Project description:Circadian rhythms are cell-autonomous biological oscillations with a period of about 24 hours. Current models propose that transcriptional feedback loops are the principal mechanism for the generation of circadian oscillations. In these models, Drosophila S2 cells are generally regarded as ‘non-rhythmic’ cells, as they do not express several canonical circadian components. Using an unbiased multi-omics approach, we made the surprising discovery that Drosophila S2 cells do in fact display widespread daily rhythms. Transcriptomics and proteomics analyses revealed that hundreds of genes and their products are rhythmically expressed in a 24-hour cycle. Metabolomics analyses extended these findings and illustrated that central carbon metabolism and amino acid metabolism are the main pathways regulated in a rhythmic fashion. We thus demonstrate that daily genome-wide oscillations, coupled to metabolic cycles, take place in eukaryotic cells without the contribution of known circadian regulators.

Project description:The daily pattern of temporal gene expression is regulated by the circadian clock system. Under constant environmental conditions, aging is associated with a shortening of the endogenous period of circadian rhythms in Arabidopsis. This study investigated to investigate how aging influences the waveforms of rhythmic patterns of gene expression under light/dark cycles. The waveforms of the daily cycling circadian clock showed significant warping in aged leaves, which shifted their expression pattern. Transcriptomic analysis revealed that the number of daily cycling genes in aged leaves was reduced by more than half. Furthermore, in aged plants, the expression schedule of cycling genes in both young and old leaves warped. Circadian clock mutants, including toc1, which did not exhibit age-dependent warping, had significantly altered warping patterns.

Project description:The circadian regulation of gene expression underlies orchestrated daily rhythms in physiology, metabolism, and behavior. The central dopamine (DA) system arising from DA neurons in the ventral midbrain has been implicated in a wide range of brain functions. Growing evidence suggests that DA transmission follows daily oscillations at multiple regulatory steps, and its dysfunction is closely related to the onset of various neuropsychiatric diseases. We examined diurnal gene expression profiles across key brain areas constituting the central DA pathways in mice by use of microarray analyses to identify rhythmically expressed genes according to the time of day (TOD).

Project description:The circadian rhythm controls timed choreography of gene expression to maintain normal cell physiology and metabolism. The predominant regulatory mechanism of the circadian rhythm is a transcriptional negative feedback loop that facilitates, and is facilitated by, circadian-regulated facultative heterochromatin. The long-term consequence of disrupted diurnal rhythm, or mutations in core clock genes, cause accelerated aging and an increased incidence in age-related diseases. To understand chromatin dynamics underlying age-related changes to circadian transcription, we performed a combined RNA-seq and ChIP-seq at two diurnal time-points for three different age groups. Our analysis focused on uncovering relationships between long non-coding RNA (lncRNA) and age-related changes to heterochromatin. We determined that the core clock genes maintain rhythmic expression regardless of age, but circadian output, including numerous lncRNAs, changes dramatically with age. In addition, there is both diurnal and age-related changes in Histone H3 lysine 9 tri-methylation (H3K9me3) that correlate with the changes in gene expression. Collectively, the data suggest a model where age-related changes in diurnal gene expression occur, in part, due to age-related redistribution of rhythmic facultative heterochromatin. Alterations in heterochromatin appear to be mediated by changes in diurnal lncRNA expression creating an interlocked circadian-chromatin regulatory network that undergoes age-dependent metamorphosis.

Project description:The circadian rhythm controls timed choreography of gene expression to maintain normal cell physiology and metabolism. The predominant regulatory mechanism of the circadian rhythm is a transcriptional negative feedback loop that facilitates, and is facilitated by, circadian-regulated facultative heterochromatin. The long-term consequence of disrupted diurnal rhythm, or mutations in core clock genes, cause accelerated aging and an increased incidence in age-related diseases. To understand chromatin dynamics underlying age-related changes to circadian transcription, we performed a combined RNA-seq and ChIP-seq at two diurnal time-points for three different age groups. Our analysis focused on uncovering relationships between long non-coding RNA (lncRNA) and age-related changes to heterochromatin. We determined that the core clock genes maintain rhythmic expression regardless of age, but circadian output, including numerous lncRNAs, changes dramatically with age. In addition, there is both diurnal and age-related changes in Histone H3 lysine 9 tri-methylation (H3K9me3) that correlate with the changes in gene expression. Collectively, the data suggest a model where age-related changes in diurnal gene expression occur, in part, due to age-related redistribution of rhythmic facultative heterochromatin. Alterations in heterochromatin appear to be mediated by changes in diurnal lncRNA expression creating an interlocked circadian-chromatin regulatory network that undergoes age-dependent metamorphosis.

Project description:The diurnal peak of phagocytosis by the retinal pigment epithelium (RPE) of photoreceptor outer segments is under circadian control, and it is believed that this process involves interactions from both the retina and RPE. Previous studies have demonstrated that a functional circadian clock exists within multiple retinal cell types and RPE cells. Thereby, the aim of the current study was to determine whether the circadian clock in the retina and or RPE controls the diurnal phagocytic peak of photoreceptor outer segments and whether selective disruption of the circadian clock in the RPE would affect RPE cells function and the viability during aging. To that aim, we first generated and validated an RPE tissue-specific KO of the essential clock gene, Bmal1, and then we determined the daily rhythm in phagocytic activity by the RPE in mice lacking a functional circadian clock in the retina or RPE. Then using electroretinography, spectral domain-optical coherence tomography, and optomotor response measurements of visual function we determined the effect of Bmal1 removal in young (6-month-old) and old (18-months old) mice. RPE morphology and lipofuscin accumulation was also determined in young and old mice. Our data show that the circadian clock in the RPE controls the daily diurnal phagocytic peak of POS. Surprisingly, the lack of a functional RPE circadian clock or the diurnal phagocytic peak does not result in any detectable age-related degenerative phenotype in the retina or RPE. Thus, our results demonstrate that the circadian clock in the RPE controls the daily peak in the phagocytic activity. However, the loss of the circadian clock in the RPE does not result in deterioration of photoreceptors or the RPE during aging.

Project description:The evolutionarily conserved circadian system allows organisms to synchronize internal processes with 24-h cycling environmental timing cues, ensuring optimal adaptation. Like other organs, the pancreas function is under circadian control. Recent evidence suggests that aging by itself is associated with altered circadian homeostasis in different tissues which could affect the organ’s resiliency to aging-related pathologies. Pancreas pathologies of either endocrine or exocrine components are age-related. Whether pancreas circadian transcriptome output is affected by age is still unknown. To address this, here we profiled the impact of age on the pancreatic transcriptome over a full circadian cycle and elucidated a circadian transcriptome reorganization of pancreas by aging. Our study highlights gain of rhythms in the extrinsic cellular pathways in the aged pancreas and extends a potential role to fibroblast-associated mechanisms.

Project description:Aging animals undergo a variety of changes in molecular processes. Among these, the cellular circadian clock has been shown to change as animals age. Moreover, there is evidence that also core circadian clock proteins could influence the ageing behavior of vertebrates. To investigate the interplay between aging and the circadian clock, we studied circadian mRNA expression in skeletal muscles from young (8 weeks) and aged (80 weeks) mice. In order to detect differences in circadian patterns, we used microarray-based transcriptome-wide time series of mRNA expression, containing 16 independent measurements for both young and aged animals. Each individual time point consists of total RNA from hind limb skeletal muscles from 3 different animals. Young and aged mice where entrained to 12 hr/12 hr light-dark conditions. From these mice, hind limb skeletal muscles were extracted at different times of day, in order to measure circadian mRNA expression patterns.

Project description:Caloric restriction (CR) prolongs lifespan, yet the mechanisms by which it does so remain poorly understood. Under CR, mice self-impose chronic cycles of 2-hour-feeding and 22-hour-fasting, raising the question whether calories, fasting, or time of day are causal. We show that 30%-CR is sufficient to extend lifespan 10%; however, a daily fasting interval and circadian-alignment of feeding act together to extend lifespan 35% in male C57BL/6J mice. These circadian effects of CR are independent of fasting duration and body weight. Aging induces widespread increases in gene expression associated with inflammation and decreases in expression of genes encoding components of metabolic pathways in liver from ad lib fed mice. CR at night ameliorates these aging-related changes. Thus, circadian interventions promote longevity and provide a perspective to further explore mechanisms of aging.

Project description:Sirtuin 1 (SIRT1) is involved in both aging and circadian-clock regulation, yet the link between the two processes in relation to SIRT1 function is not clear. Using Sirt1-deficient mice, we found that Sirt1 and Period 2 (Per2) constitute a reciprocal negative regulation loop that plays important roles in modulating hepatic circadian rhythmicity and aging. Sirt1-deficient mice exhibited profound premature aging and enhanced acetylation of histone H4 on lysine16 (H4K16) in the promoter of Per2, the latter of which leads to its overexpression; in turn, Per2 suppresses Sirt1 transcription through binding to the Sirt1 promoter at the Clock/Bmal1 site. This negative reciprocal relationship between SIRT1 and PER2 was also observed in human hepatocytes. We further demonstrated that the absence of Sirt1 or the ectopic overexpression of Per2 in the liver resulted in a dysregulated pace of the circadian rhythm. The similar circadian rhythm was also observed in aged wild type mice. The interplay between Sirt1 and Per2 modulates aging gene expression and circadian-clock maintenance. To investigate hepatic SIRT1-dependent aging related genes, livers from wild type mice at 3 months (young), 12 months (middle age), and 19 months (old) of age, as well as Sirt1-deficient mice at 3 months of age were snap frozen and subject to RNA isolation and microarray analysis.