Project description:Plant secondary growth is driven by two concentric meristems, the inner vascular cambium and outer cork cambium. The periclinal cell divisions of both meristems, providing thickness and protection to plant organs, are activated with a delay after the primary development. Cytokinins and a set of downstream transcription factors are key players in promoting transition from primary to secondary development, however it is unknown whether other factors play a role in this transition. Here, using time-course transcriptome analysis of cytokinin-treated, cytokinin deficient isopentenyltransferase1,3,5,7 (ipt1,3,5,7) mutant we show that during cambium activation cytokinins positively regulate auxin and TRACHEARY ELEMENT DIFFERENTIATION INHIBITORY FACTOR (TDIF) peptide signaling in Arabidopsis (Arabidopsis thaliana) root. Correspondingly, mutants defective in TDIF peptide signaling displayed reduced cytokinin-induced secondary growth and auxin signaling was found to be required for proper cytokinin response. Additionally, auxin and cytokinin signaling transiently overlapped in activating procambial cells and acted additively in promoting secondary development. Network analysis revealed that transcription factors belonging to the DNA-BINDING WITH ONE FINGER (DOF) and ETHYLENE RESPONSE FACTOR (ERF) gene families are regulated by cytokinin during cambium activation and mutant analysis demonstrated delayed cambium activation and xylem formation phenotypes. Overall, we find that cytokinin, auxin and TDIF form a tightly intertwined network of positive regulators for activation of secondary growth in the Arabidopsis root indicating extensive redundancy in this process.

Project description:Plant secondary growth is driven by two concentric meristems, the inner vascular cambium and outer cork cambium. The periclinal cell divisions of both meristems, providing thickness and protection to plant organs, are activated with a delay after the primary development. Cytokinins and a set of downstream transcription factors are key players in promoting transition from primary to secondary development, however it is unknown whether other factors play a role in this transition. Here, using time-course transcriptome analysis of cytokinin-treated, cytokinin deficient isopentenyltransferase1,3,5,7 (ipt1,3,5,7) mutant we show that during cambium activation cytokinins positively regulate auxin and TRACHEARY ELEMENT DIFFERENTIATION INHIBITORY FACTOR (TDIF) peptide signaling in Arabidopsis (Arabidopsis thaliana) root. Correspondingly, mutants defective in TDIF peptide signaling displayed reduced cytokinin-induced secondary growth and auxin signaling was found to be required for proper cytokinin response. Additionally, auxin and cytokinin signaling transiently overlapped in activating procambial cells and acted additively in promoting secondary development. Network analysis revealed that transcription factors belonging to the DNA-BINDING WITH ONE FINGER (DOF) and ETHYLENE RESPONSE FACTOR (ERF) gene families are regulated by cytokinin during cambium activation and mutant analysis demonstrated delayed cambium activation and xylem formation phenotypes. Overall, we find that cytokinin, auxin and TDIF form a tightly intertwined network of positive regulators for activation of secondary growth in the Arabidopsis root indicating extensive redundancy in this process.

Project description:Plant secondary growth is driven by two concentric meristems, the inner vascular cambium and outer cork cambium. The periclinal cell divisions of both meristems, providing thickness and protection to plant organs, are activated with a delay after the primary development. Cytokinins and a set of downstream transcription factors are key players in promoting transition from primary to secondary development, however it is unknown whether other factors play a role in this transition. Here, using time-course transcriptome analysis of cytokinin-treated, cytokinin deficient isopentenyltransferase1,3,5,7 (ipt1,3,5,7) mutant we show that during cambium activation cytokinins positively regulate auxin and TRACHEARY ELEMENT DIFFERENTIATION INHIBITORY FACTOR (TDIF) peptide signaling in Arabidopsis (Arabidopsis thaliana) root. Correspondingly, mutants defective in TDIF peptide signaling displayed reduced cytokinin-induced secondary growth and auxin signaling was found to be required for proper cytokinin response. Additionally, auxin and cytokinin signaling transiently overlapped in activating procambial cells and acted additively in promoting secondary development. Network analysis revealed that transcription factors belonging to the DNA-BINDING WITH ONE FINGER (DOF) and ETHYLENE RESPONSE FACTOR (ERF) gene families are regulated by cytokinin during cambium activation and mutant analysis demonstrated delayed cambium activation and xylem formation phenotypes. Overall, we find that cytokinin, auxin and TDIF form a tightly intertwined network of positive regulators for activation of secondary growth in the Arabidopsis root indicating extensive redundancy in this process.

Project description:Clubroot (Plasmodiophora brassicae) is a pathogen of Brassicaceae that causes significant reductions in yield as a consequence of gall formation in the root and hypocotyl of infected plants. The pathogen hijacks host vascular cambium development and cytokinins are implicated in this process. Microarray analysis was used to investigate changes in cytokinin metabolism during gall formation of clubroot-infected ipt1;3;5;7 mutants Arabidopsis thaliana. These mutants have severely restricted synthesis of host cytokinins (isopentenyl adenine and trans zeatin) and fail to form a vascular cambium and, as a consequence, do not undergo secondary thickening. Infection of these mutants allows the impact of pathogen-derived cytokinin synthesis to be observed.

Project description:Clubroot (Plasmodiophora brassicae) is a pathogen of Brassicaceae that causes significant reductions in yield as a consequence of gall formation in the root and hypocotyl of infected plants. The pathogen hijacks host vascular cambium development and cytokinins are implicated in this process. RNASeq was used to investigate changes in cytokinin metabolism during gall formation of clubroot-infected Arabidopsis thaliana. RNASeq analysis of infected tissue showed that host cytokinin metabolism was strongly down-regulated both at the onset (16 DPI) and late (26 DPI) stages of gall formation. Expression of host genes associated with cytokinin biosynthesis, signalling, degradation and conjugation was strongly repressed. Two isopentenyltransferase genes associated with cytokinin biosynthesis are present in the P. brassicae genome and are expressed throughout gall formation.

Project description:Wood constitutes the majority of terrestrial biomass.Composed of xylem, it arises from one side of the vascular cambium, a bifacial stem cell niche that also produces phloem on the opposing side. It is currently unknown which molecular factors endowcambium stem cell identity. Here we show that TDIF ligand-activated PXY receptors promote the expression of CAMBIUM AINTEGUMENTA-LIKE (CAIL) transcription factors to define cambium stem cell identity inthe Arabidopsisroot. By sequestrating the phloem-originated TDIF, xylem-dependent PXY confines the TDIF signaling front, resulting in the activation of CAIL expression and stem cell identity in only a narrow domain. Our findings show how signals emanating from cells on opposing sides ensure robust yet dynamically adjustable positioning of a bifacial stem cell.

Project description:In-vivo induced establishment and activity of the interfascicular cambium in Arabidopsis thaliana stems under NPA treatments. We used microarrays to detail the global programme of gene expression underlying the establishment and activity of the interfascicular cambium. 3 mm stem pieces were collected after being in treated with NPA for a week in order to stop the polar auxin transport and induce secondary growth. Collected samples were used for RNA extraction and hybridization on Affymetrix microarrays. We aimed to obtain genes responsible for auxin-induced cambium establishment and activity.

Project description:Currently little is known about the genetic mechanisms regulating the vascular cambium or the secondary growth of stems. We show here that the Populus Class I KNOX homeobox gene ARBORKNOX2 (ARK2) regulates both cell division in the cambium region and the differentiation of daughter cells in secondary xylem and phloem. ARK2 is expressed in the shoot apical meristem, and the vascular cambium region, reflecting some overlap in the regulation of these meristems. ARK2 is expressed broadly in the cambium region and in differentiating lignified cells types before becoming progressively restricted to the cambium. Populus overexpressing ARK2 present stem phenotypes with precocious cambium formation, delayed differentiation of cambium daughter cells, a wider cambium region, and ultimately less phloem fibers and secondary xylem. In contrast, Populus expressing RNAi or amicroRNA that target ARK2 transcripts present precocious differentiation of secondary phloem fibers and xylem, and ultimately more secondary xylem tissue and thicker secondary cell walls in phloem fibers and secondary xylem cells. These phenotypes in turn correlate with changes in the expression of genes affecting cell division, auxin, and cell wall synthesis and lignification that indicate that ARK2 primarily affects woody tissue development by regulation of cell differentiation. Notably, wood properties associated with secondary cell wall synthesis are negatively associated with ARK2 expression, including lignin and cellulose content. Together, our results suggest that ARK2 functions primarily by negatively regulating cell differentiation during secondary growth. We propose that ARK2 may identify a co-evolved regulatory module that influences complex wood properties relevant to ecological, industrial, and biofuels applications.

Project description:Spatiotemporal control over developmental programs is vital to all organisms. Here we show that deficiency in cytokinin signaling or biosynthesis leads to early secondary cell wall (SCW) formation in Arabidopsis inflorescence stem that associates with precocious upregulation of a SCW transcriptional cascade controlled by NAC TFs (NSTs/VNDs). We demonstrate that cytokinin signaling through the AHK2/3 and the ARR1/10/12 suppresses the expression of several NSTs/VNDs and SCW formation in the apical portions of stems. Exogenous cytokinin application led to fast downregulation of NST1 and NST3 (NST1/3) and VND6/7 in the WT and reconstituted both proper development and apical-basal gradient of NST1/3 expression in a cytokinin biosynthesis-deficient mutant. We show that AHK2 and AHK3 required functional NST1 or NST3 to control SCW initiation in the interfascicular fibers, further evidencing that cytokinins act upstream of NSTs transcription factors. The premature onset of a rigid SCW biosynthesis and altered expression of NST1/3 and VND6/7 due to cytokinin deficiency led to the formation of smaller tracheary elements (TEs) and impaired hydraulic conductivity. We conclude that cytokinins downregulate NSTs to inhibit premature SCW formation in the apical part of the inflorescence stem, facilitating thus the development of fully functional TEs and interfascicular fibers.

Project description:Injured plant somatic tissues regenerate themselves by establishing the shoot or root meristems. In Arabidopsis (Arabidopsis thaliana) a two-step culture system ensures regeneration by first promoting the acquisition of pluripotency and subsequently specifying the fate of new meristems. Although previous studies have reported the importance of phytohormones auxin and cytokinin in determining the fate of new meristems, it remains elusive whether and how the environmental factors influence this process. In this study, we investigated the impact of light signals on shoot regeneration using Arabidopsis hypocotyl as explants. We found that light signals promote shoot regeneration while inhibiting root formation. ELONGATED HYPOCOTYL 5 (HY5), the pivotal transcriptional factor in light signaling, plays a central role in this process by mediating the expression of key genes controlling the fate of new meristems. Specifically, HY5 directly represses root development genes and activates shoot meristem genes, leading to the establishment of shoot progenitor from pluripotent callus. We further demonstrated that the early activation of photosynthesis is critical for shoot initiation, and this is transcriptionally regulated downstream of the HY5-dependent pathways. In conclusion, we uncovered the intricate molecular mechanisms by which light signals control the establishment of new meristem through the regulatory network governed by HY5, thus, highlighting the influence of light signals on plant developmental plasticity.