Project description:Dietary tryptophan and circadian rhythms

Project description:Mice were fed a normal chow diet or a tryptophan depleted diet for two weeks under normal 12-hr light/dark cycles (LD) or in constant darkness (DD). Mice were sacrificed every 4th hour over the 24-hr circadian cycle. The liver was harvested and RNA was isolated using a standard TRIZOL protocol. The data suggest that dietary tryptophan is an important component of the diet regulating circadian homeostsis.

Project description:Mice were fed a normal chow diet or a tryptophan depleted diet for two weeks under normal 12-hr light/dark cycles (LD) or in constant darkness (DD). Mice were sacrificed every 4th hour over the 24-hr circadian cycle. The suprachiasmatic nucleus (SCN) was harvested and RNA was isolated using a standard TRIZOL protocol. The data suggest that dietary tryptophan is an important component of the diet regulating circadian homeostsis.

Project description:The circadian gene expression in peripheral tissue displays rhythmicity which is reprogrammed by feeding rhythms and dietary composition in mammals. In this study, circadian transcriptome was performed to investigate how maternal circadian rhythms during pregnancy influences circadian gene regulation in the mouse liver.

Project description:Observational, non randomized study aimed at measuring the circadian rhythms in the urinary concentrations of physiological modified nucleosides in 30 patients with metastatic colorectal cancer and in 30 age and sex-matched healthy subjects.

Project description:Circadian rhythms are integral to maintaining metabolic health by temporally coordinating metabolic functions across tissues. However, the mechanisms underlying circadian cross-tissue coordination remain poorly understood. In this study, we uncover a central role for the liver clock in regulating circadian rhythms in white adipose tissue (WAT). Using a liver-specific Bmal1 knockout mouse model, we show that hepatic circadian control is crucial for lipid metabolism in WAT. In addition, by utilizing a model where functional clocks are restricted to the liver, we demonstrate that the liver clock alone drives circadian gene expression in WAT, including Cebpa, a key regulator of adipogenesis. Mechanistically, we show that circadian liver-to-WAT communication is mediated through secreted proteins, including the adaptor protein 14-3-3η (Ywhah). The clinical relevance of these findings is supported by human cohort data, which correlate liver YWHAH expression with lipid metabolic pathways in WAT and cardiometabolic risk factors. These findings provide a mechanistic framework for how the liver clock coordinates WAT physiology and highlights its central role in cardiometabolic health, offering potential insights for targeted circadian-based therapies for metabolic disorders.

Project description:Circadian rhythms are integral to maintaining metabolic health by temporally coordinating metabolic functions across tissues. However, the mechanisms underlying circadian cross-tissue coordination remain poorly understood. In this study, we uncover a central role for the liver clock in regulating circadian rhythms in white adipose tissue (WAT). Using a liver-specific Bmal1 knockout mouse model, we show that hepatic circadian control is crucial for lipid metabolism in WAT. In addition, by utilizing a model where functional clocks are restricted to the liver, we demonstrate that the liver clock alone drives circadian gene expression in WAT, including Cebpa, a key regulator of adipogenesis. Mechanistically, we show that circadian liver-to-WAT communication is mediated through secreted proteins, including the adaptor protein 14-3-3η (Ywhah). The clinical relevance of these findings is supported by human cohort data, which correlate liver YWHAH expression with lipid metabolic pathways in WAT and cardiometabolic risk factors. These findings provide a mechanistic framework for how the liver clock coordinates WAT physiology and highlights its central role in cardiometabolic health, offering potential insights for targeted circadian-based therapies for metabolic disorders.

Project description:Circadian rhythms are integral to maintaining metabolic health by temporally coordinating metabolic functions across tissues. However, the mechanisms underlying circadian cross-tissue coordination remain poorly understood. In this study, we uncover a central role for the liver clock in regulating circadian rhythms in white adipose tissue (WAT). Using a liver-specific Bmal1 knockout mouse model, we show that hepatic circadian control is crucial for lipid metabolism in WAT. In addition, by utilizing a model where functional clocks are restricted to the liver, we demonstrate that the liver clock alone drives circadian gene expression in WAT, including Cebpa, a key regulator of adipogenesis. Mechanistically, we show that circadian liver-to-WAT communication is mediated through secreted proteins, including the adaptor protein 14-3-3η (Ywhah). The clinical relevance of these findings is supported by human cohort data, which correlate liver YWHAH expression with lipid metabolic pathways in WAT and cardiometabolic risk factors. These findings provide a mechanistic framework for how the liver clock coordinates WAT physiology and highlights its central role in cardiometabolic health, offering potential insights for targeted circadian-based therapies for metabolic disorders.

Project description:Ketone bodies, intermediates in energy metabolism and signaling, have attracted significant attention due to their role in health and disease. We performed around the clock study on ketone bodies and ketogenesis with mice on different diets. We found that caloric restriction, a dietary intervention that improves metabolism and longevity, induced high amplitude circadian rhythms in blood βOHB. The blood βOHB rhythms resulted from rhythmic ketogenesis in the liver controlled by the interaction between the circadian clock and PPAR transcriptional networks. This interaction results in transcriptional reprogramming of in beta-oxidation and ketogenesis enzymes. The reprogramming is impaired in circadian clock mutant mice. The circadian clock gated ketogenesis contributes to the diet impact on health and longevity.

Project description:Diurnal oscillations of gene expression are a hallmark of rhythmic physiology across most living organisms. Such oscillations are controlled by the interplay between the circadian clock and feeding rhythms. While rhythmic mRNA accumulation has been extensively studied, comparatively less is known about their transcription and translation. Here, we quantified simultaneously temporal transcription, accumulation, and translation of mouse liver mRNAs under physiological light-dark conditions and ad libitum or night-restricted feeding in wild-type and Bmal1 deficient animals. We found that rhythmic transcription predominantly drives rhythmic mRNA accumulation and translation for a majority of genes. Comparison of wild-type and Bmal1 KO mice shows that circadian clock and feeding rhythms have broad impact on rhythmic genes expression, Bmal1 deletion having surprisingly more impact at the post-transcriptional level. Translation efficiency is differentially regulated during the diurnal cycle for genes with 5’-TOP sequences and for genes involved in mitochondrial activity and harboring a TISU motif. The increased translation efficiency of 5’-TOP and TISU genes is mainly driven by feeding rhythms but Bmal1 deletion impacts also amplitude and phase of translation, including TISU genes. Together this study emphasizes the complex interconnections between circadian and feeding rhythms at several steps ultimately determining rhythmic gene expression and translation. RNA-Seq from total RNA of mouse liver during the dirunal cycle. Time-series mRNA profiles of wild type (WT) and Bmal -/- mice under ad libitum and night restriced feeding regimen were generated by deep sequencing.