2024
An epigenetic timer regulates the transition from cell division to cell expansion during Arabidopsis petal organogenesis
Huang R, Irish V. An epigenetic timer regulates the transition from cell division to cell expansion during Arabidopsis petal organogenesis. PLOS Genetics 2024, 20: e1011203. PMID: 38442104, PMCID: PMC10942257, DOI: 10.1371/journal.pgen.1011203.Peer-Reviewed Original ResearchMeSH KeywordsArabidopsisArabidopsis ProteinsCell DivisionEpigenesis, GeneticFlowersGene Expression Regulation, PlantTranscription FactorsConceptsCell division to cell expansionCell divisionCell expansionRemodeling of chromatin accessibilityResponse to environmental changesRNA polymerase activityPlant developmental timingRegulate developmental eventsMultiple cell divisionsDownstream direct targetsCorepressor TOPLESSArabidopsis petalsChromatin accessibilityHistone modificationsPetal developmentEpigenetic stateTranscriptional repressorPetal organogenesisPolymerase activityEpigenetic memoryPetal primordiaPlant organogenesisCell cycleEpigenetic factorsControl organogenesis
2015
Temporal Control of Plant Organ Growth by TCP Transcription Factors
Huang T, Irish VF. Temporal Control of Plant Organ Growth by TCP Transcription Factors. Current Biology 2015, 25: 1765-1770. PMID: 26073137, DOI: 10.1016/j.cub.2015.05.024.Peer-Reviewed Original ResearchConceptsPost-mitotic cell expansionCell divisionArabidopsis petalsPetal developmentCell expansionCIN-TCP genesTCP transcription factorsZinc finger transcriptional repressorPlant organ growthCell cycle progressionPetal organogenesisTranscriptional repressorOrgan formRepression resultsTranscription factorsPetal initiationOrgan growthDevelopmental eventsLamina growthExcellent modelTemporal controlCell proliferationPetalsDivisionTurn act
2008
An Arabidopsis F-box protein acts as a transcriptional co-factor to regulate floral development
Chae E, Tan Q, Hill TA, Irish VF. An Arabidopsis F-box protein acts as a transcriptional co-factor to regulate floral development. Development 2008, 135: 1235-1245. PMID: 18287201, DOI: 10.1242/dev.015842.Peer-Reviewed Original ResearchConceptsUNUSUAL FLORAL ORGANSAP3 promoterLFY activityTranscription factorsProtein degradationFloral homeotic gene expressionLEAFY transcription factorFloral homeotic genesHomeotic gene expressionTranscriptional repressor domainF-box proteinsSCF ubiquitin ligaseF-box componentAPETALA3 (AP3) geneHomeotic genesRepressor domainFloral organsFlower developmentPlant speciesTranscriptional complexPlants flowerProtein actsFloral developmentUbiquitin ligaseEndogenous signals
1999
Patterning the Flower
Irish V. Patterning the Flower. Developmental Biology 1999, 209: 211-220. PMID: 10328916, DOI: 10.1006/dbio.1999.9226.Peer-Reviewed Original ResearchEvolution of genetic mechanisms controlling petal development
Kramer E, Irish V. Evolution of genetic mechanisms controlling petal development. Nature 1999, 399: 144-148. PMID: 10335842, DOI: 10.1038/20172.Peer-Reviewed Original ResearchConceptsGenetic mechanismsB-class genes APETALA3Expression patternsOrgan identity genesClasses of genesPI homologuesStamen identityMolecular genetic studiesOrgan identityArabidopsis thalianaPetal developmentFloral organsHigher eudicotsFlowering plantsAPETALA3Angiosperm petalsGenetic studiesGenesOrthologuesAngiospermsPetalsExpressionEudicotsThalianaHomologues
1998
Molecular Evolution of Genes Controlling Petal and Stamen Development: Duplication and Divergence Within the APETALA3 and PISTILLATA MADS-Box Gene Lineages
Kramer E, Dorit R, Irish V. Molecular Evolution of Genes Controlling Petal and Stamen Development: Duplication and Divergence Within the APETALA3 and PISTILLATA MADS-Box Gene Lineages. Genetics 1998, 149: 765-783. PMID: 9611190, PMCID: PMC1460198, DOI: 10.1093/genetics/149.2.765.Peer-Reviewed Original ResearchMeSH KeywordsAmino Acid SequenceArabidopsis ProteinsEvolution, MolecularGenes, PlantHomeodomain ProteinsMADS Domain ProteinsMolecular Sequence DataMultigene FamilyPapaverPhylogenyPlant ProteinsPlant StructuresPlants, MedicinalSequence AlignmentSequence Analysis, DNASequence Homology, Amino AcidSolanum lycopersicumTranscription FactorsConceptsDuplication eventsGene lineagesLower eudicotHigher eudicotsPI genesMADS-box gene familyMajor duplication eventsFloral organ identityMultiple duplication eventsAP3 lineageStamen identityOrgan identityEudicot lineagesHomeotic genesDicot speciesMolecular evolutionStamen developmentGene familyAPETALA3Such genesEudicotsPistillataLineagesGenesSimilar functions
1996
Cellular Interactions Mediated by the HomeoticPISTILLATAGene Determine Cell Fate in theArabidopsisFlower
Bouhidel K, Irish V. Cellular Interactions Mediated by the HomeoticPISTILLATAGene Determine Cell Fate in theArabidopsisFlower. Developmental Biology 1996, 174: 22-31. PMID: 8626018, DOI: 10.1006/dbio.1996.0048.Peer-Reviewed Original ResearchConceptsMeristematic cellsShoot apical meristem cellsShoot apical meristemDetermines cell fateCell-cell communicationApical meristem cellsDifferentiation of cellsArabidopsis plantsInner tissue layersArabidopsis flowersCoordinated divisionFloral organsPISTILLATA genesCell fateApical meristemFate mapMeristem cellsFloral primordiaChromosomal deletionsCellular interactionsFlowersEpidermal tissueInternal tissuesCellsPistillata
1989
The Drosophila posterior-group gene nanos functions by repressing hunchback activity
Irish V, Lehmann R, Akam M. The Drosophila posterior-group gene nanos functions by repressing hunchback activity. Nature 1989, 338: 646-648. PMID: 2704419, DOI: 10.1038/338646a0.Peer-Reviewed Original Research