2017
HOW DOES THE SILENCING OF THE INFLAMMATION MEDIATOR GENE: FAT10, EXTEND LIFESPAN IN MICE?
Canaan A, Arjona C, Gulez B, Seay M, Zhang J, Henegariu O, Garcia Milian R. HOW DOES THE SILENCING OF THE INFLAMMATION MEDIATOR GENE: FAT10, EXTEND LIFESPAN IN MICE? Innovation In Aging 2017, 1: 978-978. PMCID: PMC6185008, DOI: 10.1093/geroni/igx004.3533.Peer-Reviewed Original ResearchDifferential gene expressionRNA sequence analysisStem cell populationNovel mechanistic insightsAdipogenic transcription factorsAdipocyte metabolic functionMammalian agingHematopoietic stem cellsTranscription factorsGene expressionPathway analysisPleiotropic natureKnockout miceFAT10 geneMaximal lifespanDruggable targetsMetabolic functionsStem cellsTRANSFAC analysisFAT10Mediator genesMechanistic insightsMost tissuesCell populationsGenes
2001
Alteration in expression of the rat mitochondrial ATPase 6 gene during Pneumocystis carinii infection
Asnicar M, Henegariu O, Shaw M, Goheen M, Bartlett M, Smith J, Lee C. Alteration in expression of the rat mitochondrial ATPase 6 gene during Pneumocystis carinii infection. BMC Microbiology 2001, 1: 8. PMID: 11446902, PMCID: PMC34520, DOI: 10.1186/1471-2180-1-8.Peer-Reviewed Original ResearchConceptsATPase 6 geneMitochondrial ATPase 6 geneHost cellsF0F1-ATP synthase complexTwo-color fluorescentMRNA differential displaySitu hybridizationATPase 6 mRNANorthern blot analysisATPase 6Synthase complexSurfactant protein BNucleotide sequenceDifferential displayDNA fragmentsGenesCell typesClara cellsMolecular levelProtein BBlot analysisType II pneumocytesTotal RNASame cellsRespiratory tree
1998
Molecular cytogenetic analysis of patients with holoprosencephaly and structural rearrangements of 7q
Vance G, Nickerson C, Sarnat L, Zhang A, Henegariu O, Morichon‐Delvallez N, Butler M, Palmer C. Molecular cytogenetic analysis of patients with holoprosencephaly and structural rearrangements of 7q. American Journal Of Medical Genetics 1998, 76: 51-57. PMID: 9508065, PMCID: PMC6775641, DOI: 10.1002/(sici)1096-8628(19980226)76:1<51::aid-ajmg9>3.0.co;2-s.Peer-Reviewed Original ResearchMeSH KeywordsCell LineChromosome AberrationsChromosome DeletionChromosomes, Human, Pair 13Chromosomes, Human, Pair 22Chromosomes, Human, Pair 7CytogeneticsFemaleGenetic MarkersHedgehog ProteinsHoloprosencephalyHumansIn Situ Hybridization, FluorescenceInfantInfant, NewbornKaryotypingMaleMosaicismPolymerase Chain ReactionProteinsTrans-ActivatorsTranslocation, GeneticConceptsSonic hedgehog geneHedgehog geneCell linesDifferent chromosome regionsStructural rearrangementsHuman Sonic Hedgehog genePatient cell linesMolecular cytogenetic analysisChromosome regionsChromosome 7Embryonic forebrainLong armGenesSitu hybridizationPolymerase chain reaction amplificationHPE3Chain reaction amplificationCytogenetic analysisMidline cleavageReaction amplificationRearrangementPhenotypeCritical regionLinesHybridization
1995
The human A1 adenosine receptor: ligand binding properties, sites of somatic expression and chromosomal localization
Rivkees S, Lasbury M, Stiles G, Henegariu O, Curtis C, Vance G. The human A1 adenosine receptor: ligand binding properties, sites of somatic expression and chromosomal localization. Endocrine 1995, 3: 623-629. PMID: 21153220, DOI: 10.1007/bf02746338.Peer-Reviewed Original ResearchA1AR geneHuman-rodent somatic cell hybridsChromosome 1Human A1ARHuman chromosome 1Somatic cell hybridsLigand binding propertiesChromosomal localizationChromosomal locationMammalian biologyCell hybridsGene expressionNorthern analysisGenesCHO cellsImportant biological effectsLong armPCR analysisSouthern blottingSitu hybridizationHuman A1 adenosine receptorSomatic expressionHigh-affinity receptorHuman physiologyHuman tissues