2019
TCF4 induces enzalutamide resistance via neuroendocrine differentiation in prostate cancer
Lee G, Rosenfeld J, Kim W, Kwon Y, Palapattu G, Mehra R, Kim W, Kim I. TCF4 induces enzalutamide resistance via neuroendocrine differentiation in prostate cancer. PLOS ONE 2019, 14: e0213488. PMID: 31536510, PMCID: PMC6752758, DOI: 10.1371/journal.pone.0213488.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsBenzamidesBeta CateninCell Line, TumorDisease Models, AnimalDrug Resistance, NeoplasmHumansMaleMiceMice, KnockoutNeuroendocrine CellsNitrilesPhenylthiohydantoinProstatic NeoplasmsProtein BindingProtein TransportTranscription Factor 7-Like 2 ProteinXenograft Model Antitumor AssaysConceptsCastration-resistant prostate cancerEnzalutamide resistanceTranscription factor 4Neuroendocrine differentiationProstate cancerSecond-generation androgen receptor antagonistHuman prostate cancer cell linesLNCaP human prostate cancer cell lineResistant prostate cancerProstate cancer cell linesStandard of careAndrogen receptor antagonistMouse xenograft modelExpression levelsCell linesTCF4 overexpressionCancer cell linesMedian timeClinical benefitReceptor antagonistNeuroendocrine markersMetastatic CaPTreatment resistanceXenograft modelParental cell line
2017
Garlic extract in bladder cancer prevention: Evidence from T24 bladder cancer cell xenograft model, tissue microarray, and gene network analysis
Kim W, Seo S, Byun Y, Kang H, Kim Y, Lee S, Jeong P, Seo Y, Choe S, Kim D, Kim S, Moon S, Choi Y, Lee G, Kim I, Yun S, Kim W. Garlic extract in bladder cancer prevention: Evidence from T24 bladder cancer cell xenograft model, tissue microarray, and gene network analysis. International Journal Of Oncology 2017, 51: 204-212. PMID: 28498422, DOI: 10.3892/ijo.2017.3993.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsApoptosisBiomarkers, TumorCell ProliferationGarlicGene Expression Regulation, NeoplasticGene Regulatory NetworksHumansMaleMiceMice, Inbred BALB CMice, NudePlant ExtractsSignal TransductionTissue Array AnalysisTumor Cells, CulturedUrinary Bladder NeoplasmsXenograft Model Antitumor AssaysConceptsCancer preventionBladder cancerGarlic extractXenograft modelNude mouse xenograft modelAcceptable safety profileBladder cancer preventionCancer prevention activitiesCell xenograft modelBALB/cTissue microarray analysisMouse xenograft modelMicroarray analysisTumor weightBC patientsSafety profileTumor volumeTissue microarrayControl groupGene network analysisControl dietPrevention activitiesPreventionExtract intakePotential mechanismsIntracrine androgen biosynthesis in renal cell carcinoma
Lee G, Han C, Kwon Y, Patel R, Modi P, Kwon S, Faiena I, Patel N, Singer E, Ahn H, Kim W, Kim I. Intracrine androgen biosynthesis in renal cell carcinoma. British Journal Of Cancer 2017, 116: 937-943. PMID: 28253524, PMCID: PMC5379152, DOI: 10.1038/bjc.2017.42.Peer-Reviewed Original ResearchMeSH KeywordsAbiraterone AcetateAndrogensAnimalsAntineoplastic AgentsApoptosisBenzamidesBlotting, WesternCarcinoma, Renal CellCell ProliferationDihydrotestosteroneFemaleHumansImmunoenzyme TechniquesKidney NeoplasmsMaleMiceMice, NudeNitrilesOrchiectomyPhenylthiohydantoinPrognosisProstatic NeoplasmsProstatic Neoplasms, Castration-ResistantReal-Time Polymerase Chain ReactionReceptors, AndrogenReverse Transcriptase Polymerase Chain ReactionRNA, MessengerTestosteroneTumor Cells, CulturedXenograft Model Antitumor AssaysConceptsRenal cell carcinomaCastration-resistant prostate cancerRCC cell linesAnti-androgen therapyHuman RCC cell linesAndrogen biosynthesisAbiraterone acetateCell carcinomaAndrogen receptorTumor volumeCell linesAndrogen deprivation therapyHigher tumor stageProstate cancer patientsMouse xenograft studiesGenitourinary cancersTumor suppressionSignificant tumor suppressionRCC patientsTumor stageCancer patientsMale miceProstate cancerIntratumoral steroidogenesisXenograft studies
2016
BMI-1 Targeting Interferes with Patient-Derived Tumor-Initiating Cell Survival and Tumor Growth in Prostate Cancer
Bansal N, Bartucci M, Yusuff S, Davis S, Flaherty K, Huselid E, Patrizii M, Jones D, Cao L, Sydorenko N, Moon Y, Zhong H, Medina D, Kerrigan J, Stein M, Kim I, Davis T, DiPaola R, Bertino J, Sabaawy H. BMI-1 Targeting Interferes with Patient-Derived Tumor-Initiating Cell Survival and Tumor Growth in Prostate Cancer. Clinical Cancer Research 2016, 22: 6176-6191. PMID: 27307599, PMCID: PMC5159329, DOI: 10.1158/1078-0432.ccr-15-3107.Peer-Reviewed Original ResearchConceptsTumor-initiating cellsProstate tumor-initiating cellsBmi-1Androgen receptor-directed therapyIntrinsic therapy resistanceReceptor-directed therapyProstate cancer managementProstate cancer treatmentMore effective therapiesBmi-1 expressionProstate cancer cellsStem cell-like traitsSelf-renewing tumor-initiating cellsCell-like traitsPatient-derived cellsEffective therapyTumor relapseCancer managementXenograft modelTherapy resistancePharmacologic inhibitionBmi-1 functionTherapyNormal tissuesCancer treatment
2013
Enrichment of human prostate cancer cells with tumor initiating properties in mouse and zebrafish xenografts by differential adhesion
Bansal N, Davis S, Tereshchenko I, Budak‐Alpdogan T, Zhong H, Stein M, Kim I, DiPaola R, Bertino J, Sabaawy H. Enrichment of human prostate cancer cells with tumor initiating properties in mouse and zebrafish xenografts by differential adhesion. The Prostate 2013, 74: 187-200. PMID: 24154958, PMCID: PMC3939797, DOI: 10.1002/pros.22740.Peer-Reviewed Original Research