Project description:Understanding stem cell regulatory circuits is the next challenge in plant biology, as these cells are essential for tissue growth and organ regeneration in response to stress. In the Arabidopsis primary root apex, stem-cell specific transcription factors BRAVO and WOX5 co-localize in the Quiescent Center (QC) cells, where they commonly repress cell division so that these cells can act as a reservoir to replenish surrounding stem cells, yet their molecular connection remains unknown. Genetic and biochemical analysis indicates that BRAVO and WOX5 form a transcription factor complex that modulates gene expression in the QC cells to preserve overall root growth and architecture. Furthermore, by using mathematical modeling we establish that BRAVO uses the WOX5/BRAVO complex to promote WOX5 activity in the stem cells. Our results unveil the importance of transcriptional regulatory circuits in plant stem cell development.

Project description:The Arabidopsis quiescent center (QC) is a small group of cells with low mitotic activity located at the center of the root stem cell niche. Its transcriptional profile was previously analyzed using two repeats of cells FACS isolated using the WOX5 marker. To get more power in analyzing QC transcriptional profile, we generated three additional samples of the QC, using the QC-specific marker WOX5.

Project description:The Arabidopsis quiescent center (QC) is a small group of cells with low mitotic activity located at the center of the root stem cell niche. Its transcriptional profile was previously analyzed using two repeats of cells FACS isolated using the AGL42 marker. To get more power in analyzing QC transcriptional profile, we generated three additional samples of the QC, using the QC-specific marker WOX5. Three replicates of FACS-sorted GFP-positive cells from WOX5:GFP roots.

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.

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:WOX5 maintains columella stem cells in the Arabidopsis root and prevents their differentiation. In order to understand the molecular mode of WOX5 action the genes differentially expressed by WOX5 inducible over-expression were determined by analysis of microarray hybridizations. Seedlings transformed with a dexamethasone inducible WOX5 construct were induced for one or four hours with dexamethasone or a mock solution. Other seedlings were treated one hour with cycloheximide ( a protein synthesis inhibitor to reduce secondary transcriptional effects after WOX5 activation) and either dexamethasone or a mock solution. Root tips were harvested, RNA extracted, and the RNA samples prepared for hybridization to Affymetrix microarrays. Potential target genes of WOX5 were further analyzed by transcriptional markers, qPCR and EMSA (electrophoretic mobility shift assay).

Project description:To demonstrate our method of controlling for technical noise in single-cell RNA-seq experiments we manually collected single A. thaliana cells marked by the expression of green fluorescent protein (GFP) driven by either the GL2 or WOX5 promoters. Seven and six cells were collected from each cell type, respectively. The GL2 promoter marks the non-hair cells in the root epidermis whereas the WOX5 promoter specifies the quiescent center (QC) of the root. Each cell selected was processed together with 50 pg of total HeLa RNA spike-in to prepare RNA-seq libraries using the Tang protocol. For comparison, we again added the commercially available ERCC spike-ins. We also performed RNA-seq on a set of technical replicates of total A. thaliana RNA using starting amounts ranging from 5000pg down to 10pg, a range that covers the RNA content obtainable from single cells of various sizes.

Project description:We isolated QC and CEI cells and obtained their cell-type specific transcriptional profiles in a WT and in a wox5 mutant background by sorting GFP+ cells marked with pWOX5::GFP and pCYCD6::GFP.

Project description:We report the discovery of a root growth program in Arabidopsis that is independent of a functional quiescent center (QC). In this regulatory program, PHABULOSA (PHB), posttranscriptionally regulated by SHR and SCR, plays a central role. In phb shr and phb scr mutants, root meristem/growth activity recovers significantly. Interestingly, this recovery does not accompany the resurgence of QC cells. PHB regulates apical root growth in stele cells of the root meristem, located proximal to the QC. Our genome-wide investigation suggests that PHB exerts its influence on root growth by regulating auxin-cytokinin homeostasis. Apical root growth was restored when cytokinin levels were genetically reduced in the shr mutant. Conversely, when miRNA-resistant PHB was expressed in the root stele cells, apical root growth and meristem functions were significantly inhibited without blocking the QC identity. Taken together, our investigation reveals two mechanisms through which SHR regulates root growth and stem cell activities: one is to specify and maintain the QC and the other is to regulate the proximal meristem activity through PHB and cytokinin. In this regulation, QC seems to be more involved in maintaining the “growth signal” and thus ensure the indeterminate root growth.

Project description:To reveal how ARF10 and ARF16 regulate Al-induced root-growth inhibition, a transcriptome analysis was carried out by comparing without and with Al-exposed arf10/16 double mutant line and WT through RNA sequencing. The present transcriptomic analysis has revealed that many of the differentially transcribed genes associated with cell wall modification were regulated by transcription factors ARF10 and ARF16. The implication is that the auxin-regulated Al-induced inhibition of root growth arises from auxin signalling-regulated cell wall structure or component modification.