Project description:De novo shoot organogenesis (DNSO) is a commonly used pathway for plant biotechnology, and is a hormonally regulated process, where auxin and cytokinin coordinates suites of genes encoding transcription factors, general transcription factors, and RNA metabolism machinery genes. Here we report that silencing Arabidopsis thaliana CTD phosphatase-like 4 (CPL4RNAi), which increases phosphorylation level of RNA polymerase II (pol II) CTD, altered lateral root development and DNSO efficiency of the host plants, suggesting an importance of precise control of pol II activities during DNSO. Under standard condition, roots of CPL4RNAi lines produced no or few lateral roots. When induced by high concentration of auxin, CPL4RNAi lines failed to produce focused auxin maxima at the meristem of lateral root primordia, and produced fasciated lateral roots. By contrast, root explants of CPL4RNAi lines were highly competent for DNSO. Efficient DNSO of CPL4RNAi lines were observed even under 10 times less cytokinin required for wild type explants. Transcriptome analysis showed CPL4RNAi but not wild type explants expressed high levels of shoot meristem related genes during priming by high auxin/cytokinin ratio, and subsequent shoot induction with cytokinin. These results indicate that CPL4 functions as a repressor of the early stage of DNSO, during acquisition of competency by high auxin/cytokinin ratio, perhaps via regulation of pol II activities.

Project description:C-terminally encoded peptides (CEPs) are peptide hormones that function as mobile signals coordinating crucial developmental programs in plants. Previous studies have revealed that CEPs exert negative regulation on root development through interaction with CEP receptors (CEPRs), CEPR DOWNSTREAMs (CEPDs), the cytokinin receptor ARABIDOPSIS HISTIDINE KINASE (AHKs) and the transcriptional repressor Auxin/Indole-3-Acetic Acid (AUX/IAA). However, the precise molecular mechanisms underlying CEPs-mediated regulation of root development via auxin and cytokinin signaling pathways still necessitate further detailed investigation. In this study, we examined prior research and elucidated the underlying molecular mechanisms. The results showed that both synthetic AtCEPs and overexpression of AtCEP5 markedly supressed primary root elongation and lateral root (LR) formation in Arabidopsis. Molecular biology and genetics elucidated how CEPs inhibit root growth by suppressing auxin signaling while promoting cytokinin signaling. In summary, this study elucidated the inhibitory effects of AtCEPs on Arabidopsis root growth and provided insights into their potential molecular mechanisms, thus enhancing our comprehension of CEP-mediated regulation of plant growth and development.

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: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:This model is from the article: The influence of cytokinin-auxin cross-regulation on cell-fate determination in Arabidopsis thaliana root development Muraro D, Byrne H, King J, Voss U, Kieber J, Bennett M. J Theor Biol.2011 Aug 21;283(1):152-67. PMID: 21640126, Abstract: Root growth and development in Arabidopsis thaliana are sustained by a specialised zone termed the meristem, which contains a population of dividing and differentiating cells that are functionally analogous to a stem cell niche in animals. The hormones auxin and cytokinin control meristem size antagonistically. Local accumulation of auxin promotes cell division and the initiation of a lateral root primordium. By contrast, high cytokinin concentrations disrupt the regular pattern of divisions that characterises lateral root development, and promote differentiation. The way in which the hormones interact is controlled by a genetic regulatory network. In this paper, we propose a deterministic mathematical model to describe this network and present model simulations that reproduce the experimentally observed effects of cytokinin on the expression of auxin regulated genes. We show how auxin response genes and auxin efflux transporters may be affected by the presence of cytokinin. We also analyse and compare the responses of the hormones auxin and cytokinin to changes in their supply with the responses obtained by genetic mutations of SHY2, which encodes a protein that plays a key role in balancing cytokinin and auxin regulation of meristem size. We show that although shy2 mutations can qualitatively reproduce the effect of varying auxin and cytokinin supply on their response genes, some elements of the network respond differently to changes in hormonal supply and to genetic mutations, implying a different, general response of the network. We conclude that an analysis based on the ratio between these two hormones may be misleading and that a mathematical model can serve as a useful tool for stimulate further experimental work by predicting the response of the network to changes in hormone levels and to other genetic mutations.

Project description:In plant tissue culture, callus forms from detached explants in response to a high-auxin-to-low-cytokinin ratio on callus-inducing medium. Callus is a group of pluripotent cells because it can regenerate either roots or shoots in response to a low level of auxin on root-inducing medium or a high-cytokinin-to-low-auxin ratio on shoot-inducing medium, respectively1. However, our knowledge of the mechanism of pluripotency acquisition during callus formation is limited. On the basis of analyses at the single-cell level, we show that the tissue structure of Arabidopsis thaliana callus on callus-inducing medium is similar to that of the root primordium or root apical meristem, and the middle cell layer with quiescent centre-like transcriptional identity exhibits the ability to regenerate organs. In the middle cell layer, WUSCHEL-RELATED HOMEOBOX5 (WOX5) directly interacts with PLETHORA1 and 2 to promote TRYPTOPHAN AMINOTRANSFERASE OF ARABIDOPSIS1 expression for endogenous auxin production. WOX5 also interacts with the B-type ARABIDOPSIS RESPONSE REGULATOR12 (ARR12) and represses A-type ARRs to break the negative feedback loop in cytokinin signalling. Overall, the promotion of auxin production and the enhancement of cytokinin sensitivity are both required for pluripotency acquisition in the middle cell layer of callus for organ regeneration.

Project description:In plant tissue culture, callus forms from detached explants in response to a high-auxin-to-low-cytokinin ratio on callus-inducing medium. Callus is a group of pluripotent cells because it can regenerate either roots or shoots in response to a low level of auxin on root-inducing medium or a high-cytokinin-to-low-auxin ratio on shoot-inducing medium, respectively1. However, our knowledge of the mechanism of pluripotency acquisition during callus formation is limited. On the basis of analyses at the single-cell level, we show that the tissue structure of Arabidopsis thaliana callus on callus-inducing medium is similar to that of the root primordium or root apical meristem, and the middle cell layer with quiescent centre-like transcriptional identity exhibits the ability to regenerate organs. In the middle cell layer, WUSCHEL-RELATED HOMEOBOX5 (WOX5) directly interacts with PLETHORA1 and 2 to promote TRYPTOPHAN AMINOTRANSFERASE OF ARABIDOPSIS1 expression for endogenous auxin production. WOX5 also interacts with the B-type ARABIDOPSIS RESPONSE REGULATOR12 (ARR12) and represses A-type ARRs to break the negative feedback loop in cytokinin signalling. Overall, the promotion of auxin production and the enhancement of cytokinin sensitivity are both required for pluripotency acquisition in the middle cell layer of callus for organ regeneration.

Project description:In plant tissue culture, callus forms from detached explants in response to a high-auxin-to-low-cytokinin ratio on callus-inducing medium. Callus is a group of pluripotent cells because it can regenerate either roots or shoots in response to a low level of auxin on root-inducing medium or a high-cytokinin-to-low-auxin ratio on shoot-inducing medium, respectively1. However, our knowledge of the mechanism of pluripotency acquisition during callus formation is limited. On the basis of analyses at the single-cell level, we show that the tissue structure of Arabidopsis thaliana callus on callus-inducing medium is similar to that of the root primordium or root apical meristem, and the middle cell layer with quiescent centre-like transcriptional identity exhibits the ability to regenerate organs. In the middle cell layer, WUSCHEL-RELATED HOMEOBOX5 (WOX5) directly interacts with PLETHORA1 and 2 to promote TRYPTOPHAN AMINOTRANSFERASE OF ARABIDOPSIS1 expression for endogenous auxin production. WOX5 also interacts with the B-type ARABIDOPSIS RESPONSE REGULATOR12 (ARR12) and represses A-type ARRs to break the negative feedback loop in cytokinin signalling. Overall, the promotion of auxin production and the enhancement of cytokinin sensitivity are both required for pluripotency acquisition in the middle cell layer of callus for organ regeneration.