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 #1 was to control for environmental influences (light and nutrition) on the detection of circadian rhythms in gene expression. In Microarray Experiment #1, 72 mice were segregated equally into 2 equal groups the day prior to the experiment at the beginning of the dark phase (Circadian Time 12 (CT12) or 7:00 PM local time). In one group (samples labeled with the suffix “MR”) the mice were kept under standard lighting and nutritional conditions (LD 12:12). In the second group (samples labeled with the suffix “DD”), mice were kept in constant darkness and food pellets were removed from their cages at the start of sample acquisition (DD 12:12+STV). Sample acquisition commenced at CT4 (or 11:00 AM local time). For each group 3 animals were sacrificed per time point (12 time points total). 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 #1 RNA labeling and microarray hybridization were conducted at the Partners Center for Personalized Genetic Medicine. All biological samples were represented by a single technical replicate on the microarray.
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.
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.
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:Endogenous circadian rhythms regulate the hosts response to influenza infection, more through the host tolerance pathways rater than direct effects on anti-viral resistance.
Project description:Circadian rhythms are oscillations with a periodicity of 24 hours that are controlled by an endogenous clock and are observed in virtually all aspects of mammalian function from expression of genes to complex physiological processes. The master clock is present in the suprachiasmatic nucleus (SCN) in the anterior part of the hypothalamus and controls peripheral clocks present in other parts of the body . Although much is known about the mechanism of the central clock in the SCN, the regulation of clocks present in peripheral tissues is still unclear. This study is designed to examine fluctuations in gene expression in lungs within the 24 hour circadian cycle in normal animals. The objectives of this study is to identify and analyze circadian oscillation in gene expression in lungs, and to identify the role of circadian regulation in coordinating the functioning of this dynamic organ. Fifty-four male normal Wistar rats (250-350 g body weight) were housed in a strictly controlled stress free environment with light:dark cycles of 12 hr:12hr. Three animals were sacrificed at each of 18 selected time points within the 24 hour cycle. RNA was prepared from lungs for gene arrays. Time point designations reflect time after lights on in hours.
Project description:Circadian rhythms are oscillations with a periodicity of 24 hours that are controlled by an endogenous clock and are observed in virtually all aspects of mammalian function from expression of genes to complex physiological processes. The master clock is present in the suprachiasmatic nucleus (SCN) in the anterior part of the hypothalamus and controls peripheral clocks present in other parts of the body . Although much is known about the mechanism of the central clock in the SCN, the regulation of clocks present in peripheral tissues is still unclear. This study is designed to examine fluctuations in gene expression in lungs within the 24 hour circadian cycle in normal animals. The objectives of this study is to identify and analyze circadian oscillation in gene expression in lungs, and to identify the role of circadian regulation in coordinating the functioning of this dynamic organ.