Project description:In this study we utilized a genome-wide approach to analyze circadian patterns of gene expression in mouse lung lungs, both in the basal state and in the setting of systemic inflammation caused by endotoxemia. We chose the lung because it represents a primary portal for systemic infection and organ failure in critically ill patients, and because the lung exhibits strong physiological circadian rhythms in health and in diseases such as asthma. The gene expression the data presented here was correlated to histological observations and metabolite measurements derived from the same biological samples, in order to obtain a broad picture of how inflammation impacts circadian rhythms in mouse lung. To examine circadian regulation in mouse lung we performed 2 independent time-series experiments (Microarray Experiments #1 and #2), in which groups of mice were euthanized at 4 hour intervals for 48 hours. The purpose of Microarray Experiment #2 was to compare circadian gene expression in healthy lungs (samples labeled with the prefix “NT”) to lungs derived from endotoxemic animals (samples labeled with the prefix “LT”). For Microarray Experiment #2, 94 mice were placed under constant light conditions (LL 12:12, food ad libitum) at CT12 the prior day (7:00 PM local time). At CT10 (5:00 PM) on the day of the experiment a sub-group of 40 mice received a single intraperitoneal injection of 12 mg/kg E. coli O127:B8 endotoxin (LPS, Sigma L3129, Lot 029K4055), and sample collection began directly after. 3-4 mice per group were sacrificed at consecutive 4 hour intervals for 2-3 days. The left lung and the right upper lobe were frozen immediately in liquid nitrogen for microarray analysis. For mRNA isolation lung tissue was immersed in RNAlater (Qiagen) and total RNA was then extracted using the RNeasy Mini Kit (Qiagen). RNA quality (RIN>=7) was confirmed using an Agilent 2100 Bioanalyzer. RNA from all biological samples was labeled at once using the Ambion TotalPrep-96 RNA Amplification Kit. The samples were then blinded, randomized to chip position and hybridized to the Illumina MouseRef-8 v2.0 Expression BeadChips. For Microarray Experiment #2 at the Channing Division of Network Medicine (Brigham and Women’s Hospital). Two biological samples (NT00L1 and LT00L1) were represented by 2 technical replicates on the microarray. The remaining biological samples were represented by a single technical replicate.

Project description:Anopheles gambiae, the primary African malarial mosquito, exhibits numerous behaviors that are under diel and circadian control, including locomotor activity, swarming, mating, host seeking, eclosion, egg laying and sugar feeding. However, little has been performed to elucidate the molecular basis for these daily rhythms. To study how gene expression is globally regulated by diel and circadian mechanisms, we have undertaken a DNA microarray analysis of A. gambiae head and bodies under 12:12 light:dark cycle (LD) and constant dark (DD, free-running) conditions. Zeitgeber Time (ZT) with ZT12 defined as time of lights OFF under the light:dark cycle, and ZT0 defined as end of the dawn transition. Circadian Time (CT) with CT0 defined as subjective dawn, inferred from ZT0 of the previous light:dark cycle. Adult mated but non-blood fed female mosquito heads and bodies under 12:12 light:dark cycle (LD) and constant dark (DD) conditions were collected every 4 hr to generate 48 hr gene expression profiles, and samples were processed with Affymetrix full genome microarrays. Downstream analysis identified genes with ~24hr rhythmic expression profiles.

Project description:Anopheles gambiae, the primary African malarial mosquito, exhibits numerous behaviors that are under diel and circadian control, including locomotor activity, swarming, mating, host seeking, eclosion, egg laying and sugar feeding. However, little has been performed to elucidate the molecular basis for these daily rhythms. To study how gene expression is globally regulated by diel and circadian mechanisms, we have undertaken a DNA microarray analysis of A. gambiae head and bodies under 12:12 light:dark cycle (LD) and constant dark (DD, free-running) conditions. Zeitgeber Time (ZT) with ZT12 defined as time of lights OFF under the light:dark cycle, and ZT0 defined as end of the dawn transition. Circadian Time (CT) with CT0 defined as subjective dawn, inferred from ZT0 of the previous light:dark cycle.

Project description:To address the T cell-intrinsic rhythms underlying circadian variations of their functions, we analyzed gene expression rhythms in mouse CD8+ T cells. To do this, we entrained 8 weeks old male C57BL/6J mice for at least 2 weeks in a light:dark cycle, then put them in constant darkness (DD). Mice were sacrificed every 4 h over 48 h, on the second and third day in DD, and brachial, axillary and inguinal lymph nodes (LNs) were harvested. For each of the 12 time points, LNs from 6 mice were pooled. CD8+ T cells were isolated using EasySepTM mouse CD8a positive selection kit (STEMCELL technologies). The purity of the CD8 T cells was between 95.6 and 98.9% in all samples. Total RNA was extracted and RNA sequencing performed. Subsequent analysis aimed to identify transcript that show significant rhythmicity.

Project description:Investigation of transcriptome dynamics of Japanese cedar (Cryptomeria japonica) in winter (Dec. 22-23, 2011) and summer (July 30-31, 2012). We investigated seasonal and diurnal transcriptome dynamics of Japanese cedar (Cryptomeria japonica) by analyzing shoot samples collected at four-hour interval for two days in winter and summer, respectively. We first collected sequence data of expressed genes from shoots to designed microarray probes. Microarray analysis revealed the significant difference of transcripts between summer and winter, and the diurnal transcriptome dynamic in summer.Statistical analysis indicated that about 7.7 % of unique genes showed diurnal rhythms with more than two-fold of peak-to-trough amplitude in summer. Summer samples were collected at four-hour interval for two days (12 time points) from three different cuttings as biological repeats (total 36 samples). Winter samples were collected at 4:00/8:00/12:00/16:00/20:00/24:00 on Dec 22 and 12:00/24:00 on Dec 23 (total eight samples).

Project description:The goal of the experiment was to perform a large scale study of circadian regulation of gene expression in maize. To identify maize genes with expression regulated by the circadian clock, transcript levels in the aerial tissues of young maize seedlings were determined by transcriptional profiling with the Affymetrix GeneChip Maize Genome Array. Maize inbred B73 seedlings were grown inside Conviron growth chamber. B73 seedlings were grown for 7 days under 12 h light:12 h dark (LD) photocycles, 26° C temperature and 70% humidity. At the 8th day, seedlings were transferred to continuous light (LL) and were allowed to entrain completely for 24 h prior to tissue harvest following which tissue was harvested every 4 hours under LL conditions for a period of 48h. Therefore, for the circadian LL time course 12 time points were collected as follows (also defined as factors in the treatment section): ZT0 - 8:00 am/ subjective dawn/ Day1 ZT4 - 12:00 pm/ subjective mid-day/ Day1 ZT8 - 4:00 pm/ subjective late-day/ Day1 ZT12 - 8:00 pm/ subjective dusk/ Day1 ZT16 - 12:00 am/ subjective mid-night/ Day1 ZT20 - 4:00 am/ subjective pre-dawn/ Day1 ZT24- 8:00 am/ subjective dawn/ Day2 ZT28 - 12:00 pm/ subjective mid-day/ Day2 ZT32 - 4:00 pm/ subjective late-day/ Day2 ZT36 - 8:00 pm/ subjective dusk/ Day2 ZT40 - 12:00 am/ subjective mid-night/ Day2 ZT44 - 4:00 am/ subjective pre-dawn/ Day2 Tissue comprised of aerial portion of the seedlings (corresponding to tissue from the prop roots and up) for RNA isolation. Total RNA was isolated from the entire aerial portion of 7 day-old seedlings (corresponding to tissue from the prop roots and up) by Trizol extraction followed by Qiagen RNeasy columns and treatment with RNase-free DNase I (Qiagen; qiagen.com). RNA was isolated from 3 independent biological replicates was pooled. cRNA was generated from pooled total RNA from 3 biological replicates with the GeneChip One-Cycle Target Labeling kit according to the manufacturer’s recommendations (Affymetrix, affymetrix.com). The University of California, Berkeley Functional Genomics Laboratory hybridized samples to Affymetrix GeneChip Maize Genome Arrays and scanned the washed arrays as suggested by manufacturer. Probe sets called “Not Present” or “Marginal” on one or more microarrays were removed from the downstream analysis, as is common practice with circadian studies. Raw hybridization intensities were normalized across all twelve arrays using RMA express in Perfect Match mode. ****[PLEXdb(http://www.plexdb.org) has submitted this series at GEO on behalf of the original contributor, Frank G. Harmon. The equivalent experiment is ZM28 at PLEXdb.]

Project description:The circadian rhythm is the most general and important rhythm in biological organisms. In this study, continuous 24 h video recordings showed that the cumulative movement distance and duration of the abalone, Haliotis discus hannai reached their maximum values between 20:00–00:00, but both were significantly lower between 08:00–12:00 than at any other time of day or night (P < 0.05). To investigate the causes of these diel differences in abalone movement behavior, their cerebral ganglia were harvested at 00:00 (group D) and 12:00 (group L) to screen for differentially expressed proteins using tandem mass tagging (TMT) quantitative proteomics. Seventy-five significantly different proteins were identified in group D vs. group L. Acetylcholinesterase (AChE) was found three times, and its expression levels differed significantly between day and night (P < 0.05). A cosine rhythm analysis found that the concentration of acetylcholine (Ach) and the expression levels of AchE tended to be low during the day and high at night, and high during the day and low at night, respectively.

Project description:Chick pinealocytes exhibit all the characteristics of a complete circadian system, comprising photoreceptive inputs, molecular clockworks and an easily measured rhythmic output, melatonin biosynthesis. We used microarray analysis to investigate the expression of approximately 8000 genes within cultured pinealocytes subjected to both LD and DD cycles. We report that a reduced subset of genes were rhythmically expressed in vitro compared to those previously published in vivo, and that gene expression rhythms were lower in amplitude, although the functional distribution of the rhythmic transcriptome was largely similar. We also investigated the effects of 6-hour pulses of light or of norepinephrine on gene expression in free-running cultures during both subjective day and night. As expected, both light and norepinephrine inhibited melatonin production; however, the two treatments differentially up- or down-regulated specific sets of genes in a fashion that was dependent upon time of day. Our combined approach of utilizing a time of day study and a light/NE pulse microarray experiment allowed us to identify novel genes linking clock input to clock function within the pineal. We identified approximately 30 rhythmic, light-responsive, NE-insensitive genes with no previously known clock function, which may play a role in circadian regulation of the pineal. These are candidates for future functional genomics experiments to elucidate their potential role in pineal physiology. Keywords: circadian; avian; pineal; light; norepinephrine Microarray analysis was performed on pineal samples subjected to one of four experimental groups: cultures placed within a 12-hour light:12-hour dark cycle (LD); cultures placed in continuous darkness (DD); cultures subjected to a 6-hour light pulse beginning at either CT0 or CT12 (i.e., zero or 12 hours after the beginning of subjective day) or that received no light pulse; and cultures subjected to 6 hours of NE treatment beginning at either CT0 or CT12 or that received similarly administered vehicle. For LD and DD groups, time-course sampling was performed such that 6 samples were collected over the course of a day at 4-hour intervals. For the light pulse and NE administration groups, 2 samples were collected over the course of a day, either at CT6 or CT18 (i.e., 6 or 18 hours after the beginning of subjective day). Four biological replicates and two technical replicates (for each biological repeat) were performed for each sample. For the LD and DD groups, time-points ZT18 and CT18 served as the control reference for the time-course analysis. For the light pulse experiment, cultures that did not receive light served as the control. For the NE administration experiment, cultures that received vehicle served as the control. Dye swaps for performed for experimental samples from the light pulse and NE administration experiments.

Project description:We used a digital gene expression (DGE) system to generate partial gene expression profiles for 12 selected samples. Significant differences in gene expression between early- and late-flowering samples were detected for 72 candidate genes for flowering time. Genes related to circadian rhythms were significantly overrepresented among the differentially expressed genes. Our data suggest that circadian clock genes play an important role in the evolution of flowering time, and C. bursa-pastoris plants exhibit expression differences for candidate genes likely to affect flowering time across the broad range of environments they face in China.

Project description:In this study we utilized a genome-wide approach to analyze circadian patterns of gene expression in mouse lung lungs, both in the basal state and in the setting of systemic inflammation caused by endotoxemia. We chose the lung because it represents a primary portal for systemic infection and organ failure in critically ill patients, and because the lung exhibits strong physiological circadian rhythms in health and in diseases such as asthma. The gene expression the data presented here was correlated to histological observations and metabolite measurements derived from the same biological samples, in order to obtain a broad picture of how inflammation impacts circadian rhythms in mouse lung.