Project description:At high concentrations caesium (Cs) is toxic to plant growth. This toxic effect may occur when Cs blocks potassium (K) uptake mechanisms in plants. Consequently, plants starved of K and plants exposed to toxic concentrations of Cs should have similar gene expression patterns. To test this hypothesis, Arabidopsis will initially be grown on agar containing 1/10 MS salts before being transferred to either 1/10 MS nutrient solution (control plants), 1/10 MS nutrient solution containing 2 mM Cs, or 1/10 MS nutrient solution with no K. Roots and shoot will then be harvested seven days after transfer and used to challenge ATH1 GeneChips. Experiment Overall Design: Number of plants pooled:40-50

Project description:The aim of the experiment is to study the pattern of genes expression involved in defense to heavy metals and their transport and distribution within plant organs. Most of the plant species inhibits heavy metals entrance to the roots and their transport and accumulation to/in above ground organs after toxic ions penetrate roots. Some species of Brassicacea differ in the pattern of defense gene expression in the roots in a way that allow for greater transport of toxic ions to the above ground part. If so, by harvesting such plants toxic elements will be extracted from the soil. Identification of these differences in the gene expression is crucial in development of the newly emerging environmental biotechnology phytoremediation in which plants as well as being green lungs play also a role of a green liver. Results of our studies with mustard plants showed among others that exposure for 12 hr to 12.5mg of Pb/1L of hydroponics solution is efficient to increase of constitutive genes expression and in de novo induction of genes expression coding for Pb tolerance and that this response is organ specific. Sequencing of the whole genome of A. thaliana opens the opportunity to study this phenomenon at molecular level more widely including the signaling (two-component system) and plasmolemma and tonoplast transporters genes. Therefore in our further steps we are going to use Arabidopsis as a model plant and the transcriptomics aproach is the only way for such studies. At first based on results with mustard physiological study we will conduct for elucidating Arabidopsis plant responses to lead in order to choose the most appropriate dose and time of treatment. In the trascriptome experiment we would like to study the profile gene expression in above ground parts and in the roots of arabidopsis plants in response to toxic ions of lead. Results of this study, besides promising applicable aspects, will also lead to a better understanding of plant acclimation and adaptation to antropogenic stresses. We expect to obtain mutant(s) tolerant to Pb and if so, they will be provided to NASC.

Project description:Background: The Arabidopsis ANR1 gene is a key regulator of root architecture (Zhang and Forde, 1998): when ANR1 is down-regulated (by antisense or co-suppression) the resulting lines are no longer able to proliferate their lateral roots in response to localised supplies of NO3- (Zhang and Forde, 1998). ANR1 encodes a root-specific member of the MADS box family of transcription factors and is thought to be a component of a signalling pathway that links an external NO3- signal to increased meristematic activity in the lateral root meristem (Zhang et al., 1999).A major goal of our present BBSRC-funded project is to learn more about this NO3- response pathway by identifying the downstream targets of ANR1. To this end we have generated a set of transgenic lines in which ANR1 is under a novel post-translational control. This was achieved by tagging ANR1 with the steroid-binding domain of the rat glucocorticoid receptor (rGR) and expressing the fusion protein under the control of the CaMV 35S promoter. Initial results with these lines confirm that the architecture of the root system is altered in a way that correlates with the presence of the steroid inducer (dexamethasone, or DEX) and the expression of the ANR1::rGR transgene. We now wish to apply transcript analysis to one of these lines (ANGR4-12) to identify the genes whose expression is up- or down-regulated by ANR1. Sablowski and Meyerowitz (1998) successfully used an analogous approach to identify a gene that is an immediate target of the AP3 MADS-box transcription factor (although here, in the absence of microarray technology, differential display was used). Experimental: Plants of the two genotypes (ANGR4-12 and wild type) will be grown in sterile liquid culture for 3-4 weeks and then starved of N for 3 d (to quench the endogenous NO3- signalling pathway) before starting the DEX treatment. Roots will be harvested after 60 min from roots of DEX-treated and mock-treated RGR4-12 and control plants (four RNA samples). To minimise background noise due to environmental variables we will repeat the experiment three times and pool the RNA samples. Experiment Overall Design: Number of plants pooled:20 Experiment Overall Design: Biological replicates: 2

Project description:This application is the second part of a BBSRC-funded grant to compare and contrast the plastid-signalling pathways disrupted by Norflurazon and far-red light treatment of Arabidopsis seedlings. The first application of this laboratory to GARNet's Affymetrix service (2002-08-25-17.41.49_McCormac) addressed the Norflurazon pathway; this application addresses the far-red pathway. The assembly of photosynthetic complexes in developing chloroplasts is critical to the establishment of the autotrophic plant. This requires light-mediated upregulation of both nuclear- and chloroplast-encoded genes. The expression of such photosynthetically-associated nuclear genes is also often dependant on a retrograde plastid signal which emanates from chloroplasts to modulate nuclear transcription. Extensive studies using the herbicide Norflurazon to knock-out the plastid signal (including this lab's previous Affymetrix application to GARNet) are identifying the affected gene sets. However, genetic studies have indicated the existence of more than one plastid signalling pathway. We have recently investigated a phytochrome A-mediated, far-red (FR) input pathway which blocks subsequent chloroplast development under white light (WL). This has also been found to inhibit the transcription of a small group of known nuclear-encoded plastidic proteins. Here we wish to establish how wide-reaching this FR-effect is on nuclear transcription, and will directly compare the affected gene groups with those identified from our earlier (and other's) studies with a Norflurazon treatment. In this array experiment we will compare RNA from seedlings grown in complete darkness (D) before transfer to WL, with that of seedlings preconditioned under a restricted wavelength FR source before exposure to WL. This comparison of FR- and Norflurazon-affected gene groupings will indicate whether the plastid signalling pathways are likely to be the same, overlapping or highly divergent. As well as wild-type seedlings, the gun1,gun5 mutant line is to be used as both these alleles are well established as alleviating the Norflurazon-inhibited pathway, but their affect on the FR-pathway is less clear. A single replicate of a phyA-null mutant line will also be included in order to differentiate between specific phytochromeA-mediated responses and other FR effects. It is envisaged that, in general, D- and FR-treated samples of the phyA mutant line will respond in the same way as each other and as the wild-type D-treated samples and, thus, the lack of a biological repeat in this case is not a major short-fall. The proposed experiment will consist of: wild-type: D-pretreated (x2 biological replicates) wild-type: FR-preconditioned (x2) gun1,gun5: D-pretreated (x2) gun1,gun5: FR-preconditioned (x2) phyA: D-pretreated (x1) phyA: FR-preconditioned (x1) Experiment Overall Design: Number of plants pooled:300 seedlings

Project description:Nitric oxide (NO.) is a well-established signal in mammalian cells regulating e.g. smooth muscle tone, neurotransmission and apoptosis. NO interacts with superoxide (O2-) to derive the highly reactive peroxynitrite (ONOO-) radical leading to the generation of lipid hydroxy-peroxides (ROO.) and cell death. Thus the recent reports implicating of .NO in the Hypersensitive Response (HR) a form of programmed cell death elicited by pathogens in plantsis suggestive of parallel roles in animals and plants. As part of BBSRC funded programmes which are investigating oxidative signaling and cell death in Arabidopsis we have collaborated with the Trace Gas Detection facility at the University of Nijmegen to be the first to measure NO in planta from a developing HR (Mur et al.paper in prep). The challenge remains to understand the spatio-temporal role(s) of .NO during the HR and disease development. In line with other groups e.g. Klessig et al.(2000) PNAS 978849-55 we have observed that .NO mediated event are both SA- dependent and independent. We propose a two-stage programme to investigate NO events which will lead to subsequent BBSRC grant bids. Firstly to exploit the GARNET Affymetrix transcriptomic service to identify genes which are upregulated by .NO (see programme below). These will be compared with similar data generated by other members of the consortium; Dr. Steve Neill for oxidative stress (Desikan et al. (2001). Plant Physiol 127(1): 159-72; Clarke et al.2000 Plant J.; 24:667-77); Dr. Paul Kenton who is mainly interested in signaling by the oxylipid Jasmonic acid (Kentonet al. (1999). MPMI 12(1): 74-78) as well as from other sources. Though these data in themselves will suggest modes of NO action. However as a second approach we will clone the promoter of a strongly NO-responsive gene which will be fused to positive and negative selectable markers as well as reporter genes e.g. LUC. to identify Arabidopsis EMS mutants which are perturbed in NO-mediated events. Programme. Our in planta measurement show that from a baseline production of 1nl.g fwt-1h-1 NO levels rise to 6nl. g fwt-h-1 (_plus/- 1.1 SE) prior to cell death and to 25nl g fwt-h-1 (_plus/- 4.2 SE) at cell death following which the concentration falls. At this juncture we will intend to gas Arabidopsis to ~75ppb (the head-space concentration when NO production was at 6nl. g fwt-h-1). Prior to using the DNA RNA will establish that this does not elicit cell death over the proposed treatment period and that both PR1 (SA-dependent) and PAL1 (SA-independent) genes are induced. We will compare this plant with sealed but non-treated Arabidopsis. Future targets for DNA RNAs analysis induce plant treated with both NO (Sodium Nitro Prusside) and O2- (Xanthine oxidase) generators and depending on their effectiveness (to be assessed by NO measurement) HR lesions treated with Nitric Oxide Synthase inhibitors. Experiment Overall Design: Number of plants pooled:8

Project description:The aim of this study is to identify Arabidopsis genes whose expression is altered by aphid feeding. An understanding of the plant aphid interaction at the level of the plant transcriptome will 1) consolidate current areas of investigation focused on the phloem composition (the aphid diet), 2) open up areas of plant aphid interactions for ourselves and other workers, 3) Contribute to understanding the use of new molecular technologies in an environmental context and 4) contribute to existing and development of novel control strategies.Our Arabidopsis/Myzus persicae system provides a valuable model for the study because of: a) the advantages of using Arabidopsis, b) The ability to use clonal insects, c) phloem feeding aphids facilitate focus on a specific cell type, d) aphid stylectomy allows collection of pure phloem sap to monitor ?phloem phenotype?? of the plant and the insect diet, e) we have techniques to monitor the reproductive performance and feeding behaviour aphids.Our strategy has been to test the function of selected genes, particularly those regulating phloem composition (the feeding site of the aphid) based on current phloem models of phloem function. Gene choice is limited the simplicity of current models of phloem aphid interaction.We propose a simple two treatment (aphid infested vs control plants) experiment that will identify novel target genes for future analysis. Arabidopsis plants (variety Columbia) will be grown in 16/8 light/dark in temperature controlled growth rooms. At growth stage 3.90, when rosette growth is complete, 10 clonal adult Myzus persicae will be caged in clip cages on the two largest leaves on each plant. Control plants will be treated identically except that the cages will be empty. Leaves will be harvested 8 h after infestation. This time point is selected as we know that 90% of aphids are plugged into the sieve element within 2h and that a 6h lag phase has period has previously been used when examining gene expression affected by wounding. In subsequent experiments we will examine time courses of expression of relevant genes using other approaches. Pooling two leaves from each of ten plants will generate the RNA sample, ensuring that expression signals are representative of the population of plants. Experiment Overall Design: Number of plants pooled:10

Project description:Background: Since chemical assays of soil nutrients are unreliable the UK horticultural and agricultural industries routinely apply large amounts of inorganic fertiliser to maintain crop yields and quality. Excessive fertiliser applications are both costly and can lead to unnecessary pollution. A possible solution to this problem is to use sensor (GM or non-GM) technologies that exploit the changes in plant gene expression profiles under incipient nutrient deficiency. The aim of this project is to identify genes upregulated in the early stages of nutrient depletion. Methods: Arabidopsis ecotype Col-5 (N1644) will be grown hydroponically using established techniques. In parallel experiments NP and K will be withdrawn individually after 21 d growth. RNA will be extracted from shoots of nutrient replete (control) and nutrient depleted plants 24 h after the removal of nutrients. Shoot nutrient content will be assayed by ICP-EMS as a reference. By comparing expression profiles we will be able to differentiate between genes that are upregulated by lack of specific nutrients and those upregulated by a universal stress-response system. Promoters and transcripts of these genes will underpin the development of novel sensor technologies and knowledge of the gene expression profiles will improve our understanding of the physiology of plant mineral nutrition. Experiment Overall Design: 4 samples

Project description:Background: Since chemical assays of soil nutrients are unreliable the UK horticultural and agricultural industries routinely apply large amounts of inorganic fertiliser to maintain crop yields and quality. Excessive fertiliser applications are both costly and can lead to unnecessary pollution. A possible solution to this problem is to use sensor (GM or non-GM) technologies that exploit the changes in plant gene expression profiles under incipient nutrient deficiency. The aim of this project is to identify genes upregulated in the early stages of nutrient depletion. Methods: Arabidopsis ecotype Col-5 (N1644) will be grown hydroponically using established techniques. In parallel experiments NP and K will be withdrawn individually after 21 d growth. RNA will be extracted from shoots of nutrient replete (control) and nutrient depleted plants 24 h after the removal of nutrients. Shoot nutrient content will be assayed by ICP-EMS as a reference. By comparing expression profiles we will be able to differentiate between genes that are upregulated by lack of specific nutrients and those upregulated by a universal stress-response system. Promoters and transcripts of these genes will underpin the development of novel sensor technologies and knowledge of the gene expression profiles will improve our understanding of the physiology of plant mineral nutrition. Experiment Overall Design: 4 samples

Project description:Our interest lies in how plants respond to bacterial pathogens. Over the past three years we have identified and documented reproducible, landmark biochemical and molecular events following the challenge of Arabidopsis with the phytopathogenic enterobacteria P. syringae. Significantly, our studies revealed 60% of cDNA-AFLP differentials not present on the 8,200 feature GeneChips and 20% absent from public EST databases (de Torres in press). We now seek to exploit this background using carefully defined time-points to analyse global changes in the Arabidopsis transcriptome using challenges selected to define gene targets implicated in (i) expression of basal immunity (ii) the establishment of successful parasitism (resistance) by a virulent pathogen (host). The results will provide a rationale for future functional assays of the identified pathways using transgenic knockouts and mutant analyses. Additionally, data will provide underpinning support for comparative proteomics of the defense response currently in progress with GARNet support using the same experimental parameters (BBSRC 32/P14635). We propose the following treatments: (i) Mock vs. DC3000hrpA @ 60 min: 60 minutes is subsequent to host immediate-early stress responses and will catalogue the innate responses induced by pathogen associated molecular patterns. The hrpA lesion will ensure no type III effectors influence transcriptional responses. Gene products induced at this time are predicted to potentiate latter host responses (2 treatments X 3 biological replicates = 6 chips). (ii) Mock vs. DC3000 vs. DC3000hrpA vs. DC3000::avrRpm1 @ 4 hours: A key time point previously defined where no macroscopic symptoms are visible but significant differences exist between compatible and incompatible interactions at the molecular and physiological levels. These treatments will serve to define the earliest genes induced by the complement of DC3000 type III effector and will specifically define genes/pathways suppressed by virulence factors in addition to those implicated in orchestration of the hypersensitive cell death. We will also include an incompatible interaction on a transgenic line expressing an RPM1 interacting protein, which fails to mount an HR but exhibits hyper-resistance. We predict this challenge will separate the resistance response (pathogen restriction) from that associated with hypersensitive cell death (5 treatments X 3 biological replicates = 15 chips). (iii) Mock vs. DC3000 vs. DC3000hrpA @ 14 hours: At 10 h before phenotypes are apparent in the DC3000 background, Type III effector delivery is well advanced and impact on host transcription maximal (3 treatments X 3 biological replicates = 9 chips). Experiment Overall Design: Number of plants pooled:4 leaves/plant; 18 plants/time point

Project description:This work is part of an existing collaboration between the two laboratories, funded by the EU (EU-RTN-INTEGA). Both parties will share the cost of this microarray experiment. Background: We have demonstrated that ethylene-insensitive mutants and wild type(col-0) Arabidopsis plants treated with an ethylene perception inhibitor have increased levels of expression of genes, such as GASA1 and g-TIP, that are thought to be regulated by GA (Vriezen et al, unpublished results). However, this observation was based on an RNA gel blot analysis and therefore limited to few genes. Aim: To investigate whether plants with decreased ethylene perception are generally hypersensitive to GA or whether this effect is restricted to specific genes. We plan to undertake a complete transcriptome analysis of GA-treated wild type andetr1-1 plants. The aim is to identify genes that are induced directly as a result of the GA treatment, and we will therefore focus on the time window 0-3h. Tissues to be sampled: Plants will be grown in vitroon MS/2 containing 1% sucrose, pH 5.7, at 22 C,70% RH, under white light (54 PAR) and a photoperiod of 16h light/8h dark. Plants will be treated at 14 days and harvested entirely, i.e. roots and shoots are extracted together. Experimental set-up: Col-0 and the ethylene-insensitive mutant etr1-1 will be sprayed with 50 microM GA4 in water. GA4 is the major bio-active GA in Arabidopsis. Samples will be taken after 0, 30 min, 1h, and 3h. In order to correct for touch-induced genes a control, which is sprayed with water only and harvested at 1h, will be included for both genotypes. The total number of chips to be hybridized is 10. The time course with 4 data points is preferred to a single time point with 3 repeats, because it will allow us to follow the induction kinetics and identify early response genes. For each timepoint, RNA will be extracted from at least 40 individuals. Experiment Overall Design: 18 samples