Featured Publications
Neuregulin-activated ERBB4 induces the SREBP-2 cholesterol biosynthetic pathway and increases low-density lipoprotein uptake
Haskins JW, Zhang S, Means RE, Kelleher JK, Cline GW, Canfrán-Duque A, Suárez Y, Stern DF. Neuregulin-activated ERBB4 induces the SREBP-2 cholesterol biosynthetic pathway and increases low-density lipoprotein uptake. Science Signaling 2015, 8: ra111. PMID: 26535009, PMCID: PMC4666504, DOI: 10.1126/scisignal.aac5124.Peer-Reviewed Original ResearchMeSH KeywordsCell Line, TumorCholesterolFemaleHumansHydroxymethylglutaryl CoA ReductasesLipoproteins, LDLMechanistic Target of Rapamycin Complex 1Multiprotein ComplexesNeuregulin-1Proto-Oncogene Proteins c-aktReceptor, ErbB-4Receptors, LDLSterol Regulatory Element Binding Protein 2TOR Serine-Threonine KinasesConceptsIntracellular domainEGFR family membersLow-density lipoprotein uptakeCholesterol biosynthesisSREBP target genesRapamycin complex 1ErbB4 intracellular domainSite-1 proteaseCholesterol biosynthesis genesSoluble intracellular domainCholesterol biosynthetic pathwayActivation of ErbB4Mammary epithelial cellsInhibition of AktSterol regulatory elementBiosynthesis genesLipoprotein uptakeRegulatory elementsBiosynthetic pathwayTarget genesDevelopmental processesMetabolic remodelingMature formNeuregulin-1Cellular membranesPhosphoproteomic Screen Identifies Potential Therapeutic Targets in Melanoma
Tworkoski K, Singhal G, Szpakowski S, Zito CI, Bacchiocchi A, Muthusamy V, Bosenberg M, Krauthammer M, Halaban R, Stern DF. Phosphoproteomic Screen Identifies Potential Therapeutic Targets in Melanoma. Molecular Cancer Research 2011, 9: 801-812. PMID: 21521745, PMCID: PMC3117976, DOI: 10.1158/1541-7786.mcr-10-0512.Peer-Reviewed Original ResearchMeSH KeywordsApoptosisCell Line, TumorCell MovementCell ProliferationErbB ReceptorsGene Expression Regulation, NeoplasticGene Knockdown TechniquesHEK293 CellsHumansInfant, NewbornMelanocytesMelanomaPhosphoproteinsPhosphorylationProteomicsReceptor Protein-Tyrosine KinasesReceptor, IGF Type 2RNA, Small InterferingSignal TransductionSkin NeoplasmsSTAT3 Transcription FactorConceptsTherapeutic targetReceptor tyrosine kinasesMelanoma cellsPotential therapeutic targetIdentifies potential therapeutic targetsActive receptor tyrosine kinasesTyrosine kinaseMelanoma cell migrationReceptor expressionBreast cancerAxl knockdownAutocrine circuitTherapeutic interventionsCancer subtypesReceptor tyrosine kinase activationTyrosine kinase activationNovel targetActivated receptorsAxlRNA knockdownMelanomaCell migrationHER3KnockdownIGF1RGenotype-Selective Combination Therapies for Melanoma Identified by High-Throughput Drug Screening
Held MA, Langdon CG, Platt JT, Graham-Steed T, Liu Z, Chakraborty A, Bacchiocchi A, Koo A, Haskins JW, Bosenberg MW, Stern DF. Genotype-Selective Combination Therapies for Melanoma Identified by High-Throughput Drug Screening. Cancer Discovery 2013, 3: 52-67. PMID: 23239741, PMCID: PMC3546137, DOI: 10.1158/2159-8290.cd-12-0408.Peer-Reviewed Original ResearchConceptsMutant BRAF melanomaCyclin-dependent kinase inhibitorBRAF melanomaSmall molecule inhibitorsHigh-throughput drug screeningDrug screeningEGF receptorCombination therapyDrug combinationsMelanoma culturesContext of genotypePairwise combinationsResistance phenotypeCombinatorial drug screeningUnique treatment regimensCombination of statinsVivo xenograftsKinase inhibitorsMutant BRAFMutationsEfficacious drug combinationsPartial responseTreatment regimensRAS mutationsBRAF mutations
2018
Inhibition of isoprenylation synergizes with MAPK blockade to prevent growth in treatment‐resistant melanoma, colorectal, and lung cancer
Theodosakis N, Langdon CG, Micevic G, Krykbaeva I, Means RE, Stern DF, Bosenberg MW. Inhibition of isoprenylation synergizes with MAPK blockade to prevent growth in treatment‐resistant melanoma, colorectal, and lung cancer. Pigment Cell & Melanoma Research 2018, 32: 292-302. PMID: 30281931, PMCID: PMC6590911, DOI: 10.1111/pcmr.12742.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsCell Line, TumorCell ProliferationColorectal NeoplasmsDrug Resistance, NeoplasmDrug SynergismHumansHydroxymethylglutaryl-CoA Reductase InhibitorsLung NeoplasmsMaleMelanomaMevalonic AcidMice, NudeMitogen-Activated Protein KinasesPrenylationProtein Kinase InhibitorsProtein Processing, Post-TranslationalSignal TransductionConceptsUseful adjunctive therapyHMG-CoA reductase inhibitorsAnti-tumor effectsAdjunctive therapyInhibition of isoprenylationLung cancerMEK inhibitionReductase inhibitorsMAPK blockadeDriver mutationsAdditional studiesStatinsTherapyMelanomaTumorsVemurafenibMAPK pathwayDownstream metabolitesInhibitionMAPKAdjunctiveColorectalSelumetinibBlockadeCancerKeeping Tumors Out of the MAPK Fitness Zone
Stern DF. Keeping Tumors Out of the MAPK Fitness Zone. Cancer Discovery 2018, 8: 20-23. PMID: 29311225, DOI: 10.1158/2159-8290.cd-17-1243.Peer-Reviewed Original ResearchMeSH KeywordsCell DeathCell Line, TumorHumansMAP Kinase Signaling SystemProtein Kinase InhibitorsProto-Oncogene Proteins B-rafSignal TransductionConceptsMAPK-targeted therapiesGreater fitnessMAPK signalingTumor cell subclonesMAPK pathwayCell deathERK inhibitorDNA damageTumor cell deathFitness barriersCell subclonesNew therapeutic approachesInhibitor withdrawalResistant clonesTherapeutic approachesTriple combinationMEKSignalingClonesSubclonesFitnessPathwayPatients
2017
p90RSK Blockade Inhibits Dual BRAF and MEK Inhibitor-Resistant Melanoma by Targeting Protein Synthesis
Theodosakis N, Micevic G, Langdon CG, Ventura A, Means R, Stern DF, Bosenberg MW. p90RSK Blockade Inhibits Dual BRAF and MEK Inhibitor-Resistant Melanoma by Targeting Protein Synthesis. Journal Of Investigative Dermatology 2017, 137: 2187-2196. PMID: 28599981, PMCID: PMC6342201, DOI: 10.1016/j.jid.2016.12.033.Peer-Reviewed Original ResearchConceptsProtein synthesisRibosomal S6 kinase (RSK) familyPatient-derived melanoma cell linesDifferential protein expressionReverse phase protein arrayPhase protein arrayTranslation complexesKinase familyBI-D1870RSK inhibitorsMelanoma cell linesProtein arraysCell proliferationInhibitor treatmentProtein expressionCell linesNew targetsHuman melanoma patientsBRAF inhibitor vemurafenibCombinatorial Screening of Pancreatic Adenocarcinoma Reveals Sensitivity to Drug Combinations Including Bromodomain Inhibitor Plus Neddylation Inhibitor
Langdon CG, Platt JT, Means RE, Iyidogan P, Mamillapalli R, Klein M, Held MA, Lee JW, Koo JS, Hatzis C, Hochster HS, Stern DF. Combinatorial Screening of Pancreatic Adenocarcinoma Reveals Sensitivity to Drug Combinations Including Bromodomain Inhibitor Plus Neddylation Inhibitor. Molecular Cancer Therapeutics 2017, 16: 1041-1053. PMID: 28292938, PMCID: PMC5457712, DOI: 10.1158/1535-7163.mct-16-0794.Peer-Reviewed Original ResearchAdenosine TriphosphateAnimalsAntineoplastic AgentsApoptosisCarcinoma, Pancreatic DuctalCell Line, TumorCell ProliferationDNA DamageDose-Response Relationship, DrugDrug CombinationsDrug Screening Assays, AntitumorDrug SynergismHigh-Throughput Nucleotide SequencingHumansMiceMitochondriaMolecular Targeted TherapyNeoplastic Stem CellsPancreatic NeoplasmsSuperoxidesXenograft Model Antitumor AssaysSystematic Drug Screening Identifies Tractable Targeted Combination Therapies in Triple-Negative Breast Cancer
Wali VB, Langdon CG, Held MA, Platt JT, Patwardhan GA, Safonov A, Aktas B, Pusztai L, Stern DF, Hatzis C. Systematic Drug Screening Identifies Tractable Targeted Combination Therapies in Triple-Negative Breast Cancer. Cancer Research 2017, 77: 566-578. PMID: 27872098, PMCID: PMC5582957, DOI: 10.1158/0008-5472.can-16-1901.Peer-Reviewed Original ResearchConceptsTriple-negative breast cancerTNBC cell linesPairwise drug combinationsClinical translationAggressive diseaseCombination therapyBreast cancerPreclinical proofDrug combinationsCombination treatmentInvestigational drugsSingle agentSensitivity patternCell sensitivityCell linesTherapyApoptotic activityAnticancer activityDownregulated genesMitogenic signalingCrizotinibBlockadeClinicAgentsCancerA Computational Approach for Identifying Synergistic Drug Combinations
Gayvert KM, Aly O, Platt J, Bosenberg MW, Stern DF, Elemento O. A Computational Approach for Identifying Synergistic Drug Combinations. PLOS Computational Biology 2017, 13: e1005308. PMID: 28085880, PMCID: PMC5234777, DOI: 10.1371/journal.pcbi.1005308.Peer-Reviewed Original Research
2016
PMCA2 regulates HER2 protein kinase localization and signaling and promotes HER2-mediated breast cancer
Jeong J, VanHouten JN, Dann P, Kim W, Sullivan C, Yu H, Liotta L, Espina V, Stern DF, Friedman PA, Wysolmerski JJ. PMCA2 regulates HER2 protein kinase localization and signaling and promotes HER2-mediated breast cancer. Proceedings Of The National Academy Of Sciences Of The United States Of America 2016, 113: e282-e290. PMID: 26729871, PMCID: PMC4725473, DOI: 10.1073/pnas.1516138113.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsBreast NeoplasmsCalciumCarcinogenesisCell Line, TumorCell MembraneCell ProliferationCell SurvivalEndocytosisFemaleFluorescent Antibody TechniqueForkhead Box Protein O1Forkhead Transcription FactorsGene Knockdown TechniquesHSP90 Heat-Shock ProteinsHumansImmunoblottingIntracellular SpaceMammary Neoplasms, AnimalMicePlasma Membrane Calcium-Transporting ATPasesProtein BindingProtein TransportReceptor, ErbB-2Signal TransductionSurvival AnalysisConceptsBreast cancerHigh tumor levelsDegradation of HER2Increases Intracellular CalciumMouse mammary tumor virusBreast cancer cellsMammary tumor virusPMCA2 levelsNeu miceTumor levelsFormation of tumorsHER2 levelsIntracellular calciumTherapeutic targetBreast tumorsHER2Milk calciumExpression correlatesCancerHSP 90Mammary glandCancer cellsTumor virusTumorsCalcium
2015
SMAC mimetic Debio 1143 synergizes with taxanes, topoisomerase inhibitors and bromodomain inhibitors to impede growth of lung adenocarcinoma cells
Langdon CG, Wiedemann N, Held MA, Mamillapalli R, Iyidogan P, Theodosakis N, Platt JT, Levy F, Vuagniaux G, Wang S, Bosenberg MW, Stern DF. SMAC mimetic Debio 1143 synergizes with taxanes, topoisomerase inhibitors and bromodomain inhibitors to impede growth of lung adenocarcinoma cells. Oncotarget 2015, 6: 37410-37425. PMID: 26485762, PMCID: PMC4741938, DOI: 10.18632/oncotarget.6138.Peer-Reviewed Original ResearchMeSH KeywordsAdenocarcinomaAdenocarcinoma of LungAnimalsAntineoplastic Combined Chemotherapy ProtocolsApoptosisApoptosis Regulatory ProteinsAzepinesAzocinesBenzhydryl CompoundsCamptothecinCell Line, TumorCell ProliferationDocetaxelDose-Response Relationship, DrugDrug SynergismFemaleHumansIrinotecanLung NeoplasmsMice, Inbred BALB CMice, NudeNF-kappa BPaclitaxelSignal TransductionTaxoidsTime FactorsTopoisomerase InhibitorsTriazolesTumor BurdenXenograft Model Antitumor AssaysConceptsLung adenocarcinoma cellsDebio 1143Adenocarcinoma cellsOngoing clinical trialsNon-canonical NF-κB signalingTopoisomerase inhibitorsLung adenocarcinoma xenograftsNF-κB signalingBromodomain inhibitor JQ1Clinical trialsConventional chemotherapyTumor volumeVivo treatmentAdenocarcinoma xenograftsAnti-apoptotic proteinsSingle agentCaspase-8 expressionVivo growthInhibitor JQ1Tumor cellsPro-apoptotic protein SmacJQ1Cell linesInhibitorsTaxanesThe broad‐spectrum receptor tyrosine kinase inhibitor dovitinib suppresses growth of BRAF‐mutant melanoma cells in combination with other signaling pathway inhibitors
Langdon CG, Held MA, Platt JT, Meeth K, Iyidogan P, Mamillapalli R, Koo AB, Klein M, Liu Z, Bosenberg MW, Stern DF. The broad‐spectrum receptor tyrosine kinase inhibitor dovitinib suppresses growth of BRAF‐mutant melanoma cells in combination with other signaling pathway inhibitors. Pigment Cell & Melanoma Research 2015, 28: 417-430. PMID: 25854919, PMCID: PMC5215495, DOI: 10.1111/pcmr.12376.Peer-Reviewed Original ResearchConceptsBRAF-mutant melanomaBRAF inhibitorsCell linesCombination of dovitinibBRAF inhibitor treatmentBRAF mutant melanoma cellsBRAF inhibitor resistanceColorectal carcinoma cell linesBRAF-mutant melanoma cell linesMelanoma cell linesCarcinoma cell linesMetastatic melanomaEffective therapyWild-type BRAF cellsInhibitor treatmentAgent inhibitsPathway inhibitorDovitinibInhibitor resistanceMelanoma cellsMelanomaSecond agentInhibitorsTreatmentPDK1 and SGK3 Contribute to the Growth of BRAF-Mutant Melanomas and Are Potential Therapeutic Targets
Scortegagna M, Lau E, Zhang T, Feng Y, Sereduk C, Yin H, De SK, Meeth K, Platt JT, Langdon CG, Halaban R, Pellecchia M, Davies MA, Brown K, Stern DF, Bosenberg M, Ronai ZA. PDK1 and SGK3 Contribute to the Growth of BRAF-Mutant Melanomas and Are Potential Therapeutic Targets. Cancer Research 2015, 75: 1399-1412. PMID: 25712345, PMCID: PMC4383687, DOI: 10.1158/0008-5472.can-14-2785.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsBenzoatesBridged Bicyclo Compounds, HeterocyclicCell Line, TumorDrug Screening Assays, AntitumorG1 Phase Cell Cycle CheckpointsHumansImmediate-Early ProteinsIndazolesLymphatic MetastasisMelanomaMice, KnockoutMolecular Targeted TherapyProtein Kinase InhibitorsProtein Serine-Threonine KinasesProto-Oncogene Proteins B-rafPyrimidinesPyruvate Dehydrogenase Acetyl-Transferring KinaseSkinSkin NeoplasmsConceptsPDK1 inhibitionAGC kinase familySynthetic lethal screenCell cycle arrestPhase cell cycle arrestPigmentation genesPDK1 activityG1 phase cell cycle arrestSuppress melanoma growthKinase familyTherapeutic targetMelanoma growthPDK1PTEN genotypePI3KMelanoma developmentPotential therapeutic targetK inhibitionPharmacologic inhibitionDevelopment of melanomaPan-PI3K inhibitionBRAF-mutant melanomaSGK3GenesMelanoma cells
2014
Neuregulin 1–activated ERBB4 interacts with YAP to induce Hippo pathway target genes and promote cell migration
Haskins JW, Nguyen DX, Stern DF. Neuregulin 1–activated ERBB4 interacts with YAP to induce Hippo pathway target genes and promote cell migration. Science Signaling 2014, 7: ra116. PMID: 25492965, PMCID: PMC4648367, DOI: 10.1126/scisignal.2005770.Peer-Reviewed Original ResearchMeSH KeywordsBreast NeoplasmsCell Cycle ProteinsCell Line, TumorCell MovementConnective Tissue Growth FactorErlotinib HydrochlorideFemaleGene Expression Regulation, NeoplasticGene Knockdown TechniquesHippo Signaling PathwayHumansLapatinibMechanotransduction, CellularNeuregulin-1Nuclear ProteinsProtein Kinase InhibitorsProtein Serine-Threonine KinasesQuinazolinesReceptor, ErbB-4Transcription FactorsConceptsIntracellular domainHippo pathway target genesHippo tumor suppressor pathwayCell migrationTranscriptional coactivator YAPCultured mammary epithelial cellsTumor suppressor pathwayPathway target genesSoluble intracellular domainExpression of genesEpidermal growth factor receptor familyMammary epithelial cellsGrowth factor receptor familyNuclear functionsIntramembrane proteolysisCoactivator YAPFactor receptor familyGrowth factor receptorTarget genesYAP activityNeuregulin-1Receptor tyrosine kinase ErbB4Receptor familyMechanosensory pathwayBreast cancer cell linesConvergent and Divergent Cellular Responses by ErbB4 Isoforms in Mammary Epithelial Cells
Wali VB, Haskins JW, Gilmore-Hebert M, Platt JT, Liu Z, Stern DF. Convergent and Divergent Cellular Responses by ErbB4 Isoforms in Mammary Epithelial Cells. Molecular Cancer Research 2014, 12: 1140-1155. PMID: 24829397, PMCID: PMC4728083, DOI: 10.1158/1541-7786.mcr-13-0637.Peer-Reviewed Original ResearchConceptsYAP/Hippo pathwayIsogenic MCF10A cellsMultiple structural isoformsAlternative mRNA splicingDivergent cellular responsesChIP-seq experimentsProteases/protease inhibitorsErbB4 isoformsMammary epithelial cellsAssociation of ErbB4Hippo pathwayMRNA splicingNovel molecular targetsTranscriptional profilingDivergent functionsTranscription factorsCYT-1Signaling activitiesMevalonate pathwayCellular responsesLuminal breast cancer cell linesDiverse biologic activitiesMCF10A cellsCYT-2Intracellular isoformsSignificance of glioma-associated oncogene homolog 1 (GLI1)expression in claudin-low breast cancer and crosstalk with the nuclear factor kappa-light-chain-enhancer of activated B cells (NFκB) pathway
Colavito SA, Zou MR, Yan Q, Nguyen DX, Stern DF. Significance of glioma-associated oncogene homolog 1 (GLI1)expression in claudin-low breast cancer and crosstalk with the nuclear factor kappa-light-chain-enhancer of activated B cells (NFκB) pathway. Breast Cancer Research 2014, 16: 444. PMID: 25252859, PMCID: PMC4303124, DOI: 10.1186/s13058-014-0444-4.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntineoplastic AgentsBreast NeoplasmsCell Line, TumorCell MovementCell ProliferationClaudinsEpithelial-Mesenchymal TransitionFemaleGene ExpressionHeterocyclic Compounds, 2-RingHumansMice, Inbred NODMice, SCIDNeoplasm TransplantationNeoplastic Stem CellsNF-kappa BPromoter Regions, GeneticProtein BindingReceptor Cross-TalkRNA, MessengerSignal TransductionThiazolesTranscription FactorsZinc Finger Protein GLI1ConceptsGlioma-associated oncogene homolog 1Claudin-low cell linesBreast cancer stem cellsCancer stem cellsOncogene homolog 1Gli1 expressionBreast cancerClaudin-low breast cancer subtypeMetastatic breast cancer stem cellsNFκB pathwayCell linesClaudin-low breast cancerActivated B cells (NF-κB) pathwayClaudin-low subtypeHomolog 1Breast cancer subtypesMarkers of EMTB-cell pathwayNFκB subunit p65Stem cellsMesenchymal-like characteristicsPoor prognosisTreatment optionsOrthotopic xenograftsAggressive type
2013
MERTK controls melanoma cell migration and survival and differentially regulates cell behavior relative to AXL
Tworkoski KA, Platt JT, Bacchiocchi A, Bosenberg M, Boggon TJ, Stern DF. MERTK controls melanoma cell migration and survival and differentially regulates cell behavior relative to AXL. Pigment Cell & Melanoma Research 2013, 26: 527-541. PMID: 23617806, PMCID: PMC3918898, DOI: 10.1111/pcmr.12110.Peer-Reviewed Original ResearchMeSH KeywordsAxl Receptor Tyrosine KinaseCdc42 GTP-Binding ProteinCell Line, TumorCell MovementCell ProliferationCell SurvivalC-Mer Tyrosine KinaseCytophotometryGene Expression ProfilingGene Expression Regulation, NeoplasticHEK293 CellsHumansMelanomaNeoplasm MetastasisOligonucleotide Array Sequence AnalysisPhosphorylationProto-Oncogene ProteinsReceptor Protein-Tyrosine KinasesSignal TransductionSkin NeoplasmsConceptsCell migrationCell behaviorMelanoma cellsAkt-dependent mannerShRNA-mediated knockdownDifferential cell behaviorDifferent transcriptional signaturesReceptor tyrosine kinase AXLMelanoma cell migrationMelanoma cell proliferationKinase domainTyrosine kinase AXLCell motilityTranscriptional signatureCell survivalColony formationCell proliferationOverexpression of AxlPossible therapeutic targetMelanoma pathogenesisNovel mutationsMerTKAxlTherapeutic targetMutations
2011
NFBD1/MDC1 Regulates Cav1 and Cav2 Independently of DNA Damage and p53
Wilson KA, Colavito SA, Schulz V, Wakefield PH, Sessa W, Tuck D, Stern DF. NFBD1/MDC1 Regulates Cav1 and Cav2 Independently of DNA Damage and p53. Molecular Cancer Research 2011, 9: 766-781. PMID: 21551225, PMCID: PMC3901581, DOI: 10.1158/1541-7786.mcr-10-0317.Peer-Reviewed Original ResearchMeSH KeywordsAdaptor Proteins, Signal TransducingAnimalsAtaxia Telangiectasia Mutated ProteinsCaveolin 1Caveolin 2Cell AdhesionCell Cycle ProteinsCell Line, TumorCells, CulturedChromatinDNA DamageDNA RepairDNA-Binding ProteinsFibroblastsGene Knockdown TechniquesHistonesHumansMiceNuclear ProteinsProtein Serine-Threonine KinasesRNA, MessengerSignal TransductionTrans-ActivatorsTranscription, GeneticTumor Suppressor Protein p53Tumor Suppressor ProteinsConceptsDNA damage checkpoint signalingNFBD1 knockdownDNA damageNFBD1/MDC1Focal adhesion signalingDNA repair factorsDNA damage responseP53-mediated transcriptionAdhesion signalingCheckpoint signalingRepair factorsResponsive transcriptionDamage responseMitogenic signalingNFBD1DNA repairNovel functionTransactivation activityGene pathwaysAtaxia telangiectasiaMicroarray analysisSimilar phenotypeERK phosphorylationGenesTranscription
2010
Interactions of ErbB4 and Kap1 Connect the Growth Factor and DNA Damage Response Pathways
Gilmore-Hebert M, Ramabhadran R, Stern DF. Interactions of ErbB4 and Kap1 Connect the Growth Factor and DNA Damage Response Pathways. Molecular Cancer Research 2010, 8: 1388-1398. PMID: 20858735, PMCID: PMC3901583, DOI: 10.1158/1541-7786.mcr-10-0042.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsCell Line, TumorChlorocebus aethiopsCOS CellsDNA DamageDown-RegulationErbB ReceptorsGene Expression Regulation, EnzymologicGene Expression Regulation, NeoplasticHumansIntercellular Signaling Peptides and ProteinsProtein BindingReceptor, ErbB-4Repressor ProteinsSignal TransductionSilencer Elements, TranscriptionalSubstrate SpecificityTripartite Motif-Containing Protein 28ConceptsIntracellular domainKinase activityDNA damage response pathwayDamage response pathwayDNA damage responseErbB4 intracellular domainGrowth factor signalingHigh kinase activitySoluble intracellular domainExpression of genesReceptor tyrosine kinasesSuppression of MDM2Candidate interactorsDamage responseResponse pathwaysFactor signalingPlasma membraneMultiple isoformsErbB4 kinase activityTyrosine kinaseDNA damageRole of ErbB4Protein 1KAP1Conjoint regulation
2009
Association of constitutively activated hepatocyte growth factor receptor (Met) with resistance to a dual EGFR/Her2 inhibitor in non-small-cell lung cancer cells
Agarwal S, Zerillo C, Kolmakova J, Christensen JG, Harris LN, Rimm DL, DiGiovanna MP, Stern DF. Association of constitutively activated hepatocyte growth factor receptor (Met) with resistance to a dual EGFR/Her2 inhibitor in non-small-cell lung cancer cells. British Journal Of Cancer 2009, 100: 941-949. PMID: 19240716, PMCID: PMC2661782, DOI: 10.1038/sj.bjc.6604937.Peer-Reviewed Original ResearchConceptsEpidermal growth factor receptorEGFR/HER2 inhibitorsNSCLC cell linesDual EGFR/HER2 inhibitorsGrowth factor receptorMET inhibitorsHER2 inhibitorsUse of EGFREGFR tyrosine kinase inhibitorsCell lung cancer cellsFactor receptorMajority of patientsTreatment of NSCLCCell lung carcinomaTyrosine kinase inhibitorsPotential therapeutic advantagesSubset of tumorsLung cancer cellsCell linesCurrent clinical useReceptor TKTumor cell growthHepatocyte growth factor receptorMaximal growth inhibitionImportant molecular target