2020
Identification of miPEP133 as a novel tumor-suppressor microprotein encoded by miR-34a pri-miRNA
Kang M, Tang B, Li J, Zhou Z, Liu K, Wang R, Jiang Z, Bi F, Patrick D, Kim D, Mitra AK, Yang-Hartwich Y. Identification of miPEP133 as a novel tumor-suppressor microprotein encoded by miR-34a pri-miRNA. Molecular Cancer 2020, 19: 143. PMID: 32928232, PMCID: PMC7489042, DOI: 10.1186/s12943-020-01248-9.Peer-Reviewed Original ResearchConceptsNon-coding RNA transcriptsNasopharyngeal carcinomaCancer cell linesP53 transcriptional activationPrognostic markerTumor suppressor functionAmino acid residuesCell linesTumor growthNovel microproteinWild-type p53Cellular functionsMetastatic nasopharyngeal carcinomaTranscriptional activationPotential prognostic markerMitochondrial membraneUnfavorable prognostic markerCervical cancer cell linesRNA transcriptsMitochondrial massTumor suppressorMiR-34a expressionAcid residuesNormal human colonNPC clinical samples
2019
An Underlying Mechanism of Dual Wnt Inhibition and AMPK Activation: Mitochondrial Uncouplers Masquerading as Wnt Inhibitors
Zhang W, Sviripa VM, Kril L, Yu T, Xie Y, Hubbard W, Sullivan P, Chen X, Zhan CG, Yang-Hartwich Y, Evers BM, Spear B, Gedaly R, Watt DS, Liu C. An Underlying Mechanism of Dual Wnt Inhibition and AMPK Activation: Mitochondrial Uncouplers Masquerading as Wnt Inhibitors. Journal Of Medicinal Chemistry 2019, 62: 11348-11358. PMID: 31774672, PMCID: PMC7560992, DOI: 10.1021/acs.jmedchem.9b01685.Peer-Reviewed Original ResearchInhibition 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
Detection of p53 Protein Transcriptional Activity by Chromatin Immunoprecipitation
Yang-Hartwich Y, Romanoff E, Bingham J, Alvero AB, Mor G. Detection of p53 Protein Transcriptional Activity by Chromatin Immunoprecipitation. Methods In Molecular Biology 2014, 1219: 87-93. PMID: 25308264, DOI: 10.1007/978-1-4939-1661-0_8.Peer-Reviewed Original ResearchMeSH KeywordsChromatin ImmunoprecipitationGene Expression Regulation, NeoplasticHumansNeoplasmsReal-Time Polymerase Chain ReactionTranscription, GeneticTumor Suppressor Protein p53ConceptsTranscriptional activityP53 transcriptional activityChromatin immunoprecipitationTranscription-dependent activityDNA-binding domainExpression of hundredsImportant cellular functionsKey transcriptional mediatorAbility of p53Protein's transcriptional activityP53-induced apoptosisResult of mutationsGenome integrityCellular homeostasisCellular functionsTranscriptional mediatorsTarget genesPromoter regionApoptotic genesCell deathReal-time quantitative polymerase chain reactionCancer cellsQuantitative polymerase chain reactionImmunoprecipitationGenes
2011
Ovarian cancer stem cells and inflammation
Mor G, Yin G, Chefetz I, Yang Y, Alvero A. Ovarian cancer stem cells and inflammation. Cancer Biology & Therapy 2011, 11: 708-713. PMID: 21317559, PMCID: PMC3100563, DOI: 10.4161/cbt.11.8.14967.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsCarcinoma, Ovarian EpithelialCell DifferentiationFemaleGene Expression Regulation, NeoplasticHumansInflammationNeoplasms, Glandular and EpithelialNeoplastic Stem CellsNF-kappa BOvarian NeoplasmsToll-Like ReceptorsConceptsEpithelial ovarian cancerOvarian cancerCancer stem cellsAdvanced stage ovarian cancerOvarian cancer stem cellsGynecologic cancer deathFourth leading causeCancer-related deathSource of recurrenceLack of responseStem cellsCancer deathDisease progressionLeading causeQuestion of recurrenceRecurrenceCancerChemotherapyDeathInflammationChemoresistanceCauseCellsProgressionWomen