnimalFemaleHepatocyte Nuclear Factor 1-alphaHistocompatibility Antigens Class IHumansImmunotherapyIntercellular Signaling Peptides and ProteinsInterleukin-18Kaplan-Meier EstimateKiller Cells, NaturalLymphocytes, Tumor-InfiltratingMaleMiceNeoplasmsReceptors, Interleukin-18Stem CellsTumor MicroenvironmentConceptsIL-18IL-18BPT cellsAnti-PD-1 resistant tumorsWild-type IL-18Potent anti-tumor effectsMajor histocompatibility complex class IIL-18 pathwayIL-18 therapyInterleukin-18 pathwayMajor therapeutic barrierStem-like TCF1Anti-tumor immunityTumor-infiltrating lymphocytesNatural killer cellsRecombinant IL-18Histocompatibility complex class IAnti-tumor effectsComplex class IAnti-tumor activityMouse tumor modelsModern immunotherapyPrecursor CD8Effector CD8Exhausted CD8
2018
PD‐L1 methylation regulates PD‐L1 expression and is associated with melanoma survival
Micevic G, Thakral D, McGeary M, Bosenberg M. PD‐L1 methylation regulates PD‐L1 expression and is associated with melanoma survival. Pigment Cell & Melanoma Research 2018, 32: 435-440. PMID: 30343532, PMCID: PMC6475614, DOI: 10.1111/pcmr.12745.Peer-Reviewed Original ResearchConceptsPD-L1 expressionDNA methylationPD-1/PD-L1 immune checkpointIndependent survival prognostic factorPD-L1 promoter methylationPD-L1 immune checkpointSurvival prognostic factorsPD-L1 promoterPromoter DNA methylationOverall survivalImmune checkpointsPrognostic factorsMelanoma patientsMelanoma survivalEpigenetic mechanismsTranscriptional phenotypeClinical importanceMelanomaCpG lociMethylationPromoter methylationSurvivalTherapeutic applicationsExpressionPatients
2016
DNMT3b Modulates Melanoma Growth by Controlling Levels of mTORC2 Component RICTOR
Micevic G, Muthusamy V, Damsky W, Theodosakis N, Liu X, Meeth K, Wingrove E, Santhanakrishnan M, Bosenberg M. DNMT3b Modulates Melanoma Growth by Controlling Levels of mTORC2 Component RICTOR. Cell Reports 2016, 14: 2180-2192. PMID: 26923591, PMCID: PMC4785087, DOI: 10.1016/j.celrep.2016.02.010.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsCarrier ProteinsCell Line, TumorCell ProliferationDNA (Cytosine-5-)-MethyltransferasesDNA MethylationDown-RegulationGene Expression Regulation, NeoplasticHumansMechanistic Target of Rapamycin Complex 2Melanoma, ExperimentalMice, 129 StrainMice, Inbred C57BLMice, NudeMicroRNAsMultiprotein ComplexesNeoplasm TransplantationProportional Hazards ModelsRapamycin-Insensitive Companion of mTOR ProteinRNA InterferenceSkin NeoplasmsTOR Serine-Threonine KinasesTumor BurdenConceptsMelanoma formationPotential therapeutic targetMiR-196b expressionMouse melanoma modelPro-tumorigenic roleMTORC2 component RictorMelanoma growthTherapeutic targetMelanoma modelLoss of RictorHuman melanomaCancer typesTumor cellsMelanomaSpecific signaling pathwaysMTORC2 signalingSignaling pathwaysTurn preventsMiR-196b promoterDNA methyltransferase DNMT3BRictorControlling LevelsDNMT3BMethyltransferase DNMT3BCancer
2015
Genomic Classification of Cutaneous Melanoma
Network T, Akbani R, Akdemir K, Aksoy B, Albert M, Ally A, Amin S, Arachchi H, Arora A, Auman J, Ayala B, Baboud J, Balasundaram M, Balu S, Barnabas N, Bartlett J, Bartlett P, Bastian B, Baylin S, Behera M, Belyaev D, Benz C, Bernard B, Beroukhim R, Bir N, Black A, Bodenheimer T, Boice L, Boland G, Bono R, Bootwalla M, Bosenberg M, Bowen J, Bowlby R, Bristow C, Brockway-Lunardi L, Brooks D, Brzezinski J, Bshara W, Buda E, Burns W, Butterfield Y, Button M, Calderone T, Cappellini G, Carter C, Carter S, Cherney L, Cherniack A, Chevalier A, Chin L, Cho J, Cho R, Choi Y, Chu A, Chudamani S, Cibulskis K, Ciriello G, Clarke A, Coons S, Cope L, Crain D, Curley E, Danilova L, D’Atri S, Davidsen T, Davies M, Delman K, Demchok J, Deng Q, Deribe Y, Dhalla N, Dhir R, DiCara D, Dinikin M, Dubina M, Ebrom J, Egea S, Eley G, Engel J, Eschbacher J, Fedosenko K, Felau I, Fennell T, Ferguson M, Fisher S, Flaherty K, Frazer S, Frick J, Fulidou V, Gabriel S, Gao J, Gardner J, Garraway L, Gastier-Foster J, Gaudioso C, Gehlenborg N, Genovese G, Gerken M, Gershenwald J, Getz G, Gomez-Fernandez C, Gribbin T, Grimsby J, Gross B, Guin R, Gutschner T, Hadjipanayis A, Halaban R, Hanf B, Haussler D, Haydu L, Hayes D, Hayward N, Heiman D, Herbert L, Herman J, Hersey P, Hoadley K, Hodis E, Holt R, Hoon D, Hoppough S, Hoyle A, Huang F, Huang M, Huang S, Hutter C, Ibbs M, Iype L, Jacobsen A, Jakrot V, Janning A, Jeck W, Jefferys S, Jensen M, Jones C, Jones S, Ju Z, Kakavand H, Kang H, Kefford R, Khuri F, Kim J, Kirkwood J, Klode J, Korkut A, Korski K, Krauthammer M, Kucherlapati R, Kwong L, Kycler W, Ladanyi M, Lai P, Laird P, Lander E, Lawrence M, Lazar A, Łaźniak R, Lee D, Lee J, Lee J, Lee K, Lee S, Lee W, Leporowska E, Leraas K, Li H, Lichtenberg T, Lichtenstein L, Lin P, Ling S, Liu J, Liu O, Liu W, Long G, Lu Y, Ma, Ma Y, Mackiewicz A, Mahadeshwar H, Malke J, Mallery D, Manikhas G, Mann G, Marra M, Matejka B, Mayo M, Mehrabi S, Meng S, Meyerson M, Mieczkowski P, Miller J, Miller M, Mills G, Moiseenko F, Moore R, Morris S, Morrison C, Morton D, Moschos S, Mose L, Muller F, Mungall A, Murawa D, Murawa P, Murray B, Nezi L, Ng S, Nicholson D, Noble M, Osunkoya A, Owonikoko T, Ozenberger B, Pagani E, Paklina O, Pantazi A, Parfenov M, Parfitt J, Park P, Park W, Parker J, Passarelli F, Penny R, Perou C, Pihl T, Potapova O, Prieto V, Protopopov A, Quinn M, Radenbaugh A, Rai K, Ramalingam S, Raman A, Ramirez N, Ramirez R, Rao U, Rathmell W, Ren X, Reynolds S, Roach J, Robertson A, Ross M, Roszik J, Russo G, Saksena G, Saller C, Samuels Y, Sander C, Sander C, Sandusky G, Santoso N, Saul M, Saw R, Schadendorf D, Schein J, Schultz N, Schumacher S, Schwallier C, Scolyer R, Seidman J, Sekhar P, Sekhon H, Senbabaoglu Y, Seth S, Shannon K, Sharpe S, Sharpless N, Shaw K, Shelton C, Shelton T, Shen R, Sheth M, Shi Y, Shiau C, Shmulevich I, Sica G, Simons J, Sinha R, Sipahimalani P, Sofia H, Soloway M, Song X, Sougnez C, Spillane A, Spychała A, Stretch J, Stuart J, Suchorska W, Sucker A, Sumer S, Sun Y, Synott M, Tabak B, Tabler T, Tam A, Tan D, Tang J, Tarnuzzer R, Tarvin K, Tatka H, Taylor B, Teresiak M, Thiessen N, Thompson J, Thorne L, Thorsson V, Trent J, Triche T, Tsai K, Tsou P, Van Den Berg D, Van Allen E, Veluvolu U, Verhaak R, Voet D, Voronina O, Walter V, Walton J, Wan Y, Wang Y, Wang Z, Waring S, Watson I, Weinhold N, Weinstein J, Weisenberger D, White P, Wilkerson M, Wilmott J, Wise L, Wiznerowicz M, Woodman S, Wu C, Wu C, Wu J, Wu Y, Xi R, Xu A, Yang D, Yang L, Yang L, Zack T, Zenklusen J, Zhang H, Zhang J, Zhang W, Zhao X, Zhu J, Zhu K, Zimmer L, Zmuda E, Zou L. Genomic Classification of Cutaneous Melanoma. Cell 2015, 161: 1681-1696. PMID: 26091043, PMCID: PMC4580370, DOI: 10.1016/j.cell.2015.05.044.Peer-Reviewed Original ResearchConceptsGenomic classificationProtein-based analysesComplex structural rearrangementsImmune gene expressionMutant RASGene expressionIntegrative analysisFocal amplificationGenomic alterationsStructural rearrangementsProtein expressionMutant BRAFCell markersExpressionGenesRNADNAMutationsCutaneous melanomaKIT mutationsNF1RASRearrangementEnrichmentLandscapemTORC1 Activation Blocks Braf V600E -Induced Growth Arrest but Is Insufficient for Melanoma Formation
Damsky W, Micevic G, Meeth K, Muthusamy V, Curley DP, Santhanakrishnan M, Erdelyi I, Platt JT, Huang L, Theodosakis N, Zaidi MR, Tighe S, Davies MA, Dankort D, McMahon M, Merlino G, Bardeesy N, Bosenberg M. mTORC1 Activation Blocks Braf V600E -Induced Growth Arrest but Is Insufficient for Melanoma Formation. Cancer Cell 2015, 27: 41-56. PMID: 25584893, PMCID: PMC4295062, DOI: 10.1016/j.ccell.2014.11.014.Peer-Reviewed Original ResearchMeSH KeywordsAMP-Activated Protein KinasesAnimalsCell Line, TumorCell ProliferationCyclin-Dependent Kinase Inhibitor p16HumansMechanistic Target of Rapamycin Complex 1Mechanistic Target of Rapamycin Complex 2MelanocytesMelanoma, ExperimentalMiceMicroRNAsMolecular Sequence DataMultiprotein ComplexesMutationNevusProtein Serine-Threonine KinasesProto-Oncogene Proteins B-rafSignal TransductionSkin NeoplasmsTOR Serine-Threonine KinasesConceptsMelanoma formationGrowth arrestStable growth arrestMTORC2/AktSTK11 lossCDKN2A lossAkt activationIGF1R signalingMice resultsActivationArrestMTORC2Nevus developmentMTORC1/2SignalingAktMelanocytic nevus developmentMelanomagenesisMTORProgressionCDKN2AMelanocytesInactivationUpregulationComplete progression
2011
β-Catenin Signaling Controls Metastasis in Braf-Activated Pten-Deficient Melanomas
Damsky WE, Curley DP, Santhanakrishnan M, Rosenbaum LE, Platt JT, Rothberg BE, Taketo MM, Dankort D, Rimm DL, McMahon M, Bosenberg M. β-Catenin Signaling Controls Metastasis in Braf-Activated Pten-Deficient Melanomas. Cancer Cell 2011, 20: 741-754. PMID: 22172720, PMCID: PMC3241928, DOI: 10.1016/j.ccr.2011.10.030.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntigens, DifferentiationBenzamidesBeta CateninCell Transformation, NeoplasticColorectal NeoplasmsEnzyme ActivationGene Knockdown TechniquesHumansImatinib MesylateKaplan-Meier EstimateLung NeoplasmsLymphatic MetastasisMelanocytesMelanoma, ExperimentalMiceMice, 129 StrainMice, Inbred C57BLMice, TransgenicPhosphorylationPiperazinesProtein StabilityProto-Oncogene Proteins B-rafProto-Oncogene Proteins c-aktPTEN PhosphohydrolasePyrimidinesSignal TransductionSkin NeoplasmsSplenic NeoplasmsTranscription, GeneticTumor Cells, CulturedConceptsΒ-catenin levelsPI3K/AktLymph nodesMetastatic tumorsFrequent metastasisTumor differentiationMalignant melanomaMAPK/ERKMelanoma metastasesMouse modelControl metastasisHuman melanomaMelanomaMetastasisΒ-catenin stabilizationPTEN lossCentral mediatorMetastasis regulatorsΒ-cateninSpecific changesFunctional implicationsWntLung
2001
Telomere dysfunction and evolution of intestinal carcinoma in mice and humans
Rudolph K, Millard M, Bosenberg M, DePinho R. Telomere dysfunction and evolution of intestinal carcinoma in mice and humans. Nature Genetics 2001, 28: 155-159. PMID: 11381263, DOI: 10.1038/88871.Peer-Reviewed Original ResearchConceptsHuman intestinal neoplasiaProgression of mouseTelomerase activationHuman colorectal carcinogenesisTelomere dysfunctionInitiated lesionsIntestinal carcinomaColorectal carcinogenesisIntestinal neoplasiaHuman colorectalDysfunctionAdvanced stageMalignant transformationTumor progressionChromosomal instabilityColon carcinomaCarcinoma transitionMacroscopic adenomasTransient telomere dysfunctionEarly carcinogenesisCancer initiationHuman cancersTelomerase activityCarcinomaDifferential effects
1993
Juxtacrine cell signaling molecules
Bosenberg M, Massagué J. Juxtacrine cell signaling molecules. Current Opinion In Cell Biology 1993, 5: 832-838. PMID: 7694603, DOI: 10.1016/0955-0674(93)90032-l.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsCell AdhesionCell Adhesion MoleculesCell MembraneDrosophila ProteinsEpidermal Growth FactorEye ProteinsGrowth SubstancesHematopoietic Cell Growth FactorsHumansMembrane GlycoproteinsNerve Growth FactorsReceptors, Cell SurfaceReceptors, PeptideSignal TransductionStem Cell FactorTumor Necrosis Factor-alphaConceptsCell adhesion moleculeMembrane-anchored growth factorsIntimate cell-cell contactCell-cell contactDiffusible growth factorsAdhesion moleculesGrowth factorTissue developmentIntercellular communicationJuxtacrine interactionsJuxtacrine stimulationClass of moleculesAdjacent cellsCellsRapid progressMoleculesReceptorsBiologistsMaintenanceIdentification