2019
Mitochondrial DNA stress signalling protects the nuclear genome
Wu Z, Oeck S, West AP, Mangalhara KC, Sainz AG, Newman LE, Zhang XO, Wu L, Yan Q, Bosenberg M, Liu Y, Sulkowski PL, Tripple V, Kaech SM, Glazer PM, Shadel GS. Mitochondrial DNA stress signalling protects the nuclear genome. Nature Metabolism 2019, 1: 1209-1218. PMID: 32395698, PMCID: PMC7213273, DOI: 10.1038/s42255-019-0150-8.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsCell Line, TumorCell NucleusCytosolDNA DamageDNA, MitochondrialDNA-Binding ProteinsGenomeHigh Mobility Group ProteinsInterferonsInterferon-Stimulated Gene Factor 3Membrane ProteinsMiceMice, KnockoutMice, NudeNF-kappa BNucleotidyltransferasesProtein Serine-Threonine KinasesSignal TransductionConceptsMtDNA stressNuclear DNAGene expressionThousands of copiesMost cell typesRepair responseAcute antiviral responseNuclear genomeCircular mtDNAHigher-order structureInterferon gene expressionEssential proteinsMitochondrial DNACultured primary fibroblastsDNA stressUnphosphorylated formInterferon-stimulated gene expressionMouse melanoma cellsNDNA repairSignaling responseOxidative phosphorylationNDNA damageMtDNA damageMtDNAPrimary fibroblastsImpact of hypoxia on DNA repair and genome integrity
Kaplan AR, Glazer PM. Impact of hypoxia on DNA repair and genome integrity. Mutagenesis 2019, 35: 61-68. PMID: 31282537, PMCID: PMC7317153, DOI: 10.1093/mutage/gez019.Peer-Reviewed Original ResearchConceptsDNA repairDNA repair pathwaysHomology-directed repairBase excision repairGenome integrityRepair pathwaysGenomic instabilityExcision repairHypoxia mimeticMismatch repairDiverse mechanismsImpact of hypoxiaCancer progressionMutation frequencyTumor biologyTumor microenvironmentDevelopment of metastasesPotential clinical relevanceProfound effectRepairBiologyHypoxiaPathwayHallmarkMicroenvironment
2001
Chromosome Targeting at Short Polypurine Sites by Cationic Triplex-forming Oligonucleotides*
Vasquez K, Dagle J, Weeks D, Glazer P. Chromosome Targeting at Short Polypurine Sites by Cationic Triplex-forming Oligonucleotides*. Journal Of Biological Chemistry 2001, 276: 38536-38541. PMID: 11504712, DOI: 10.1074/jbc.m101797200.Peer-Reviewed Original ResearchMeSH KeywordsAnimalsBase SequenceCationsChromosomesCOS CellsDiaminesDNADNA Mutational AnalysisDose-Response Relationship, DrugEthylenediaminesFicusinGenes, ReporterGenes, SuppressorGenetic TechniquesGenomeIndicators and ReagentsMagnesiumMiceMice, KnockoutModels, GeneticMolecular Sequence DataMutagenesisMutagenesis, Site-DirectedNucleic Acid ConformationPotassiumProtein BindingPurinesRNA, TransferSequence Homology, Nucleic AcidConceptsChromosomal reporter geneMonkey COS cellsTarget siteSite-specific mutationsTriplex target sitesChromosome targetingEpisomal targetChromosomal targetsGene mutagenesisMammalian cellsSite-specific inductionChromosomal lociReporter geneCOS cellsGene knockoutGenomic DNAMouse cellsSite-directed modificationOligonucleotide bindsPhosphodiester bondShort sitesThird strand bindingPhosphodiester backboneSystemic administrationDNA
1996
Triplex‐Mediated, in vitro Targeting of Psoralen Photoadducts within the Genome of a Transgenic Mouse
Gunther E, Havre P, Gasparro F, Glazer P. Triplex‐Mediated, in vitro Targeting of Psoralen Photoadducts within the Genome of a Transgenic Mouse. Photochemistry And Photobiology 1996, 63: 207-212. PMID: 8657733, DOI: 10.1111/j.1751-1097.1996.tb03015.x.Peer-Reviewed Original ResearchConceptsPsoralen modificationMouse DNAGenomic mouse DNAPsoralen photoadductsSequence-specific bindingSequence-specific modificationNucleic acid secondary structureTarget site modificationMammalian genomesAcid secondary structureChromatin structureTriplex binding siteDNA repairTransgenic miceGenomeSequence specificitySecondary structureViral genomeSupF geneDNABinding sitesMutagenesisSite modificationSpecific sitesTriple helix