Project description:bri1-5 is a weak mutant of Brassinosteroid Insensitive 1 (BRI1). Suppressors by activation tagging bri1-1D, brs1-1D and bak1-1D can recover bri1-5 phenotype. We use microarray to investigate which pathways or functional categories have been transcriptionally regulated by bri1-1D, brs1-1D and bak1-1D. Whole seedlings from wild-type (WS2), bri1-5, bri1-5/brs1-1D, bri1-5/bak1-1D, bri1-5/bri1-1D. Three biological replicates for each genotype.

Project description:bri1-5 is a weak mutant of Brassinosteroid Insensitive 1 (BRI1). Suppressors by activation tagging bri1-1D, brs1-1D and bak1-1D can recover bri1-5 phenotype. We use microarray to investigate which pathways or functional categories have been transcriptionally regulated by bri1-1D, brs1-1D and bak1-1D.

Project description:Microtubule-associated CLASP balances brassinosteroid signaling through negative feedback to sustain plant cell proliferation

Project description:Brassinosteroid hormones are essential for growth and development in seed plants. In Arabidopsis, transcriptional factors from the AtBES1 (BRI1-EMS-SUPPRESSOR1)/AtBZR1 (BRASSINAZOLE-RESISTANT 1) family, are main regulators of steroid phytohormone Brassinosteroids, which finely coordinate gene expression. While genome sequence analysis in Marchantia polymorpha failed to identify BR receptors homologues to the BRI1-family, a homologue of downstream BR-regulated BES1/BZR1 transcription factors is present. Here, we decipher the biological function of MpBES1 in liverwort. Mpbes1 knock out plants have impaired thallus development, pointing up the conservation of BES1 function in organ development. RNAseq analysis of Mpbes1 reveals a prominent deregulation of oxidation processes, responses to stress and carbohydrate metabolism. Furthermore, in the Arabidopsis orthologs of Mpbes1 deregulated genes, described targets of AtBES1/BZR1 are overrepresented, suggesting a major conservation in the signaling module. In conclusion, this study unravels the origin of BES1/BZR1 family of transcriptional factors in plant cell division.

Project description:Molecular genetic analyses support a central role of BZR1 in Brassinosteroid (BR) regulation of plant development. The dominant bzr1-1D mutation, which stabilizes the BZR1 protein, completely suppresses the de-etiolated phenotype of the null bri1-116 mutant grown in the dark. Using microarray analysis, we identified genes differentially expressed in bri1-116 compared to wild type and genes differentially expressed in the bzr1-1D;bri1-116 double mutant compared to the bri1-116 single mutant. Consistent with the phenotypic suppression of bri1-116 by bzr1-1D, about 80% of the genes affected in bri1-116 were affected oppositely by bzr1-1D BZR1 regulated genes were generated from comparing genes differentially expressed by bzr1-1D;bri1-116 and bri1-116. Genes affected by BRI1 were generated from comparing differentially expressed genes of bri1-116 and Col control. ANOVA was used to find genes whose expression was different between bzr1-1D;bri1-116 and bri1-116 or between bri1-116 and Col samples [see Supplementary file below].

Project description:Molecular genetic analyses support a central role of BZR1 in Brassinosteroid (BR) regulation of plant development. The dominant bzr1-1D mutation, which stabilizes the BZR1 protein, completely suppresses the de-etiolated phenotype of the null bri1-116 mutant grown in the dark. Using microarray analysis, we identified genes differentially expressed in bri1-116 compared to wild type and genes differentially expressed in the bzr1-1D;bri1-116 double mutant compared to the bri1-116 single mutant. Consistent with the phenotypic suppression of bri1-116 by bzr1-1D, about 80% of the genes affected in bri1-116 were affected oppositely by bzr1-1D

Project description:Analysis of brassinosteroid (BR) and auxin effects on gene expression in Arabidopsis roots. Our genomic results indicate that BR and auxin induce largely opposite gene expression responses in primary roots. RNA-Seq for 7-day-old Arabidopsis Col-0, dwf4, bri1-116, and bri1-116;bzr1-1D roots grown on regular medium and treated with brassinolide, auxin or mock solution for 4 hr.

Project description:The quiescent center (QC) plays an essential role during root development by creating a microenvironment that preserves the stem cell fate of its surrounding cells. Strikingly, in order to retain root structure, QC cells only occasionally self-renew, displaying a proliferation rate far below that of all other cells within the root meristem. Previously, the APC/CCCS52A2 ubiquitine ligase and brassinosteroid signaling pathways have been found to antagonistically control Arabidopsis thaliana QC cell proliferation. Here, we demonstrate that both pathways converge on the ERF115 transcription factor that acts as a rate-limiting factor of QC cell division through transcriptional control of the autocrine phytosulfokine PSK5 peptide hormone. ERF115 marks QC cell division but is restrained through proteolysis by the APC/CCCS52A2 ubiquitine ligase, whereas QC proliferation is driven by brassinosteroid-dependent ERF115 expression. Combined, these two antagonistic mechanisms delimit the ERF115-PSK5 activity and QC renewal. Our results reveal a unique cell cycle regulatory mechanism that accounts for the low proliferation rate of QC cells within a surrounding population of highly mitotic active cells. ChIP-seq analysis of genes bound by the ERF115 transcription factor, using mock ChIP with wild type cells as negative control. Analyzed by Illumina HiSeq

Project description:Plant photomorphogenesis and skotomorphogenesis depend on interplay of various plant hormones. Brassinosteroids (BRs) play crucial roles during hypocotyl establishment both in the light and darkness. Arabidopsis brassinosteroid insensitive1 (bri1-5) is a partial loss-of-function mutant, and the short-hypocotyl phenotype of bri1-5 is greatly suppressed by a long-hypocotyl mutant phytochrome B (pbyB-77) at the double mutant for the two in the light conditions to display additive phenotypes of both. To identify the genes responsible for this genetic interaction, we employed microarray analysis with the RNAs prepared from wild type, bri1-5, phyB-77, and bri1-5 phyB-77 double mutant. Microarray analysis supported the notion that PHYB acts upstream of BRs. Total RNAs were isolated from four different genotypes: wild type, bri1-5, gul2-1/phyB-77, bri1-5 gul2-1 double mutant, and the RNAs were subjected to microarray analysis using Affymetrix GenChip arrays. Three biological replicates for each genotype resulted in 12 experiments.

Project description:The quiescent center (QC) plays an essential role during root development by creating a microenvironment that preserves the stem cell fate of its surrounding cells. Strikingly, in order to retain root structure, QC cells only occasionally self-renew, displaying a proliferation rate far below that of all other cells within the root meristem. Previously, the APC/CCCS52A2 ubiquitine ligase and brassinosteroid signaling pathways have been found to antagonistically control Arabidopsis thaliana QC cell proliferation. Here, we demonstrate that both pathways converge on the ERF115 transcription factor that acts as a rate-limiting factor of QC cell division through transcriptional control of the autocrine phytosulfokine PSK5 peptide hormone. ERF115 marks QC cell division but is restrained through proteolysis by the APC/CCCS52A2 ubiquitine ligase, whereas QC proliferation is driven by brassinosteroid-dependent ERF115 expression. Combined, these two antagonistic mechanisms delimit the ERF115-PSK5 activity and QC renewal. Our results reveal a unique cell cycle regulatory mechanism that accounts for the low proliferation rate of QC cells within a surrounding population of highly mitotic active cells.