2023
Systematic characterization of photoperiodic gene expression patterns reveals diverse seasonal transcriptional systems in Arabidopsis
Leung C, Tarté D, Oliver L, Wang Q, Gendron J. Systematic characterization of photoperiodic gene expression patterns reveals diverse seasonal transcriptional systems in Arabidopsis. PLOS Biology 2023, 21: e3002283. PMID: 37699055, PMCID: PMC10497145, DOI: 10.1371/journal.pbio.3002283.Peer-Reviewed Original ResearchConceptsExpression patternsCis-element analysisPhenylpropanoid biosynthesis pathwaySeasonal expression patternsImportant cellular pathwaysGene expression patternsThousands of genesFunctional enrichment analysisGene expression dataAlign growthArabidopsis plantsPhotoperiodic floweringTranscriptional networksPhotoperiodic genesBiosynthesis pathwayCellular processesPhenylpropanoid pathwayTranscriptomic experimentsTranscriptomic dataTranscriptional systemCellular pathwaysEnrichment analysisGene expressionGene clusteringExpression data
2019
Decoys provide a scalable platform for the identification of plant E3 ubiquitin ligases that regulate circadian function
Feke A, Liu W, Hong J, Li MW, Lee CM, Zhou EK, Gendron JM. Decoys provide a scalable platform for the identification of plant E3 ubiquitin ligases that regulate circadian function. ELife 2019, 8: e44558. PMID: 30950791, PMCID: PMC6483598, DOI: 10.7554/elife.44558.Peer-Reviewed Original ResearchConceptsE3 ubiquitin ligasesUbiquitin ligasesCircadian clockCircadian functionPlant E3 ubiquitin ligasesTransgenic Arabidopsis plantsNew potential regulatorsArabidopsis plantsRegulated degradationPlant developmentClock proteinsClock regulatorsFunctional redundancyE3 ubiquitinProtein degradationGenetic challengesLigasesPotential regulatorCircadian periodScreening platformUbiquitinRegulatorDecoysSplicingClock