Project description:Rice (Oryza sativa, spp. Indica, cv. 93-11) plants were grown in a Conviron PGR 15 growth chamber using precise control of temperature, light, and humidity.<br>Diurnal (driven) conditions included 12L:12D light cycles and 31C/20C thermocycles in three different combinations. These were: photocycles (LDHH), 12 hrs. light (L)/12 hrs. dark (D) at a constant temperature (31C; HH); photo/thermocycles (LDHC): 12 hrs. light (L) /12 hrs. dark (D) with a high day temperature (31C) and a low night temperature (20C); and thermocycles (LLHC): continuous light (LL) with 12 hrs. high/12 hrs. low temperature (31C, day; 20C, night). Light intensity and relative humidity were 1000 micromol m-2s-2 and 60%, respectively.<br>Three-month-old rice plants were entrained for at least one week under the respective condition prior to initiation of each experiment. Leaves and stems from individual rice plants were collected every four hours for 48 hrs in driven (diurnal) conditions followed by a two day freerun spacer under continuous light/temperature followed by two additional days of sampling under the same continuous free run condition.

Project description:Poplar (Populus trichocarpa, clone Nisqually-1) plants were grown in a Conviron PGR 15 growth chamber using precise control of temperature, light, and humidity. Diurnal (driven) conditions included 12L:12D light cycles and 25C/12C thermocycles in three different combinations. These were: photocycles (LDHH), 12 hrs. light (L)/12 hrs. dark (D) at a constant temperature (25C; HH); photo/thermocycles (LDHC): 12 hrs. light (L) /12 hrs. dark (D) with a high day temperature (25C) and a low night temperature (12C); and thermocycles (LLHC): continuous light (LL) with 12 hrs. high/12 hrs. low temperature (25C, day; 12C, night). Light intensity and relative humidity were 700 micromol m-2s-2 and 50%, respectively. Three-month-old poplar plants were entrained for at least one week under the respective condition prior to initiation of each experiment. Leaves and stems from individual poplar plants were collected every four hours for 48 hrs in driven (diurnal) conditions followed by a two day freerun spacer under continuous light/temperature followed by two additional days of sampling under the same continuous free run condition.

Project description:In most organisms biological processes are partitioned, or phased to specific times over the day through interactions between external cycles of temperature (thermocycles) and light (photocycles), and the endogenous circadian clock. This orchestration of biological activities is achieved in part through an underlying transcriptional network. To understand how thermocycles, photocycles and the circadian clock interact to control time of day specific transcript abundance in Arabidopsis thaliana, we conducted four diurnal and three circadian two-day time courses using Affymetrix GeneChips (ATH1). All time courses were carried out with seven-day-old seedlings grown on agar plates under thermocycles (HC, hot/cold) and/or photocycles (LD, light/dark), or continuous conditions (LL, continuous light; DD, continuous dark, HH, continuous hot). Whole seedlings (50-100), including roots, stems and leaves were collected every four hours and frozen in liquid nitrogen. The four time courses interrogating the interaction between thermocycles, photocycles and the circadian clock were carried out as two four-day time courses. Four-day time courses were divided into two days under diurnal conditions, and two days under circadian conditions of continuous light and temperature. Thermocycles of 12 hours at 22C (hot) and 12 hours at 12C (cold) were used in this study. The two time courses interrogating photoperiod were conducted under short days (8 hrs light and 16 hrs dark) or long days (16 hrs light and 8 hrs dark) under constant temperature. In addition, the photoperiod time courses were in the Landsberg erecta (ler) accession, in contrast to the other time courses that are in the Columbia (col) background. The final time course interrogated circadian rhythmicity in seedlings grown completely in the dark (etiolated). Dark grown seedlings were synchronized with thermocycles, and plants were sampled under the circadian conditions of continuous dark and temperature.

Project description:Plants are continuously exposed to varying environmental conditions; some anticipated diurnal changes in light and temperature and others far less predictable. Key to adaptation to a diurnal environment is the anticipation provided by the circadian clock, which coordinates broad changes in gene expression with a period of about 24 h.Here we present the analysis of RNA sequencing to measure transcript abundance over time in Brachypodium distachyon entrained in photo- and thermocycles then transferred to photocycles or thermocycles alone, or constant light and temperature conditions.

Project description:Microarray analysis on Brachypodium distachyon seedlings was performed to determine the response of the transcriptome to changes in ambient temperature, including identification of marker genes that were up-regulated or down-regulated by a moderate increase in growth temperature. Wild-type Brachypodium (Bd21) seedlings were grown on MSR63 media without sucrose (Alves et al. 2009 Nature Protocols vol. 4 pp 638-649) in a short-day photoperiod (14 hr light/ 10 hr dark) at 17 ºC. As the third leaf was emerging, plants were transferred to 12 ºC for 48 hrs. Plants were then maintained at 12 ºC or transferred to one of two temperature treatments: constant 22 ºC or constant 27 ºC. Samples were collected before the shift (0 hr) and at 2 hr and 24 hr after the shift and immediately frozen in liquid nitrogen. For each harvest, two to three replicates were collected that each contained 3 seedlings.

Project description:au14-07_clock - llhh clock transcriptome - Correlate clock-controlled diurnal gene expression changes with H2Bub chromatin mark changes on a genome-wide scale. - Wild type seedlings(Col-0)have been grown under Light/Dark conditions(12 h Light:12 h Dark)and thermocycles(23°C day:19°C night).After 10 days of entrainment, the conditions were switched to continuous light and temperature (LLHH) for 2 days. Seedlings have been harvested the 2nd day after the switch at Zeitgeber time 24 and 36 that correspond to dawn and dusk, respectively. llhh clock transcriptome-LLHH clock transcriptome.

Project description:S. cerevisiae S288C and S. pastorianus KBY011 were fermented at 20C for 48 hrs, respectively. The difference of transcription profiling between them was examined using samples harvested at 0, 6, 24, and 48 hrs during fermentation.

Project description:Most organisms have an endogenous circadian clock that is synchronized to environmental signals such as light and temperature. Although circadian rhythms have been described in the nematode C. elegans at the behavioral level, these rhythms appear to be relatively non-robust. Moreover, in contrast to other animal models, no circadian transcriptional rhythms have been identified. Thus, whether this simple nematode contains a bona fide circadian clock remains an open question. We used microarray experiments to identify light- and temperature-regulated transcriptional rhythms in C. elegans, and show that subsets of these transcripts are regulated in a circadian manner. In addition, we find that light and temperature also globally drive the expression of many genes, indicating that C. elegans exhibits systemic responses to these stimuli. Populations of growth-synchronized wild-type C. elegans L1 larvae were entrained for 5 days until adulthood to 12:12 hr light/dark (LD) cycles (500-1000 lux) at a constant temperature of 18°C, or for 4 days to 12:12 hr temperature cycles (25:15°C - warm/cold or WC) in constant darkness. RNA was collected every 4 hrs during the last entrainment and the subsequent free-running days and analyzed via hybridization of Affymetrix GeneChips. L4 larvae were transferred to FUDR-containing plates to inhibit embryonic development.

Project description:Transcript profiling was performed on samples derived from plants grown under long day conditions. Time series were harvested under diurnal (L/D; light/dark cycles) at control temperature (20 C) and cold (4 C); and under circadian conditions (L/L; continuous light) at control temperature (20 C). Leaves were sampled at time 0 and after 2 h (to coincide with light-dark transitions) and then every 4 h until 58 h.

Project description:The central role of transcriptional regulation in integrating various low temperature response mechanisms has been established in Arabidopsis, where the CBF/DREB regulon plays a prominent role during acclimation. Rice is sensitive to chilling but many japonica cultivars can survive continuous exposure to as low as 10oC for up to 7 days during the most critical stage of seedling establishment better than most indica cultivars. The transcriptional regulatory networks that define this variation have not been studied in detail as cold acclimation has been scrutinized in Arabidopsis. Towards the comparison of the compositional complexity of low temperature response regulons of rice and Arabidopsis, we used the cultivar Nipponbare for genome-wide survey of regulatory clusters by integrative analysis of promoter architectures and temporal expression profiles during exposure to 10oC at narrow time intervals. Temporal profiles revealed major clusters of genes that were induced within the initial 24 hours. These clusters were further defined by common features of having either CRT/DRE-like elements, as1/ocs-like elements or both in their promoters. Genes containing as1/ocs-like elements with or without CRT/DRE, but not those containing only CRT/DRE-like elements were induced by exogenous H2O2 but not by ABA at ambient temperature, suggesting that they belong to a potential regulon (ROS-bZIP – as1/ocs module) that responds to elevated levels of reactive oxygen species (ROS) during the initial stages of stress. Parallel analysis of transcription factors during the initial 12 hours revealed candidate regulator(s) of this putative early response regulon. Cultivar-specific expression signatures of selected members of this regulatory cluster were also positively correlated with genotypic variation in chilling tolerance. We hypothesized that the ROS-bZIP – as1/ocs cluster has important roles in configuring the transcriptome of rice seedlings during the early stages of chilling stress and it appears to be independent of ABA and functions in parallel to the CBF/DREB regulon. Keywords: time course (response to low temperature) This experiment describes the analysis of the temporal changes in gene expression in response to chilling temperature in Nipponbare rice. A total of 10 stress time points, i.e., 0.5, 2, 4, 6, 12, 18, 24, 36, 48, and 96 hrs after exposure to 10C in a growth chamber and one recovery time point, i.e., 96 hrs at 10C and then 24 hrs (24R) at ambient or control temperature (29C), were profiled with reference to a corresponding control, which was exposed to ambient temperature (29C) for the same length of time under cold stress (each stress time point has a corresponding control sample). Control and cold stress samples were labeled with Cy5 and Cy3, respectively. No dye swap replicate was performed in this experiment. The microarray platform used in this study was the 45K oligonucleotide microarray (www.ricearray.org) which comes in pairs of slides A and B (each containing about 50% of the total number of features). The data described in this series include all hybridizations with slide A and with slide B. All experiments were performed with two independent biological replicates (R1 and R2) for each time point.