2020
In vivo modeling of metastatic human high-grade serous ovarian cancer in mice
Kim O, Park EY, Klinkebiel DL, Pack SD, Shin YH, Abdullaev Z, Emerson RE, Coffey DM, Kwon SY, Creighton CJ, Kwon S, Chang EC, Chiang T, Yatsenko AN, Chien J, Cheon DJ, Yang-Hartwich Y, Nakshatri H, Nephew KP, Behringer RR, Fernández FM, Cho CH, Vanderhyden B, Drapkin R, Bast RC, Miller KD, Karpf AR, Kim J. In vivo modeling of metastatic human high-grade serous ovarian cancer in mice. PLOS Genetics 2020, 16: e1008808. PMID: 32497036, PMCID: PMC7297383, DOI: 10.1371/journal.pgen.1008808.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntineoplastic AgentsCell Line, TumorChromosomal InstabilityCystadenocarcinoma, SerousDEAD-box RNA HelicasesDisease Models, AnimalDNA RepairDrug Resistance, NeoplasmDrug Screening Assays, AntitumorFeasibility StudiesFemaleHumansMiceMice, KnockoutMutationNeoplasm GradingNeoplasm MetastasisOvarian NeoplasmsPeritoneal NeoplasmsPrimary Cell CulturePTEN PhosphohydrolaseRibonuclease IIITumor Suppressor Protein p53ConceptsHigh-grade serous carcinomaHuman HGSCHigh-grade serous ovarian cancerSerous ovarian cancerOvarian cancerPeritoneal metastasisHuman high-grade serous ovarian cancerMetastatic ovarian cancerOvarian cancer typesHuman cancer metastasisHuman cancer mortalityHemorrhagic ascitesClinical metastasisHistopathological similaritiesSerous carcinomaCancer mortalityFallopian tubeMurine modelPeritoneal cavityMouse modelPotential therapyMouse deathMetastasisCancer typesCancer metastasis
2019
Inhibition of Heat Shock Protein 90 suppresses TWIST1 Transcription
Chong KY, Kang M, Garofalo F, Ueno D, Liang H, Cady S, Madarikan O, Pitruzzello N, Tsai CH, Hartwich T, Shuch B, Yang-Hartwich Y. Inhibition of Heat Shock Protein 90 suppresses TWIST1 Transcription. Molecular Pharmacology 2019, 96: 168-179. PMID: 31175180, DOI: 10.1124/mol.119.116137.Peer-Reviewed Original ResearchMeSH KeywordsBenzoquinonesCell Line, TumorDrug Resistance, NeoplasmEpithelial-Mesenchymal TransitionFemaleGene Expression Regulation, NeoplasticHSP90 Heat-Shock ProteinsHumansKidney NeoplasmsLactams, MacrocyclicNasopharyngeal NeoplasmsNuclear ProteinsOvarian NeoplasmsPhosphorylationPromoter Regions, GeneticSTAT3 Transcription FactorTissue Array AnalysisTranscription, GeneticTwist-Related Protein 1ConceptsEpithelial-mesenchymal transitionHsp90 inhibitorsTwist1 transcriptionMolecular chaperone heat shock protein 90Chaperone heat shock protein 90Involvement of Hsp90Heat shock protein 90Cancer cell linesRole of Hsp90Binding of STAT3Inhibition of Hsp90Shock protein 90Cell linesProximity ligation assayHsp90 inhibitor 17TWIST1 mRNA expressionTranscription factorsSignal transducerProtein 90Promoter activityTranscription 3New therapeutic opportunitiesHsp90Molecular mechanismsSTAT3 activity
2016
TRX-E-002-1 Induces c-Jun–Dependent Apoptosis in Ovarian Cancer Stem Cells and Prevents Recurrence In Vivo
Alvero AB, Heaton A, Lima E, Pitruzzello M, Sumi N, Yang-Hartwich Y, Cardenas C, Steinmacher S, Silasi DA, Brown D, Mor G. TRX-E-002-1 Induces c-Jun–Dependent Apoptosis in Ovarian Cancer Stem Cells and Prevents Recurrence In Vivo. Molecular Cancer Therapeutics 2016, 15: 1279-1290. PMID: 27196760, DOI: 10.1158/1535-7163.mct-16-0005.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsApoptosisCell Line, TumorCell ProliferationCell SurvivalCisplatinDrug Resistance, NeoplasmDrug SynergismFemaleFlavonoidsGene Expression Regulation, NeoplasticHumansMiceNeoplasm Recurrence, LocalNeoplasm TransplantationNeoplastic Stem CellsOvarian NeoplasmsPhosphorylationProto-Oncogene Proteins c-junSignal TransductionXenograft Model Antitumor AssaysConceptsCancer stem cellsOvarian cancer cellsTumor burdenOvarian cancerCancer cellsChemoresistant cancer stem cellsOvarian cancer stem cellsIntraperitoneal tumor burdenRecurrent ovarian cancerBest therapeutic optionManagement of patientsCombination of cisplatinEpithelial ovarian cancerCell deathStem cellsTumor repairDisease recurrenceMaintenance treatmentPatient survivalTherapeutic optionsHigh mortalityStemness propertiesMonotherapyDeathVehicle control
2014
p53 protein aggregation promotes platinum resistance in ovarian cancer
Yang-Hartwich Y, Soteras MG, Lin ZP, Holmberg J, Sumi N, Craveiro V, Liang M, Romanoff E, Bingham J, Garofalo F, Alvero A, Mor G. p53 protein aggregation promotes platinum resistance in ovarian cancer. Oncogene 2014, 34: 3605-3616. PMID: 25263447, DOI: 10.1038/onc.2014.296.Peer-Reviewed Original ResearchConceptsPro-apoptotic functionP53 aggregationProtein aggregationP53 aggregatesNormal transcriptional activationTwo-dimensional gel electrophoresisCancer cellsCancer cell survivalKey transcriptional factorGenetic mutationsHigh-grade serous ovarian carcinomaP53 inactivationP53 proteinStem cell propertiesCancer stem cell propertiesCellular homeostasisTranscriptional activationCancer stem cellsTranscriptional factorsTumor-initiating capacityP53 turnoverCell survivalHGSOC cellsStem cellsPotential therapeutic target
2013
Phenotypic modifications in ovarian cancer stem cells following Paclitaxel treatment
Craveiro V, Yang-Hartwich Y, Holmberg JC, Joo WD, Sumi NJ, Pizzonia J, Griffin B, Gill SK, Silasi DA, Azodi M, Rutherford T, Alvero AB, Mor G. Phenotypic modifications in ovarian cancer stem cells following Paclitaxel treatment. Cancer Medicine 2013, 2: 751-762. PMID: 24403249, PMCID: PMC3892380, DOI: 10.1002/cam4.115.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsAntineoplastic Agents, PhytogenicCarcinoma, Ovarian EpithelialDrug Resistance, NeoplasmFemaleHEK293 CellsHumansHyaluronan ReceptorsMiceMice, NudeMyeloid Differentiation Factor 88Neoplasms, Glandular and EpithelialNeoplastic Stem CellsOvarian NeoplasmsPaclitaxelPhenotypeRecurrenceSnail Family Transcription FactorsTranscription FactorsTumor BurdenXenograft Model Antitumor AssaysConceptsEpithelial ovarian cancerRecurrent epithelial ovarian cancerOvarian cancer stem cellsEOC stem cellsCancer stem cellsQuantitative polymerase chain reactionRecurrent diseaseOvarian cancerEOC cellsVivo ovarian cancer modelsStem cellsDoses of paclitaxelLethal gynecologic malignancyOvarian cancer modelProcess of recurrenceWestern blot analysisMaintenance therapyGynecologic malignanciesPrimary diseaseAggressive diseaseEOC patientsPrimary tumorPolymerase chain reactionAggressive phenotypePaclitaxel treatmentTLR2 enhances ovarian cancer stem cell self-renewal and promotes tumor repair and recurrence
Chefetz I, Alvero A, Holmberg J, Lebowitz N, Craveiro V, Yang-Hartwich Y, Yin G, Squillace L, Soteras M, Aldo P, Mor G. TLR2 enhances ovarian cancer stem cell self-renewal and promotes tumor repair and recurrence. Cell Cycle 2013, 12: 511-521. PMID: 23324344, PMCID: PMC3587452, DOI: 10.4161/cc.23406.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsCarcinoma, Ovarian EpithelialDrug Resistance, NeoplasmFemaleHomeodomain ProteinsHumansHyaluronan ReceptorsInflammationMiceMice, NudeMyeloid Differentiation Factor 88Nanog Homeobox ProteinNeoplasm Recurrence, LocalNeoplasms, Glandular and EpithelialNeoplastic Stem CellsNF-kappa BOctamer Transcription Factor-3Ovarian NeoplasmsSOXB1 Transcription FactorsToll-Like Receptor 2Tumor Cells, CulturedTumor MicroenvironmentConceptsOvarian cancer stem cellsCancer stem cellsTumor repairEOC stem cellsTLR2-MyD88NFκB pathwaySpecific pro-inflammatory pathwaysStem cellsMajority of patientsEpithelial ovarian cancer stem cellsPrimary ovarian cancerPro-inflammatory pathwaysPro-inflammatory microenvironmentCell populationsStemness-associated genesChemoresistant recurrent diseaseRecurrent diseaseEOC patientsRecent compelling evidenceOvarian cancerTumor injuryRecurrenceCancer cell populationsTumor initiationCancer cells