Project description:Calcium has been shown to be an important signalling molecule in the transduction of abiotic stress signals in Arabidopsis thaliana. Alteration of the calcium signature through the use of inhibitors has been shown to result in changes in the expression of certain downstream abiotic stress-induced genes. However, the communication of this signal through specific calcium-sensitive intermediate molecules has remained poorly elucidated. Various candidate molecules exist and including calcinurin, calcium-dependent protein kinases and calmodulin. Recently, a screen of an Arabidopsis thaliana cDNA expression library with calmodulin resulted in the isolation of the protein designated calmodulin-binding transcriptional activator or AtCAMTA that may function as one of these calcium-sensitive intermediate molecules. The Arabidopsis genome contains six CAMTA genes (AtCAMTA1-6), all of which are expressed in varying tissues throughout development. AtCAMTA1 was shown to function as a transcriptional activator through the expression of a chimeric protein consisting of the bacteria LexA protein fused to various segments of AtCAMTA expressed in yeast. In order to identify putative target genes of AtCAMTA1 in Arabidopsis we plan to analyse the transcriptome of AtCAMTA1 loss-of-function mutants. The gene expression pattern of two previously characterised alleles of AtCAMTA1 will be compared to wild type. Experimenter name = Sarah Scrase-Field; Experimenter phone = 01865 275062; Experimenter fax = 01865 275074; Experimenter department = University of Oxford; Experimenter address = Department of Plants Sciences; Experimenter address = University of Oxford; Experimenter address = South Parks Road; Experimenter address = Oxford; Experimenter zip/postal_code = OX1 3RB; Experimenter country = UK Experiment Overall Design: 4 samples were used in this experiment

Project description:This data was annotated by TAIR (http://arabidopsis.org). Two week-old Arabidopsis aerial tissues from Columbia-0 and cpr5, cpr5npr1, cpr5scv1, cpr5npr1svi1, and npr1 lines were collected for analysis. Experimenter name = Jinyoung Yang Experimenter phone = 919-613-8176, 919-61 Experimenter fax = 919-613-8177 Experimenter department = DCMB GROUP Experimenter institute = Duke University Experimenter address = B361 LSRC Bldg. Experimenter address = Research Dr. Experimenter address = Durham Experimenter zip/postal_code = NC 27708 Experimenter country = USA Keywords: genetic_modification_design

Project description:Ozone is known to induce gene expression in plants. The roles of the induced genes and the molecular basis for the induction however largely remain to be elucidated. We will expose 2 week-old Arabidopsis seedlings to 200 ppb ozone for 1 h. RNA will be extracted from control and ozone-fumigated seedlings 3 h following the end of the fumigation period. The induction of the known anti-oxidant enzyme GST will be confirmed prior to submission of the RNA samples to GARNet. Changes in gene expression will be assessed by hybridising microarrays with fluorescently labelled cDNA prepared from control and ozone-fumigated seedlings. The role of selected genes will be inferred from their sequence and further established by over expression under the control of the 35S or cell-specific promoters and by searching for mutants among single transposon or T-DNA insertion collections. Plants will be analysed on the basis of traits that are known to be affected by ozone including growth, flowering and stomatal responses. In addition, the ozone calcium signature we have reported previously (Clayton et al.1999) will be studied by crossing transgenic or mutant plants with apoaequorin or yellow cameleon 2.1-transformed plants. Experimenter name = Eleri Short Experimenter phone = 01524 593929 Experimenter fax = 01524 843854 Experimenter department = Department of Biological Sciences Experimenter institute = Lancaster University Experimenter address = Department of Biological Sciences Experimenter address = Lancaster University Experimenter address = Lancaster Experimenter zip/postal_code = LA1 4YQ Experimenter country = UK Keywords: compound_treatment_design

Project description:This experiment was donated by Philip N. Benfey's lab through ArexDB (http://www.arexdb.org). A global map of gene expression within an organ can identify genes with coordinated expression in localized domains, thereby relating gene activity to cell fate and tissue specialization. Here, we present localization of expression of more than 22,000 genes in the Arabidopsis root. Gene expression was mapped to 15 different zones of the root that correspond to cell types and tissues at progressive developmental stages. Patterns of gene expression traverse traditional anatomical boundaries and show cassettes of hormonal response. Chromosomal clustering defined some coregulated genes. This expression map correlates groups of genes to specific cell fates and should serve to guide reverse genetics. Experimenter name = Kenneth Birnbaum Experimenter department = Benfey Lab Experimenter institute = Duke University Experimenter address = Department of Biology Experimenter address = Duke University Experimenter address = Box 91000 Experimenter address = Durham Experimenter zip/postal_code = NC 27708 Experimenter country = America Keywords: cell_type_comparison_design

Project description:Multiprotein bridging factor 1c MBF1c (At3g24500) is a stress-response transcription co-activator. To test the function of MBF1c, we over-expressed it in transgenic Arabidopsis plants using the 35S-CaMV promoter. T4 seeds form 3 independent lines were tested for their tolerance to biotic and abiotic stress conditions. Constitutive expression of MBF1c in Arabidopsis enhanced the tolerance of transgenic plants to bacterial infection, salinity, heat and osmotic stress. Moreover, the enhanced tolerance of transgenic plants to osmotic and heat stress was maintained even when these two stresses were combined. The expression of MBF1c in transgenic plants augmented the accumulation of a number of sugars and defense transcrtipts in response to heat stress. Transcriptome profiling and inhibitor studies suggest that MBF1c expression enhances the tolerance of transgenic plants to heat and osmotic stress by partially activating, or perturbing, the ethylene-response signal transduction pathway. MBF1 proteins could be used to enhance the tolerance of plants to different abiotic stresses. Suzuki et al., 2005 Plant Physiology, submitted. Experimenter name = Ron Mittler Experimenter phone = 1-775-784-1384 Experimenter fax = 1-775-784-1650 Experimenter department = Dept. of Biochemistry Experimenter institute = University of Nevada Experimenter address = MS200 Experimenter address = Reno Experimenter address = Nevada Experimenter zip/postal_code = 89557 Experimenter country = USA Keywords: genetic_modification_design; stimulus_or_stress_design

Project description:Microarray experiment was performed using 4-week old plants to compare transcriptional profiles between sni1 (suppressor of npr1) and wild type (Col-0). Three biological replicates were included. Experimenter name: Wendy Durrant Experimenter phone: 1(919)613-8175 Experimenter fax: 1(919)613-8177 Experimenter department: Durrant Lab Experimenter institute: Duke University Experimenter address: Rm. B354, LSRC Bldg. Experimenter address: Research Dr. Experimenter address: Duke University Experimenter address: Durham, NC Experimenter zip/postal_code: 27708 Experimenter country: USA Keywords: genetic_modification_design;

Project description:This experiment was annotated by TAIR (http://arabidopsis.org). This experiment studies the response of gene expression in roots of 25-35 day old plants grown on hydroponics after 6, 48 and 96 hours of potassium starvation. RNA from roots was extracted after transfer to control (control) or potassium free nutrient solution respectively (starvation). Experimenter name = Julian Schroeder Experimenter phone = 619-534-7759 Experimenter fax = 619-534-7108 Experimenter department = J Schroeder Laboratory Experimenter institute = University of California-San Diego Experimenter address = Biology Department Experimenter address = University of California-San Diego Experimenter address = La Jolla Experimenter zip/postal_code = CA 92093-0116 Experimenter country = USA Keywords: time_series_design; growth_condition_design

Project description:The sfr6 mutant was identified on the basis of its failure to cold acclimate, and exhibits a marked deficiency in cold-and osmotic stress-inducible gene expression (Knight et al., 1999). We have demonstrated that genes of this type (so-called COR genes) are misregulated if they contain the DRE (drought-responsive element, or CRT; C-repeat) cis acting element in their promoter (Boyce et al., 2003). Micro-array analysis has allowed us to identify a number of COR genes misregulated in sfr6, all of which contain the DRE element. However, these experiments have indicated that other genes, not of the COR group, are also misregulated in the mutant and these do not contain the DRE element. We chose the three non-COR genes that were most clearly down-regulated in sfr6 on our previous micro-array, and identified each as of these as dark-inducible. We now seek to address two questions: (1) Can we discover more dark-regulated genes that are down-regulated in the mutant, and thus identify a second cis-acting element with which SFR6 may be interacting? (2) Do all of the non-COR genes that are misregulated in sfr6 fall into the category of dark-inducible, or is SFR6 likely to be interacting with three or more regulons?; For this micro-array experiment, we will subject sfr6 and wild type Arabidopsis, grown in a 16/8-h light/dark cycle, to darkness for 3h or 6h at ambient growth temperature. Under these conditions we see strong up-regulation of the three genes we have identified as dark-inducible, and we see clear down-regulation of expression in sfr6. References. Knight H, Veale E, Warren GJ, Knight MR (1999) The sfr6 mutation in Arabidopsis suppresses low-temperature induction of genes dependent on the CRT/DRE sequence motif. Plant Cell 11: 875-886. Boyce JM, Knight H, Deyholos M, Openshaw MR, Galbraith DW, Warren G, Knight MR (2003). The sfr6 mutant of Arabidopsis is defective in transcriptional activation via CBF/DREB1 and DREB2 and shows sensitivity to osmotic stress. Plant Journal 34: 395-406. Experimenter name = Heather Knight; Experimenter phone = 01865 275023; Experimenter fax = 01865 275074; Experimenter institute = University of Oxford; Experimenter address = Department of Plant Sciences; Experimenter address = University of Oxford; Experimenter address = South Parks Road; Experimenter address = Oxford; Experimenter zip/postal_code = OX1 3RB; Experimenter country = UK Experiment Overall Design: 4 samples were used in this experiment

Project description:The sfr6 mutant was identified on the basis of its failure to cold acclimate, and exhibits a marked deficiency in cold-and osmotic stress-inducible gene expression (Knight et al., 1999). We have demonstrated that genes of this type (so-called COR genes) are misregulated if they contain the DRE (drought-responsive element, or CRT; C-repeat) cis acting element in their promoter (Boyce et al., 2003). Micro-array analysis has allowed us to identify a number of COR genes misregulated in sfr6, all of which contain the DRE element. However, these experiments have indicated that other genes, not of the COR group, are also misregulated in the mutant and these do not contain the DRE element. We chose the three non-COR genes that were most clearly down-regulated in sfr6 on our previous micro-array, and identified each as of these as dark-inducible. We now seek to address two questions: (1) Can we discover more dark-regulated genes that are down-regulated in the mutant, and thus identify a second cis-acting element with which SFR6 may be interacting? (2) Do all of the non-COR genes that are misregulated in sfr6 fall into the category of dark-inducible, or is SFR6 likely to be interacting with three or more regulons? For this micro-array experiment, we will subject sfr6 and wild type Arabidopsis, grown in a 16/8-h light/dark cycle, to darkness for 3h or 6h at ambient growth temperature. Under these conditions we see strong up-regulation of the three genes we have identified as dark-inducible, and we see clear down-regulation of expression in sfr6. References. Knight H, Veale E, Warren GJ, Knight MR (1999) The sfr6 mutation in Arabidopsis suppresses low-temperature induction of genes dependent on the CRT/DRE sequence motif. Plant Cell 11: 875-886. Boyce JM, Knight H, Deyholos M, Openshaw MR, Galbraith DW, Warren G, Knight MR (2003). The sfr6 mutant of Arabidopsis is defective in transcriptional activation via CBF/DREB1 and DREB2 and shows sensitivity to osmotic stress. Plant Journal 34: 395-406. Experimenter name = Heather Knight Experimenter phone = 01865 275023 Experimenter fax = 01865 275074 Experimenter institute = University of Oxford Experimenter address = Department of Plant Sciences Experimenter address = University of Oxford Experimenter address = South Parks Road Experimenter address = Oxford Experimenter zip/postal_code = OX1 3RB Experimenter country = UK Keywords: growth_condition_design; genetic_modification_design

Project description:Multiprotein bridging factor 1c MBF1c (At3g24500) is a stress-response transcription co-activator. To test the function of MBF1c, we over-expressed it in transgenic Arabidopsis plants using the 35S-CaMV promoter. T4 seeds form 3 independent lines were tested for their tolerance to biotic and abiotic stress conditions. Constitutive expression of MBF1c in Arabidopsis enhanced the tolerance of transgenic plants to bacterial infection, salinity, heat and osmotic stress. Moreover, the enhanced tolerance of transgenic plants to osmotic and heat stress was maintained even when these two stresses were combined. The expression of MBF1c in transgenic plants augmented the accumulation of a number of sugars and defense transcrtipts in response to heat stress. Transcriptome profiling and inhibitor studies suggest that MBF1c expression enhances the tolerance of transgenic plants to heat and osmotic stress by partially activating, or perturbing, the ethylene-response signal transduction pathway. MBF1 proteins could be used to enhance the tolerance of plants to different abiotic stresses. Suzuki et al., 2005 Plant Physiology, submitted. Experimenter name = Ron Mittler; Experimenter phone = 1-775-784-1384; Experimenter fax = 1-775-784-1650; Experimenter department = Dept. of Biochemistry; Experimenter institute = University of Nevada; Experimenter address = MS200; Experimenter address = Reno; Experimenter address = Nevada; Experimenter zip/postal_code = 89557; Experimenter country = USA Experiment Overall Design: 6 samples were used in this experiment