Project description:Although the impact of circadian disruption is well recognized, definitive indicators and time windows for its detection are currently lacking. Here, by conducting transcriptomic, metabolomic, and integrated analysis, we comprehensively investigated the gene and metabolite changes on the 7th day after a single 6-hour phase advance jet lag in mice. Our findings revealed significant alterations during this post-jet lag window, especially in core clock genes Bmal1 and Cry1, and metabolites L-Arginine and SM(d18:1/18:1(11Z)), with notable differences at Zeitgeber Time 0 (ZT0), suggesting ZT0 as a key diagnostic time point. Additionally, we identified L-Serine as a potential biomarker for indexing circadian disruption irrespective of time points. Our study provides new insights into potential biomarkers for detecting circadian clock disruption.

Project description:Frequent shift work causes disruption of the circadian rhythm and might on the long-term result in increased health risk. Current biomarkers evaluating the presence of circadian rhythm disturbance (CRD) require 24-hr (around the clock) measurements, which is not practical for use in large-scale (human) studies. The aim of the present study was to identify universal biomarkers for CRD independent of time of day using a transcriptomics approach. Female FVB mice were exposed to six shifts in a clockwise (CW) and counterclockwise (CCW) CRD protocol and sacrificed at baseline and after 1 shift, 6 shifts, 5 days recovery and 14 days recovery, respectively. At six time-points during the day, livers were collected for mRNA microarray analysis. Bioinformatics analysis identified a set of universal markers for CRD. These biomarkers might be useful to measure CRD and can be used later on for monitoring the effectiveness of intervention strategies aiming to prevent or minimize chronic adverse health effects.

Project description:The transcription-translation feedback loop, the core clock mechanism, is required for circadian rhythm. CRY protein, including CRY1 and CRY2, plays an important repressor role in the regulation of clock genes. However, other proteins, like PER1, PER2, NR1D1 and NR1D2, in the loop mask the transcriptional effects of CRY. This study provides data to find candidate genes specifically affected by CRY1 or CRY2 in mouse embryonic fibroblast (MEF) cells.

Project description:Circadian rhythm in clock mutants

Project description:Disruption of the circadian rhythm is associated with inflammatory diseases, metabolic syndrome and cancer. In mice, the time of day strongly influences lethality in response to LPS, with survival greatest at the beginning compared to the end of the light cycle (Halberg et al. 1960; Marpegan et al. 2009; Nguyen et al. 2013). Myeloid-cell intrinsic circadian clock components control inflammatory cytokine production (Gibbs et al. 2012; Curtis et al. 2015; Bellet et al. 2013), and metabolic inputs influence lethality in response to LPS (Wang et al. 2016; Weis et al. 2017; Traba et al. 2017), but the relative contributions of these inputs to daily changes in sepsis susceptibility are not known. Here we show that feeding, rather than light, controls time of day dependent LPS sensitivity. Mortality following LPS administration after 12 hours of food deprivation was associated with hypoglycemia, rather than inflammatory cytokine production, independent of the clock regulator BMAL1 expressed in myeloid cells. Deletion of BMAL1 in hepatocytes globally disrupted the transcriptional response to the feeding cycle in the liver and resulted in constitutively high LPS sensitivity. These results show that food, rather than light, is the ‘zeitgeber’ for acute mortality in response to LPS, with a critical role for the hepatocyte-intrinsic circadian clock in integrating nutritional cues to regulate survival in response to innate immune stimuli. Understanding the hepatic molecular programs operational in response to fasting versus fed cues could identify novel pathways that may be targeted to enhance resistance to endotoxemia.

Project description:This experiment was designed to identify the autonomous rhythm of peripheral circadian clocks in the absence of a master circadian clock to regulate the rhythm

Project description:Increased susceptibility of circadian clock mutant mice to metabolic diseases has led to the understanding that a molecular circadian clock is necessary for metabolic homeostasis. Circadian clock produces a daily rhythm in activity-rest and an associated rhythm in feeding-fasting. Feeding-fasting driven programs and cell autonomous circadian oscillator act synergistically in the liver to orchestrate daily rhythm in metabolism. However, an imposed feeding-fasting rhythm, as in time-restricted feeding, can drive some rhythm in liver gene expression in clock mutant mice. We tested if TRF alone, in the absence of a circadian clock in the liver or in the whole animal can prevent obesity and metabolic syndrome. Mice lacking the clock component Bmal1 in the liver, Rev-erb alpha/beta in the liver or cry1-/-;cry2-/- (CDKO) mice rapidly gain weight and show genotype specific increased susceptibility to dyslipidemia, hypercholesterolemia and glucose intolerance under ad lib fed condition. However, when the mice were fed the same diet under time-restricted feeding regimen that imposed 10 h feeding during the night, they were protected from weight gain and other metabolic diseases. Transcriptome and metabolome analyses of the liver from there mutant mice showed TRF reduces de novo lipogenesis, increased beta-oxidation independent of a circadian clock. TRF also enhanced cellular defense to metabolic stress. These results suggest a major function of the circadian clock in metabolic homeostasis is to sustain a daily rhythm in feeding and fasting. The feeding-fasting cycle orchestrates a balance between nutrient stress and cellular response to maintain homeostasis.

Project description:Circadian clocks drive 24-h rhythms of physiology and behavior. The circadian clock of hepatocytes has been shown to regulate glucose metabolism, and we were interested if rescuing liver clock function can reverse metabolic impairments in hyperphagic/obese Clock-D19 mutant mice. We compared transcripomte regulation in livers (at Zeitgeber time ZT10) of wild-type (C57BL/6J) and Clock-D19 mice and Clock-D19 mice with genetic rescue of liver clock function using hydrodynamic tail vein injection of a WT-CLOCK expression plasmid

Project description:Molecular analysis of circadian rhythm in mice. Liver tissue of wildtype, Clock mutant and Cry deficient C57BL/6 8- to 10-week-old male mice examined. Keywords = circadian rhythm Keywords: other

Project description:Peripheral clocks function to regulate each organ and are synchronized though various molecular and behavioral signals. However, signals that entrain the bladder clock remain elusive. Here, we show that glucocorticoids are a key cue for the bladder clock in vitro and in vivo. A pBmal1-dLuc human urothelial cell line showed significant shifts in gene expression after cortisol treatment while, in vivo, rhythmic bladder clock gene expression was not influenced by bilateral-adrenalectomy (ADx) but shifted 4 hours forward by corticosterone administration at the inactive phase (CORT). Moreover, the bladder clock shifted 8-12 hours in ADx+CORT mice. These mice saw decreases in the diurnal rhythm of volume voided per micturition, while maintaining diurnal activity rhythm. These results indicate that the diurnal rhythm of glucocorticoid signaling is a zeitgeber that overcomes other entrainment factors for the bladder clock and coordinates the diurnal rhythm of volume voided per micturition. (145 words)