2022
Inhibition of renalase drives tumour rejection by promoting T cell activation
Guo X, Jessel S, Qu R, Kluger Y, Chen TM, Hollander L, Safirstein R, Nelson B, Cha C, Bosenberg M, Jilaveanu LB, Rimm D, Rothlin CV, Kluger HM, Desir GV. Inhibition of renalase drives tumour rejection by promoting T cell activation. European Journal Of Cancer 2022, 165: 81-96. PMID: 35219026, PMCID: PMC8940682, DOI: 10.1016/j.ejca.2022.01.002.Peer-Reviewed Original ResearchConceptsPD-1 inhibitorsMurine melanoma modelMelanoma-bearing miceMelanoma modelTumor microenvironmentTumor rejectionCell death protein 1 (PD-1) inhibitorsAnti-PD-1 activityEnhanced T cell infiltrationT cell-dependent fashionMelanoma cellsMelanoma tumor regressionPreclinical melanoma modelsT cell infiltrationNatural killer cellsForkhead box P3Expression of IFNγWild-type miceProtein 1 inhibitorT cell activationTumor cell contentWild-type melanoma cellsCD4 cellsAdvanced melanomaAntibody treatmentCECR2 drives breast cancer metastasis by promoting NF-κB signaling and macrophage-mediated immune suppression
Zhang M, Liu ZZ, Aoshima K, Cai WL, Sun H, Xu T, Zhang Y, An Y, Chen JF, Chan LH, Aoshima A, Lang SM, Tang Z, Che X, Li Y, Rutter SJ, Bossuyt V, Chen X, Morrow JS, Pusztai L, Rimm DL, Yin M, Yan Q. CECR2 drives breast cancer metastasis by promoting NF-κB signaling and macrophage-mediated immune suppression. Science Translational Medicine 2022, 14: eabf5473. PMID: 35108062, PMCID: PMC9003667, DOI: 10.1126/scitranslmed.abf5473.Peer-Reviewed Original ResearchConceptsBreast cancer metastasisReticuloendotheliosis viral oncogene homolog ACancer metastasisImmune suppressionM2 macrophagesWorse metastasis-free survivalMetastatic breast cancerMetastasis-free survivalV-rel avian reticuloendotheliosis viral oncogene homolog ACancer-related deathPrimary breast tumorsMultiple mouse modelsNF-κB signalingImmunocompetent settingNuclear factor-κB family membersMetastasis-promoting genesDistant metastasisMetastatic sitesPrimary tumorEffective therapyBreast cancerMetastasis treatmentMouse modelBreast tumorsMetastasis
2021
Targeting Pyruvate Kinase M2 Phosphorylation Reverses Aggressive Cancer Phenotypes
Apostolidi M, Vathiotis IA, Muthusamy V, Gaule P, Gassaway BM, Rimm DL, Rinehart J. Targeting Pyruvate Kinase M2 Phosphorylation Reverses Aggressive Cancer Phenotypes. Cancer Research 2021, 81: 4346-4359. PMID: 34185676, PMCID: PMC8373815, DOI: 10.1158/0008-5472.can-20-4190.Peer-Reviewed Original ResearchMeSH KeywordsActive Transport, Cell NucleusAnimalsBiomarkers, TumorCarrier ProteinsCell Line, TumorCollagenCyclic N-OxidesDrug CombinationsGenome, HumanHumansIndolizinesLamininMCF-7 CellsMembrane ProteinsMiceNeoplasm InvasivenessNeoplasm TransplantationNeoplasmsOxidation-ReductionPhenotypePhosphorylationProtein IsoformsProteoglycansProteomicsPyridazinesPyridinium CompoundsPyrrolesPyruvate KinaseThyroid HormonesTriple Negative Breast NeoplasmsConceptsTriple-negative breast cancerPyruvate kinase M2TEPP-46Breast cancerAggressive breast cancer cell phenotypesCharacteristic nuclear staining patternAggressive breast cancer subtypeAggressive breast cancer phenotypeBreast cancer cell phenotypeCDK inhibitor dinaciclibCombination of dinaciclibLack of biomarkersEffective therapeutic approachBreast cancer phenotypeBreast cancer subtypesCancer phenotypePhosphorylation of PKM2Cyclin-dependent kinase (CDK) pathwayMouse xenograft modelAggressive cancer phenotypeNuclear staining patternLower survival rateImpaired redox balancePrognostic valueCancer cell phenotypeTargeting the CSF1/CSF1R axis is a potential treatment strategy for malignant meningiomas
Yeung J, Yaghoobi V, Miyagishima D, Vesely MD, Zhang T, Badri T, Nassar A, Han X, Sanmamed MF, Youngblood M, Peyre M, Kalamarides M, Rimm DL, Gunel M, Chen L. Targeting the CSF1/CSF1R axis is a potential treatment strategy for malignant meningiomas. Neuro-Oncology 2021, 23: 1922-1935. PMID: 33914067, PMCID: PMC8563319, DOI: 10.1093/neuonc/noab075.Peer-Reviewed Original ResearchConceptsColony-stimulating factor-1Myeloid cellsMalignant meningiomasTumor microenvironmentCSF1/CSF1RRNA-seqRNA sequencingHuman meningiomasImmune subsetsGene expressionT cellsTreatment strategiesNormalization cancer immunotherapyImportant regulatorCell typesNovel immunocompetent murine modelDeath ligand 1 (PD-L1) expressionCell death receptor-1Immunosuppressive myeloid cellsDeath receptor-1Ligand 1 expressionFactor 1Immune cell typesImmunocompetent murine modelEffective treatment strategies
2020
Acquired Resistance to HER2-Targeted Therapies Creates Vulnerability to ATP Synthase Inhibition
Gale M, Li Y, Cao J, Liu ZZ, Holmbeck MA, Zhang M, Lang SM, Wu L, Do Carmo M, Gupta S, Aoshima K, DiGiovanna MP, Stern DF, Rimm DL, Shadel GS, Chen X, Yan Q. Acquired Resistance to HER2-Targeted Therapies Creates Vulnerability to ATP Synthase Inhibition. Cancer Research 2020, 80: 524-535. PMID: 31690671, PMCID: PMC7002225, DOI: 10.1158/0008-5472.can-18-3985.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntineoplastic Combined Chemotherapy ProtocolsApoptosisBreast NeoplasmsCell ProliferationDrug Resistance, NeoplasmEnzyme InhibitorsFemaleHumansMiceMice, Inbred NODMice, SCIDMitochondrial Proton-Translocating ATPasesOligomycinsReceptor, ErbB-2TrastuzumabTumor Cells, CulturedXenograft Model Antitumor AssaysConceptsResistant cellsHER2-Targeted TherapyTrastuzumab-resistant tumorsNew therapeutic strategiesNovel potential targetDrug-free mediumAntibody therapySynthase inhibitionLow doseTherapeutic strategiesTrastuzumabBreast tumorsHER2TherapyAcquired ResistanceTumorsPotential targetMitochondrial respirationCellsSelective dependencyInhibitionMinimal changesNovel vulnerabilitiesATP synthase inhibitionOligomycin A
2019
Suppressing miR-21 activity in tumor-associated macrophages promotes an antitumor immune response
Sahraei M, Chaube B, Liu Y, Sun J, Kaplan A, Price NL, Ding W, Oyaghire S, García-Milian R, Mehta S, Reshetnyak YK, Bahal R, Fiorina P, Glazer PM, Rimm DL, Fernández-Hernando C, Suárez Y. Suppressing miR-21 activity in tumor-associated macrophages promotes an antitumor immune response. Journal Of Clinical Investigation 2019, 129: 5518-5536. PMID: 31710308, PMCID: PMC6877327, DOI: 10.1172/jci127125.Peer-Reviewed Original ResearchConceptsTumor-associated macrophagesMiR-21 expressionTumor growthMiR-21Immune responseCytotoxic T cell responsesC motif chemokine 10Antitumor immune responseT cell responsesAntitumoral immune responseTumor immune infiltratesInduction of cytokinesPotential therapeutic implicationsMiR-21 inhibitionStages of carcinogenesisAngiostatic phenotypeTumor cell deathIL-12Immune infiltratesTherapeutic implicationsSolid tumorsTumor neovascularizationTumor progressionTumor microenvironmentTumor pathogenesis
2018
Tumor-specific MHC-II expression drives a unique pattern of resistance to immunotherapy via LAG-3/FCRL6 engagement
Johnson DB, Nixon MJ, Wang Y, Wang DY, Castellanos E, Estrada MV, Ericsson-Gonzalez PI, Cote CH, Salgado R, Sanchez V, Dean PT, Opalenik SR, Schreeder DM, Rimm DL, Kim JY, Bordeaux J, Loi S, Horn L, Sanders ME, Ferrell PB, Xu Y, Sosman JA, Davis RS, Balko JM. Tumor-specific MHC-II expression drives a unique pattern of resistance to immunotherapy via LAG-3/FCRL6 engagement. JCI Insight 2018, 3: e120360. PMID: 30568030, PMCID: PMC6338319, DOI: 10.1172/jci.insight.120360.Peer-Reviewed Original ResearchMeSH KeywordsAdaptive ImmunityAnimalsAntibodies, NeutralizingAntigens, CDBreast NeoplasmsCD4-Positive T-LymphocytesCell Line, TumorHistocompatibility Antigens Class IIHLA-DR AntigensHumansImmunotherapyKiller Cells, NaturalLigandsLymphocyte Activation Gene 3 ProteinMiceProgrammed Cell Death 1 ReceptorReceptors, Antigen, T-CellReceptors, Cell SurfaceT-LymphocytesTumor MicroenvironmentConceptsMHC-II expressionT cellsAnti-PD-1 therapyTumor cellsPD-1 pathwayTumor-intrinsic factorsPD-1-targeted immunotherapiesMHC-II receptorsDurable responsesPD-1Immune activationImmunotherapy targetPreclinical modelsLAG-3TumorsUnique patternMHCEnhanced expressionInhibitory functionAdaptive resistanceNovel inhibitory functionImmunotherapyPatientsContext-dependent mechanismsCells
2016
Dual CCNE1/PIK3CA targeting is synergistic in CCNE1-amplified/PIK3CA-mutated uterine serous carcinomas in vitro and in vivo
Cocco E, Lopez S, Black J, Bellone S, Bonazzoli E, Predolini F, Ferrari F, Schwab CL, Menderes G, Zammataro L, Buza N, Hui P, Wong S, Zhao S, Bai Y, Rimm DL, Ratner E, Litkouhi B, Silasi DA, Azodi M, Schwartz PE, Santin AD. Dual CCNE1/PIK3CA targeting is synergistic in CCNE1-amplified/PIK3CA-mutated uterine serous carcinomas in vitro and in vivo. British Journal Of Cancer 2016, 115: 303-311. PMID: 27351214, PMCID: PMC4973158, DOI: 10.1038/bjc.2016.198.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntineoplastic AgentsCell Line, TumorClass I Phosphatidylinositol 3-KinasesCyclin EDNA Copy Number VariationsFemaleGene Knockdown TechniquesHeterograftsHumansIn Situ Hybridization, FluorescenceIn Vitro TechniquesMiceMutationOncogene ProteinsPhosphatidylinositol 3-KinasesRNA, MessengerTissue Array AnalysisUterine NeoplasmsConceptsUterine serous carcinomaSerous carcinomaTumor growthCyclin E1 (CCNE1) gene amplificationRecurrent uterine serous carcinomaPrimary USC cell linesNovel therapeutic optionsSingle-agent treatmentIdeal therapeutic targetUSC cell linesCyclin E1 expressionUSC patientsUSC xenograftsInhibited cell growthCell cycle analysisAggressive variantTherapeutic optionsCCNE1 amplificationEndometrial tumorsCYC065Therapeutic targetClinical optionPIK3CA driver mutationsDriver mutationsXenograftsPD-L1 Expression in Lung Cancer
Yu H, Boyle TA, Zhou C, Rimm D, Hirsch FR. PD-L1 Expression in Lung Cancer. Journal Of Thoracic Oncology 2016, 11: 964-975. PMID: 27117833, PMCID: PMC5353357, DOI: 10.1016/j.jtho.2016.04.014.Peer-Reviewed Original ResearchConceptsPD-L1Lung cancerAnti-PD-1 drugsDifferent PD-L1 antibodiesPD-L1 protein expressionImmunotherapy clinical trialsAdvanced lung cancerPD-L1 expressionPD-L1 antibodiesSubset of patientsDeath ligand 1PD-L1 detectionBetter patient careClinical trialsPatient careProtein expressionHistory of useImmunohistochemistry platformBiomarkersImmunotherapyLigand 1PatientsCancerExpressionTrialsRAS/MAPK Activation Is Associated with Reduced Tumor-Infiltrating Lymphocytes in Triple-Negative Breast Cancer: Therapeutic Cooperation Between MEK and PD-1/PD-L1 Immune Checkpoint Inhibitors
Loi S, Dushyanthen S, Beavis PA, Salgado R, Denkert C, Savas P, Combs S, Rimm DL, Giltnane JM, Estrada MV, Sánchez V, Sanders ME, Cook RS, Pilkinton MA, Mallal SA, Wang K, Miller VA, Stephens PJ, Yelensky R, Doimi FD, Gómez H, Ryzhov SV, Darcy PK, Arteaga CL, Balko JM. RAS/MAPK Activation Is Associated with Reduced Tumor-Infiltrating Lymphocytes in Triple-Negative Breast Cancer: Therapeutic Cooperation Between MEK and PD-1/PD-L1 Immune Checkpoint Inhibitors. Clinical Cancer Research 2016, 22: 1499-1509. PMID: 26515496, PMCID: PMC4794351, DOI: 10.1158/1078-0432.ccr-15-1125.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsB7-H1 AntigenBiomarkersCell Line, TumorDisease Models, AnimalDisease ProgressionFemaleGene Expression ProfilingHumansImmunomodulationImmunophenotypingLymphocytes, Tumor-InfiltratingMiceMitogen-Activated Protein KinasesMortalityPhenotypeProgrammed Cell Death 1 ReceptorProtein Kinase InhibitorsRas ProteinsSignal TransductionTranscriptomeTriple Negative Breast NeoplasmsConceptsTriple-negative breast cancerTumor-infiltrating lymphocytesImmune checkpoint inhibitorsResidual diseaseNeoadjuvant chemotherapyBreast cancerPD-L1Checkpoint inhibitorsMHC expressionMouse modelPD-1/PD-L1 immune checkpoint inhibitorsPD-L1 immune checkpoint inhibitorsPresence of TILsPD-1/PD-L1Low tumor-infiltrating lymphocytesPD-L1/PDAntitumor immune responseRAS/MAPK activationCell-surface MHC expressionMAPK activationImproved survivalImproved prognosisPredictive biomarkersClinical trialsImmune responsemiR-34a Silences c-SRC to Attenuate Tumor Growth in Triple-Negative Breast Cancer
Adams BD, Wali VB, Cheng CJ, Inukai S, Booth CJ, Agarwal S, Rimm DL, Győrffy B, Santarpia L, Pusztai L, Saltzman WM, Slack FJ. miR-34a Silences c-SRC to Attenuate Tumor Growth in Triple-Negative Breast Cancer. Cancer Research 2016, 76: 927-939. PMID: 26676753, PMCID: PMC4755913, DOI: 10.1158/0008-5472.can-15-2321.Peer-Reviewed Original ResearchConceptsTriple-negative breast cancerBreast cancerTumor growthMiR-34a replacement therapyTNBC cell linesDifferent TNBC subtypesPromising therapeutic strategyAttenuates tumor growthHuman clinical trialsMiRNA-profiling studiesMiR-34a levelsCell linesPotent antitumorigenic effectsMiR-34a targetsHuman tumor specimensC-SrcReplacement therapyTNBC subtypesAggressive subtypeTreatment optionsClinical trialsDisease progressionEffective therapyPatient outcomesC-Src inhibitor
2012
microRNA Regulatory Network Inference Identifies miR-34a as a Novel Regulator of TGF-β Signaling in Glioblastoma
Genovese G, Ergun A, Shukla SA, Campos B, Hanna J, Ghosh P, Quayle SN, Rai K, Colla S, Ying H, Wu CJ, Sarkar S, Xiao Y, Zhang J, Zhang H, Kwong L, Dunn K, Wiedemeyer WR, Brennan C, Zheng H, Rimm DL, Collins JJ, Chin L. microRNA Regulatory Network Inference Identifies miR-34a as a Novel Regulator of TGF-β Signaling in Glioblastoma. Cancer Discovery 2012, 2: 736-749. PMID: 22750848, PMCID: PMC3911772, DOI: 10.1158/2159-8290.cd-12-0111.Peer-Reviewed Original ResearchConceptsMultidimensional cancer genomic dataPromoter enrichment analysisCancer genomic dataNovel regulatorGenomic dataContext likelihoodEnrichment analysisPutative regulatory networksFunctional genetic screensDifferent genetic elementsGenetic screenTGF-β signalingTranscriptional networksPlatelet-derived growth factorMRNA nodesGenome spaceRegulatory networksTranscriptomic networksBiology of cancerNovel regulationGenetic elementsTumor suppressorSilico analysisDirect regulationNew pathogenetic insightsQuantitative analysis of microRNAs in tissue microarrays by in situ hybridization
Hanna JA, Wimberly H, Kumar S, Slack F, Agarwal S, Rimm DL. Quantitative analysis of microRNAs in tissue microarrays by in situ hybridization. BioTechniques 2012, 52: 235-245. PMID: 22482439, PMCID: PMC3891915, DOI: 10.2144/000113837.Peer-Reviewed Original Research
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 implicationsWntLungA Pathway for the Control of Anoikis Sensitivity by E-Cadherin and Epithelial-to-Mesenchymal Transition
Kumar S, Park SH, Cieply B, Schupp J, Killiam E, Zhang F, Rimm DL, Frisch SM. A Pathway for the Control of Anoikis Sensitivity by E-Cadherin and Epithelial-to-Mesenchymal Transition. Molecular And Cellular Biology 2011, 31: 4036-4051. PMID: 21746881, PMCID: PMC3187352, DOI: 10.1128/mcb.01342-10.Peer-Reviewed Original ResearchConceptsRegulation of anoikisE-cadherin complexMesenchymal transitionE-cadherinAnoikis sensitivityNuclear localizationInappropriate matrixAnoikis resistanceApoptotic responseOncogenic EMTAnoikisNRAGECellular sensitivityNovel pathwayUnknown mechanismAnkyrinEpithelial cellsEMTPathwayP14ARFCellsTbx2ComplexesGenesCytoplasmTargeting Androgen Receptor in Estrogen Receptor-Negative Breast Cancer
Ni M, Chen Y, Lim E, Wimberly H, Bailey ST, Imai Y, Rimm DL, Liu XS, Brown M. Targeting Androgen Receptor in Estrogen Receptor-Negative Breast Cancer. Cancer Cell 2011, 20: 119-131. PMID: 21741601, PMCID: PMC3180861, DOI: 10.1016/j.ccr.2011.05.026.Peer-Reviewed Original ResearchMeSH KeywordsAndrogensAnilidesAnimalsBeta CateninBreast NeoplasmsCell Line, TumorCell ProliferationDihydrotestosteroneFemaleGene Expression ProfilingGene Expression Regulation, NeoplasticHepatocyte Nuclear Factor 3-alphaHumansMiceNitrilesReceptor, ErbB-2Receptors, AndrogenReceptors, EstrogenSignal TransductionTosyl CompoundsTranscriptional ActivationUp-RegulationWnt ProteinsXenograft Model Antitumor AssaysConceptsAndrogen receptorBreast cancerEstrogen receptorER-/HER2Estrogen receptor-negative breast cancerReceptor-negative breast cancerBreast cancer growthER- breast tumorsPotential therapeutic approachTumor cell growthAndrogen-regulated gene expressionEndocrine therapyER statusTherapeutic approachesAR cistromeBreast tumorsCancer growthDirect transcriptional inductionCancerHER2Ligand-dependent activationReceptorsSpecific targetingTumorsCell growthProinvasion Metastasis Drivers in Early-Stage Melanoma Are Oncogenes
Scott KL, Nogueira C, Heffernan TP, van Doorn R, Dhakal S, Hanna JA, Min C, Jaskelioff M, Xiao Y, Wu CJ, Cameron LA, Perry SR, Zeid R, Feinberg T, Kim M, Woude G, Granter SR, Bosenberg M, Chu GC, DePinho RA, Rimm DL, Chin L. Proinvasion Metastasis Drivers in Early-Stage Melanoma Are Oncogenes. Cancer Cell 2011, 20: 92-103. PMID: 21741599, PMCID: PMC3176328, DOI: 10.1016/j.ccr.2011.05.025.Peer-Reviewed Original ResearchMeSH KeywordsAcid PhosphataseAnimalsCell LineageConserved SequenceEvolution, MolecularGene Expression ProfilingGene Expression Regulation, NeoplasticGenomeHumansIsoenzymesKaplan-Meier EstimateMelanomaMiceNeoplasm InvasivenessNeoplasm MetastasisNeoplasm StagingOncogenesPhosphorylationReproducibility of ResultsSkin NeoplasmsTartrate-Resistant Acid PhosphataseTissue Array AnalysisConceptsFunctional genetic screensGenetic screenGlobal transcriptomeMetastatic potentialSuch genesGenomic evidenceExpression selectionTranscriptomic profilesHuman melanoma tissuesMetastasis driverCell invasionKey pathwaysOncogenic capabilitiesMelanoma tissuesGenesHuman melanomaHuman primary melanomasTranscriptomeMouse modelSpontaneous metastasisOncogeneEnhancerACP5PathwayInvasionGlucose and Inflammation Control Islet Vascular Density and β-Cell Function in NOD Mice Control of Islet Vasculature and Vascular Endothelial Growth Factor by Glucose
Akirav EM, Baquero MT, Opare-Addo LW, Akirav M, Galvan E, Kushner JA, Rimm DL, Herold KC. Glucose and Inflammation Control Islet Vascular Density and β-Cell Function in NOD Mice Control of Islet Vasculature and Vascular Endothelial Growth Factor by Glucose. Diabetes 2011, 60: 876-883. PMID: 21307078, PMCID: PMC3046848, DOI: 10.2337/db10-0793.Peer-Reviewed Original ResearchConceptsVascular endothelial growth factorIslet vascular densityNOD miceEndothelial cell densityGlucose toleranceEndothelial growth factorΒ-cellsVascular densityInsulin contentIslet vasculatureAnti-CD3 monoclonal antibodyEndothelial cellsGrowth factorDiabetic NOD micePrediabetic NOD miceAltered glucose toleranceImproved glucose toleranceEndothelial cell destructionType 1 diabetesAnti-CD3 mAbΒ-cell functionΒ-cell massHigh glucose levelsΒ-cell proliferationTransfer of supernatants
2010
Molecular Analysis of Non–Small Cell Lung Cancer Identifies Subsets with Different Sensitivity to Insulin-like Growth Factor I Receptor Inhibition
Gualberto A, Dolled-Filhart M, Gustavson M, Christiansen J, Wang YF, Hixon ML, Reynolds J, McDonald S, Ang A, Rimm DL, Langer CJ, Blakely J, Garland L, Paz-Ares LG, Karp DD, Lee AV. Molecular Analysis of Non–Small Cell Lung Cancer Identifies Subsets with Different Sensitivity to Insulin-like Growth Factor I Receptor Inhibition. Clinical Cancer Research 2010, 16: 4654-4665. PMID: 20670944, PMCID: PMC2952544, DOI: 10.1158/1078-0432.ccr-10-0089.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntibodies, MonoclonalAntineoplastic AgentsCarcinoma, Non-Small-Cell LungClinical Trials, Phase II as TopicDrug Resistance, NeoplasmFemaleHormone AntagonistsHumansImmunoglobulins, IntravenousInsulin-Like Growth Factor IMaleMiceMolecular Diagnostic TechniquesNIH 3T3 CellsPrognosisRetrospective StudiesTissue Array AnalysisConceptsNon-small cell lung cancerPhase II studySquamous cell tumorsIGF-IRII studyCell tumorsStage IIIB/IV non-small cell lung cancerAdvanced non-small cell lung cancerCell lung cancerIGF-IR pathwayIGF-IR inhibitionIGF-IR expressionCombination of chemotherapyHigh response rateEpidermal growth factor receptorEpithelial-like tumorsInsulin receptor substrate-1Growth factor receptorHistologic subtypeTransitional tumorsReceptor therapyIGF-IILung cancerReceptor inhibitionIGF-IIRThe ERα coactivator, HER4/4ICD, regulates progesterone receptor expression in normal and malignant breast epithelium
Rokicki J, Das PM, Giltnane JM, Wansbury O, Rimm DL, Howard BA, Jones FE. The ERα coactivator, HER4/4ICD, regulates progesterone receptor expression in normal and malignant breast epithelium. Molecular Cancer 2010, 9: 150. PMID: 20550710, PMCID: PMC2894764, DOI: 10.1186/1476-4598-9-150.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsBreast NeoplasmsCell Line, TumorErbB ReceptorsEstrogen Receptor alphaFemaleGene ExpressionGene Expression RegulationHumansMammary Glands, AnimalMammary Glands, HumanMiceMice, TransgenicPregnancyReceptor, ErbB-4Receptors, ProgesteroneReverse Transcriptase Polymerase Chain ReactionSignal TransductionConceptsPgR expressionExpression of PgRBreast cancerERα coactivatorMammary glandHER4 intracellular domainProgesterone receptor expressionPositive breast carcinomaMalignant breast epitheliumPrimary breast tumorsMCF-7 variantEstrogen receptor coactivatorBreast tumor cell linesCell linesBreast tumor cellsTamoxifen responseMouse mammary glandProgesterone receptorReceptor expressionBreast carcinomaMCF-7 breast tumor cell linePatient responseBreast carcinogenesisEstrogen stimulationBreast epithelium