Project description:During cold acclimation plants increase their freezing tolerance in response to low non-freezing temperatures. This is accompanied by many physiological, biochemical and molecular changes that have been extensively investigated. In addition, many cold acclimated plants become more freezing tolerant during exposure to mild, non-damaging sub-zero temperatures. There is hardly any information available about the molecular basis of this adaptation. However, Arabidopsis thaliana is among the species that acclimate to sub-zero temperatures. This makes it possible to use the molecular and genetic tools available in this species to identify components of sub-zero signal transduction and acclimation. Here, we have used microarrays and a qRT-PCR primer platform covering 1880 genes encoding transcription factors to monitor changes in gene expression in the accessions Columbia-0, Rschew and Tenela during the first three days of sub-zero acclimation at -3°C. The results indicate that gene expression during sub-zero acclimation follows a tighly controlled time-course. Especially AP2/EREBP and WRKY transcription factors may be important regulators of sub-zero acclimation, although the CBF signal transduction pathway seems to be less important during sub-zero than during cold acclimation. Globally, we estimate that approximately 5% of all Arabidopsis genes are regulated during sub-zero acclimation. Particularly photosynthesis-related genes were down-regulated and genes belonging to the functional classes of cell wall biosynthesis, hormone metabolism and RNA regulation of transcription were up-regulated. Collectively, these data provide the first global analysis of gene expression during sub-zero acclimation and allow the identification of candidate genes for forward and reverse genetic studies into the molecular mechanisms of sub-zero acclimation. We used whole genome microarrays to monitor changes in gene expression in the Arabidopsis thaliana accessions Columbia-0, Rschew and Tenela during three days of acclimation to sub-zero temperature at -3°C after cold acclimation

Project description:Arabidopsis thaliana and Eutrema salsugineum show the ability to cold acclimate. However, the degree of freezing tolerance depends in both cases on the accession. To elucidate the transcriptional basis of this differencial freezing tolerance, we performed where we grew plants under control conditions (20°C/18°C day/night) or under cold conditions (additional 4°C for 2 weeks). Rosettes were harvested from non-acclimated and cold acclimated plants for RNA isolation. Expression patterns were compared between treatments, accessions and species.

Project description:Freezing causes physiological changes even in a hardy, cold-acclimated wild type. During recovery from freezing, gene expression will reflect the induction of damage-repair processes distinct from the damage-prevention associated with cold acclimation. This will be detected by observing the wild-type transcriptome at two time points during recovery from a freezing episode. The appropriate control is the unfrozen, cold-acclimated wild type. Experimenter name = Glenn Thorlby Experimenter phone = 01874 443770 Experimenter address = School of biological Sciences Experimenter address = Bourne Building Experimenter address = Royal Holloway Experimenter address = Egham Experimenter zip/postal_code = TW20 0EX Keywords: growth_condition_design;

Project description:Intertidal zone organisms can experience transient freezing temperatures during winter low tides, but their extreme cold tolerance mechanisms are not known. Petrolisthes cinctipes is a temperate mid-high intertidal zone crab species that can experience wintertime habitat temperatures below the freezing point of seawater. We examined how cold tolerance changed during the initial phase of thermal acclimation to cold and warm temperatures, as well as the persistence of cold tolerance during long-term thermal acclimation. Thermal acclimation for as little as 6 hours at 8˚C enhanced crab tolerance during a 1h exposure to -2°C relative to crabs acclimated to 18˚C. Potential mechanisms for this enhanced tolerance were elucidated using cDNA microarrays to probe for differences in gene expression in cardiac tissue of warm and cold acclimated crabs during the first day of thermal acclimation. No changes in gene expression were detected until 12h of thermal acclimation. Genes strongly upregulated in warm acclimated crabs represented immune response and extracellular / intercellular processes, suggesting that warm acclimated crabs had a generalized stress response and may have been remodelling tissues or altering intercellular processes. Genes strongly upregulated in cold acclimated crabs included many that are involved in glucose production suggesting that cold acclimation involves increasing intracellular glucose as a cryoprotectant. Structural cytoskeletal proteins were also strongly represented among the genes upregulated in only cold acclimated crabs. There were no consistent changes in composition or the level of unsaturation of membrane phospholipid fatty acids with cold acclimation, which suggests that neither short- nor long-term changes in cold tolerance are mediated by changes in membrane fatty acid composition. Overall, our study demonstrates that initial changes in cold tolerance are likely not regulated by transcriptomic responses, but that gene expression-related changes in homeostasis begin within 12 hours – the length of a tidal cycle. all array data and raw images archived at the Porcelain Crab Array Database (http://array.sfsu.edu)

Project description:Plants in temperate regions have evolved mechanisms to survive sudden temperature drops. Previous reports have indicated that the cold acclimation mechanism is light-dependent and does not fully operate under a low light intensity. In these studies, plants were grown under a long-day photoperiod and were more sensitive to freezing stress. However, winter annuals like Arabidopsis thaliana Col-0 germinate in the fall, overwinter as rosettes, and therefore must acclimate under short photoperiods and low irradiance. The role of light intensity was analysed in plants grown under a short-day photoperiod at the growth stage 1.14. Plants were acclimated at 4 °C for seven days under 100 and 20 μmol m-2s-1 PPFD for control and limited-light conditions, respectively. All cold acclimated plants accumulated molecular markers reportedly associated with acquired freezing tolerance, including proline, sucrose, CBFs, and COR gene protein products dehydrins and low-temperature-responsive proteins LTIs. Observed changes indicated that low PPFD did not inhibit the cold acclimation process, and the freezing stress experiment confirmed similar survival rates. The molecular analysis found distinct PPFD-specific adaptation mechanisms that were manifested in contrasting content of anthocyanins, cytokinin conjugates, abundances of proteins forming photosystems, and enzymes of protein, energy, and ROS metabolism pathways. Finally, this study led to the identification of putative proteins and metabolite markers correlating with susceptibility to freezing stress of non-acclimated plants grown under low PPFD. Our data show that Arabidopsis plants grown under short-day photoperiod can be fully cold-acclimated under limited light conditions, employing standard and PPFD-specific pathways.

Project description:During low temperature exposure, temperate plant species increase their freezing tolerance in a process termed cold acclimation. During deacclimation in response to warm temperatures cold acclimated plants lose freezing tolerance and resume growth and development. While considerable effort has been directed toward understanding the molecular and metabolic basis of cold acclimation, much less information is available about the regulation of deacclimation. Here, we report metabolic (GC-MS) and transcriptional (microarrays, qRT-PCR) responses underlying deacclimation during the first 24 h after a shift of cold acclimated Arabidopsis thaliana (Columbia-0) plants to warm temperature. The data revealed a faster response of the transcriptome than of the metabolome and provided evidence for tightly regulated temporal responses at both levels. Metabolically deacclimation is associated with decreasing contents of sugars, amino acids and glycolytic and TCA cycle intermediates, indicating an increased need for carbon sources and respiratory energy production associated with growth resumption under warm temperature conditions. Deacclimation also involves extensive down-regulation of protein synthesis and changes in the metabolism of lipids and cell wall components. Altered hormonal regulation appears particularly important during deacclimation, with changes in the expression of genes related to auxin, gibberellin, brassinosteroid, jasmonate and ethylene metabolisms. Several transcription factor families controlling fundamental aspects of plant development are significantly regulated during deacclimation, emphasizing that loss of freezing tolerance and growth resumption are interrelated processes that are transcriptionally highly interrelated. Expression patterns of some clock oscillator components during deacclimation resembled those under warm conditions, indicating at least partial re-activation of the circadian clock. This study provide the first comprehensive analysis of the regulation of deacclimation in cold acclimated plants. The data indicate cascades of rapidly regulated genes and metabolites that underly the developmental switch resulting in reduced freezing tolerance and the resumption of growth. They constitute a reference dataset of genes, metabolites and pathways that are crucial during the first rapid phase of deacclimation and will be useful for the further analysis of this important but under-researched plant process. We used whole genome microarrays to monitor changes in gene expression in the Arabidopsis thaliana accession Columbia-0 during the first 24 h after a shift of cold acclimated plants to warm temperature.

Project description:Freezing causes physiological changes even in a hardy, cold-acclimated wild type. During recovery from freezing, gene expression will reflect the induction of damage-repair processes distinct from the damage-prevention associated with cold acclimation. This will be detected by observing the wild-type transcriptome at two time points during recovery from a freezing episode. The appropriate control is the unfrozen, cold-acclimated wild type. Experimenter name = Glenn Thorlby; Experimenter phone = 01874 443770; Experimenter address = School of biological Sciences; Experimenter address = Bourne Building; Experimenter address = Royal Holloway; Experimenter address = Egham; Experimenter zip/postal_code = TW20 0EX Experiment Overall Design: 3 samples were used in this experiment

Project description:Our goals are to discover the basis of the stress-sensitive phenotypes of the sfr2, sfr3 and sfr6 mutants, and to distinguish damage-repair from damage-prevention-related transcription in the wild type. The effects of sfr2 and sfr3 on cold-induced gene expression will be observed. Since sfr6 causes sensitivity to drought as well as freezing, the effects of sfr6 on the transcriptional response to drought is studied; an observation of cold-induced sfr6 expression is needed for direct comparison to the effect of drought. Unstressed mutants, and equivalently-stressed wild types, are necessary controls. The above experiments are conducted on tissue-culture-grown plants grown under 24 hr illumination for maximum reproducibility and comparability to other transcriptomic experiments.Freezing causes physiological changes even in a hardy, cold-acclimated wild type. During the recovery period, gene expression will reflect the induction of damage-repair processes distinct from the damage-prevention associated with cold acclimation. This will be detected by observing the wild-type transcriptome at two time points during recovery from a freezing episode. The appropriate controls is the unfrozen, cold-acclimated wild type. Plants for this experiment will be soil-grown in an 9/15 day/night cycle to the rosette stage, and this regime will be maintained during acclimation and freezing treatments.Cold-induction will be 10 days at 4°C; drought will be imposed by placing excised leaves in a desiccator for 6 h. The youngest fully-expanded rosette leaves will be harvested for RNA extraction. Experiment Overall Design: Number of plants pooled:18

Project description:Our goals are to discover the basis of the stress-sensitive phenotypes of the sfr2, sfr3 and sfr6 mutants, and to distinguish damage-repair from damage-prevention-related transcription in the wild type. The effects of sfr2 and sfr3 on cold-induced gene expression will be observed. Since sfr6 causes sensitivity to drought as well as freezing, the effects of sfr6 on the transcriptional response to drought is studied; an observation of cold-induced sfr6 expression is needed for direct comparison to the effect of drought. Unstressed mutants, and equivalently-stressed wild types, are necessary controls. The above experiments are conducted on tissue-culture-grown plants grown under 24 hr illumination for maximum reproducibility and comparability to other transcriptomic experiments.Freezing causes physiological changes even in a hardy, cold-acclimated wild type. During the recovery period, gene expression will reflect the induction of damage-repair processes distinct from the damage-prevention associated with cold acclimation. This will be detected by observing the wild-type transcriptome at two time points during recovery from a freezing episode. The appropriate controls is the unfrozen, cold-acclimated wild type. Plants for this experiment will be soil-grown in an 9/15 day/night cycle to the rosette stage, and this regime will be maintained during acclimation and freezing treatments.Cold-induction will be 10 days at 4°C; drought will be imposed by placing excised leaves in a desiccator for 6 h. The youngest fully-expanded rosette leaves will be harvested for RNA extraction. Keywords: stimulus_or_stress_design; strain_or_line_design; time_series_design

Project description:Intertidal zone organisms can experience transient freezing temperatures during winter low tides, but their extreme cold tolerance mechanisms are not known. Petrolisthes cinctipes is a temperate mid-high intertidal zone crab species that can experience wintertime habitat temperatures below the freezing point of seawater. We examined how cold tolerance changed during the initial phase of thermal acclimation to cold and warm temperatures, as well as the persistence of cold tolerance during long-term thermal acclimation. Thermal acclimation for as little as 6 hours at 8˚C enhanced crab tolerance during a 1h exposure to -2°C relative to crabs acclimated to 18˚C. Potential mechanisms for this enhanced tolerance were elucidated using cDNA microarrays to probe for differences in gene expression in cardiac tissue of warm and cold acclimated crabs during the first day of thermal acclimation. No changes in gene expression were detected until 12h of thermal acclimation. Genes strongly upregulated in warm acclimated crabs represented immune response and extracellular / intercellular processes, suggesting that warm acclimated crabs had a generalized stress response and may have been remodelling tissues or altering intercellular processes. Genes strongly upregulated in cold acclimated crabs included many that are involved in glucose production suggesting that cold acclimation involves increasing intracellular glucose as a cryoprotectant. Structural cytoskeletal proteins were also strongly represented among the genes upregulated in only cold acclimated crabs. There were no consistent changes in composition or the level of unsaturation of membrane phospholipid fatty acids with cold acclimation, which suggests that neither short- nor long-term changes in cold tolerance are mediated by changes in membrane fatty acid composition. Overall, our study demonstrates that initial changes in cold tolerance are likely not regulated by transcriptomic responses, but that gene expression-related changes in homeostasis begin within 12 hours – the length of a tidal cycle. all array data and raw images archived at the Porcelain Crab Array Database (http://array.sfsu.edu) n=264 specimens were divided into warm (18°C, n=96), cold (8°C, n=96), and control (13°C, n=72) acclimation groups. Crabs were sampled from the 13°C group at 0 h (the start of the experiment) and 24 h, the termination of the experiment. Crabs were sampled from the warm and cold acclimation groups at 6, 12, 18, and 24 hours following the start of thermal acclimation. At each time point, heart tissue from n=16 crabs from each group was dissected, flash frozen and stored at −80°C. A pooled total aRNA sample was prepared for each group by mixing equal quantities of total RNA from n=5 individuals in each group in order to have the same amount of biological diversity within each pooled RNA sample. For microarray hybridizations we used n=25 slides in an incomplete loop design where each sample was hybridized n=5 times, 2-3 times labelled with each Cy dye