Project description:Investigation of whole genome gene expression level changes in Arabidopsis roots by the effect of light. Plant growth is sustained by a continuous cell division in meristems followed by cell differentiation and elongation. We have found that in Arabidopsis thaliana roots, flavonols play a key role in regulating the transition from cell division to differentiation. Using an engineered device to grow roots in darkness, but shoot in light cycle, coupled with transcriptomic and metabolomics analysis, we deciphered that flavonols accumulation regulates proliferation-promoting levels of auxin-PLETHORA and superoxide anion (O2-). High flavonols levels restrict auxin transport and the PLETHORA gradient but also superoxide radical content, promoting an accelerated cell differentiation. Furthermore, cytokinin-SHY2 and H2O2-UPB1 pathways, which promote differentiation and, respectively, antagonize auxin and O2- activity, increase flavonols biosynthesis establishing mutual interactions among these pathways. Flavonols function as positional signals integrating hormonal and ROS pathways to determine final organ growth. This work analyze the effect of root illumination in gene transcription. Details of how plants and roots are grown are described in Silva et al. (submitted) A six chip study using total RNA extracted from three independent experiments of Arabidopsis roots growing in presence of light and three independent experiments of Arabidopsis roots growing without light.

Project description:Here we show that differntiated endodermal cells have a distinct transcriptional response to auxin treatment. We perform a time serie of 10µM NAA treatment and sample at t=0, 2, 4, 8, 16 and 24hrs after NAA treatment. For the time series we compared roots of the solitairy root 1 (slr-1) mutant to the CASP1::shy2-2/slr-1 double mutant. We also provide RNAseq data of slr-1, CASP1::shy2-2 and CASP1::shy2-2/slr-1 at t=0

Project description:Isoprene is a C5 volatile organic compound, which can protect aboveground plant tissue from abiotic stress such as short-term high temperatures and accumulation of reactive oxygen species (ROS). Here, we uncover new roles for isoprene in the plant belowground tissues. By analyzing Populus x canescens isoprene synthase (PcISPS) promoter reporter plants, we discovered PcISPS promoter activity in certain regions of the roots including the vascular tissue, the differentiation zone and the root cap. Treatment of roots with auxin or salt increased PcISPS promoter activity at these sites, especially in the developing lateral roots (LR). Transgenic, isoprene non-emitting poplar roots revealed an accumulation of O2 - in the same root regions where PcISPS promoter activity was localized. Absence of isoprene emission, moreover, increased the formation of LRs. Inhibition of NAD(P)H oxidase activity suppressed LR development, suggesting the involvement of ROS in this process. The analysis of the fine root proteome revealed a constitutive shift in the amount of several redox balance, signaling and development related proteins, such as superoxide dismutase, various peroxidases and linoleate 9S-lipoxygenase, in isoprene non-emitting poplar roots. Together our results indicate for isoprene a ROS-related function, eventually co-regulating the plant-internal signaling network and development processes in root tissue. This article is protected by copyright. All rights reserved.

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:Elongator is a histone acetyltransferase (HAT) complex associated with RNA polymerase II (RNAPII) to facilitate transcription elongation. It consists of subunits Elp1-6, with Elp3 conferring HAT activity. Elongator is conserved in yeast, plants and humans. In humans, mutations in Elp genes cause neuronal diseases. In plants, Elongator is a positive regulator of cell proliferation during leaf and root growth. Consequently, Arabidopsis Elongator mutants (elo) have narrow leaves and short roots; additionally, germination, vegetative growth and reproductive development are also affected. Mutants have altered auxin signaling, and a number of auxin-related genes are among those differentially expressed in the mutant. Only two genes have been confirmed as targeted by Elongator during RNAPII transcription elongation, including the light-regulated auxin response regulator IAA3/SHY2.

Project description:To identify genes involved in the early phases of lateral root initiation, we profiled the transcriptomes of plants synchronously induced for lateral root initiation after 0, 1, 2, 4 and 6h of auxin treatment in conditions where IAA14 or IAA3-dependent auxin signaling is blocked. For this we used seedlings expressing non-degradable versions of the AUX/IAAs IAA14 (slr-1) or IAA3 (shy2-2) fused to the glucocorticoid receptor domain (slr-1:GR or shy2-2:GR) under the control of the pericycle and founder cell specific GATA23 promoter. Treatment with dexamethasone induces, specifically in pericycle cells, the nuclear translocation of the non-degradable AUX/IAA that acts as a dominant repressor of auxin signaling resulting in a complete block of lateral root formation

Project description:Coordination of cell division and pattern formation is central to tissue and organ development, and is particularly important in plants where walls prevent cell migration. Auxin and cytokinin are both critical for division and patterning, but it is unknown how these hormones converge to control tissue development. Here, we identify a genetic network that reinforces an early embryonic bias in auxin distribution to create a local, non-responding cytokinin source within the root vascular tissue. We provide experimental and theoretical evidence that these cells act as a local tissue organizer by positioning the domain of oriented cell divisions. We further demonstrate that the auxin-cytokinin interaction acts as a spatial incoherent feed forward loop, which is essential to generate distinct hormonal response zones, thus establishing a stable pattern within a growing vascular tissue. 4-day-old plants grown on MS were treated with the indicated compounds for the indicated time, whereafter roots were harvested and total RNA was isolated. Alternatively, roots were protoplasted and cell sorted for GFP+ cells followed by total RNA extraction.

Project description:Lateral Organ Boundary Domain (LBD) transcription factors are specific of plants and are involved in the control of development. One LBD clade is related to the control of root development (Coudert et al., 2013, Mol. Biol. Evol. 30, 569-572). Belonging to this clade, CROWN ROOT LESS 1 controls the initiation of crown roots in rice and its expression is induced by auxin (Inukai Plant Cell, 17, 1387-1396, Liu et al., 2005, Plant J., 43, 47-56). The aim of this study was to identify CRL1-dependant auxin responsive genes. Transcriptome analysis in wild-type and crl1 mutant stem bases after exogenous auxin treatment of plantlets revealed 126 CRL1-dependant auxin responsive genes including a large part of genes encoding proteins involved in signal transduction pathways that may be related to cell division, expansion and differentiation, and root development.

Project description:The PLETHORA gene regulatory network guides growth and cell differentiation in Arabidopsis roots

Project description:An optimal size of postembryonic root apical meristem (RAM) is achieved by a balance between cell division and differentiation. Despite extensive research, molecular mechanisms underlying the spatiotemporal coordination of cell division and differentiation remain largely unknown. Here, we report that ORESARA 15 (ORE15), an Arabidopsis PLATZ transcription factor preferentially expressed in the RAM, determines RAM size. The primary root length, RAM size, cell division rate, and stem cell niche activity were reduced in an ore15 loss-of-function mutant but enhanced in an activation-tagged line overexpressing ORE15 compared with the wild type. We further demonstrate that ORE15 regulates auxin transport and distribution, at least partly, by modulating the expression and localization of the auxin importer AUXIN RESISTANT 1 (AUX1). ORE15 forms mutually positive and negative feedback loops with auxin and cytokinin signaling, respectively. Collectively, our findings imply that ORE15 controls the RAM size by mediating the antagonistic interaction between auxin and cytokinin.